42nd European Conference on Optical Communication
September 18—22, 2016 Congress Center Düsseldorf (CCD), Germany
FINAL PROGRAMME
www.ecoc-conference.org
1
ECOC 2016 - Programme Overview
Time Room 18+19 Room 17 Room 16 Room 15 Room 110 Room 112 Room 14 Sunday, September 18 09:00 – 13:00 Training Course: Training Course: Laser systems on ePIXfab Training Photonic Integrated cource on the state Circuits of the art in Silicon Phonotnics 10 10 4th Optical 13:30 – 18:00 WS 1: Progress and WS 2: Exploring the WS 3: Short range WS 4: Fiber and WS 5: Next WS 6: Extending re- Interconnect in Challenges in Signal real value of fl exible optical transmission waveguide based Generation Ultra- ach in long-haul WDM Data Centers EU- Processing and optical networks for emerging 5G devices for 2 micron, Broadband Silicon systems: What can be Symposium 15:30 – 16:00 Channel Modelling fronthaul, DCI and is there the need ? Photonics Based achieved with nonlinear Coffee Break for Space Division Metro Networks Integrated Circuits mitigation techniques (Foyer CCD) Multiplexed Trans- in fully loaded WDM mission Systems Transmission? 12 13 14 15 16 17 11 18:00 – 19:30 Get Together, Wintergarden Restaurant CCD Stadthalle Monday, September 19 10:00 – 12:30 Plenary Session, Room 1 12:30 – 14:00 Lunch Break 72 14:00 – 15:30 M.1.A: High Power M.1.B: DSP for Re- M.1.C: High Speed M.1.D: Probabilistic M.1.E: Coherent PON M.1.F: Advanced FiberSC1 Lasers 30 ceiverSC3 Subsystems 30 SubsystemsSC430 ShapingSC531 SC731 OpticalSC6 Networking 31 15:30 – 16:00 Coffee Break, Exhibition Hall 16:00 – 17:30 M.2.A: Fiber M.2.B: DSP for M.2.C: Pulse M.2.D: Short M.2.E: Transmitters I M.2.F: Data Center Amplifi ers for SDM Short Reach Amplitude Distance Direct Networks SC1 32 SC332 ModalationSC4 I 32 DetectionSC5 Systems 33 SC233 SC633 18:00 – 20:30 Welcome Reception, Big Foyer CCD Stadthalle Tuesday, September 20 09:00 – 10:30 Tu.1.A: Light Sources Tu.1.B: Multi-Layer Tu.1.C: Advanced Tu.1.D: SDM Tu.1.E: Coding and Tu.1.F: Optical CLEO 1: Spatio- forSC2 Interconnects 34 SDNSC634 ModulationSC434 TransmissionSC5 I 35 ReceiversSC335 AccessSC7 for 5G 35 temporal Control 26 10:30 – 11:00 Coffee Break, Exhibition Hall 11:00 – 12:30 Tu.2.A: Digital Tu.2.B: Network Tu.2.C: Measurement Tu.2.D: SDM Tu.2.E: MM-Wave Tu.2.F: Novel Fibre CLEO 2: Optical Infor- SignalSC3 Processing 36 AutomationSC636 andSC4 Control 36 TransmissionSC5 II 37 DevicesSC237 TechnologiesSC1 37 mation Processing 26 12:30 – 14:00 Lunch Break 72 14:00 – 16:00 Exhibition Only / 15:30 – 16:00 Coffee Break, Exhibition Hall 16:00 – 17:30 Tu.3.A: Modulators Tu.3.B: DSP Tu.3.C: Multicarier Tu.3.D: Elastic Tu.3.E: Nonlinear Tu.3.F: Advanced CLEO 3: for Nonlinearity Modulation Optical Networks III and Quantum Modulation for Optoelectronics SC238 MitigationSC338 SC438 SC639 TechniquesSC539 AccessSC739 27 Wednesday, September 21 09:00 – 10:30 W.1.A: Advanced W.1.B: Fiber W.1.C: Signal W.1.D: Nonlinear W.1.E: Photonics- W.1.F: CLEO 4: Nonlinear Silicon Photonics Sensing and Shaping Distortions Based Wireless SDN and NFV Cavities SC440 MeasurementSC1 40 SC340 SC541 AccessSC741 SC641 28 10:30 – 11:00 Coffee Break, Exhibition Hall 11:00 – 12:30 W.2.A: Trends on W.2.B: Multicore W.2.C: W.2.D: Advanced W.2.E: W.2.F: Switching CLEO 5: Lasers and Passive Optical Fibers Error Correction Modulation Formats I Transmitters II and Routing instabilities NetworkSC742 SC1 42 SC342 SC543 SC243 SC443 29 12:30 – 14:00 Lunch Break 72 14:00 – 15:30 W.3.A: Elastic W.3.B: Fibres for W.3.C: Nonlinear W.3.D: Advanced W.3.E: TWDM PON W.3.F: Silicon Optical Networks I Mode Division Optical Signal Modulation Formats II Photonics and SC644 MultilexingSC1 44 ProcessingSC344 SC545 SC745 IntegrationSC245 15:30 – 16:00 Coffee Break, Exhibition Hall
16:00 – 17:30 W.4.P. Poster Session I, Big Foyer CCD Stadthalle 46 19:30 – 22:30 Conference Dinner, Classic Remise Thursday, September 22 09:00 – 10:30 Th.1.A: Nonlinear Th.1.B: Multiplexing Th.1.C: Th.1.D: Auxiliary Th.1.E: Elastic Mitigation and Switching Pulse Amplitude Managementand Optical Networks II Devices Modulation II Control Channel SC5 SC2 SC4 TechnologiesSC7 for SC6 50 50 50 Mobile Fronthaul 51 51 10:30 – 11:00 Coffee Break, Foyer CCD
11:00 – 12:30 Th.2.P. Poster Session II, Big Foyer CCD Stadthalle 52 12:30 – 14:00 Lunch Break 72 14:00 – 15:30 Post Deadline Paper Sessions 15:30 – 16:00 Awards and Closing Ceremony, Room 1
2 n n = page number Contents Programme Overview...... 2 Welcome ...... 5
ECOC 2016 Topics ...... 7
ECOC 2016 Committees ...... 8
TPC Subcommittees ...... 8
Training Courses ...... 10
EU Symposium ...... 11
Workshops ...... 12
Keynote Presentations ...... 18
Tutorials ...... 20
Invited Talks ...... 22
CLEO Focus Meeting ...... 26
Technical Programme
Monday ...... 30
Tuesday ...... 34
Wednesday ...... 40
Thursday ...... 50
Author List ...... 56
General Information ...... 70
Route Map...... 75
Exhibitor Index ...... 76
Exhibition Floorplan...... 78
Floorplan...... 79
3 DC-B 400G/slot 2.4T/chassis Flexible grid Large Capacity Encryption into ODUk Switch/Router High Security HUAWEI OSN902 OSN902 2 U high, 6 pluggable boards Installation in 19-inch cabinets Front air inlet and rear outlet High Adaptation T-SDN Controller OSN902 Switch/Router Typical Huawei OSN902 application scenario Typical DCI Solution - OSN 902 DC-A Web GUI SNMP NETCONF/CORBA /RESTful/CLI Self-developed 28nm ASIC chip 0.5 W/Gbit Ultra low power Green IT Simplified O&M BBU BBU λ4
λ1 , support 4 access
λ3
λ2 Ring /Chain Network Unidirection sites 50G CPRI bandwidth per access site
IEC 60529 standard
Free of commissioning
Easy OAM Full Outdoor Support Multi-service Large Throughput ------BBU Simplified Network, OTN Everywhere Simplified Network, OTN , 100G/50G , 50G 1+1 protection OSN 810 P2P Network setup, auto-configuration Work path Installed on pole with RRUs
Bidirection without protection Bidirection Huawei C-RAN Solution_CPRI Xpress, OSN 810.pdf 1 2016/8/8 14:19:05 C-RAN Solution - OSN 810 Auto detection of power off, error warning, latency and fault location <30min CPRI, OPSI, GE, 10GE, SDH 15 CPRI Access 120G total capacity “0” site, installation like RRU Satisfy 4 C M Y K CM MY CY CMY Welcome / Bienvenido / Benvingut / Bienvenu / Willkommen / / / Velkommen / / Benvenuto / Welkom / / Tervetuloa / Bem-vindo / Powitanie / / / Välkommen /
Welcome to ECOC 2016 in Düsseldorf! Following Munich in 2000 and Berlin in 2007, Düs- seldorf, Germany will be the next European capital of optical communications, hosting the 42nd edition of the European Conference and Exhibition on Optical Communications held Sep- tember 18th to 22nd, 2016. This well-established conference will provide another milestone in recent scientific and technical progress on materials, devices, and systems for applications in photonic networks, the basic technology for today’s and the future world-wide internet. With attendances and delegates from all over the world, ECOC provides a unique opportunity to stay connected to the latest innovations in the field as well as for networking and interaction that nobody of you should miss.
EOCOC 2016 will start on Sunday, September 18th with six workshops – for warming-up – focusing on hot topics such as elastic optical networking, digital signal processing, architectures for 5G front- and backhaul, nonlinear mitigation techniques, waveguide based devices and ultra-broadband Silicon technology.
The plenary session, open to exhibitors as well, will feature speakers from academia and industry who will share their viewpoints on very relevant topics of present interest and visions on future trends and perspectives. Inspiring talks will be given by Bruno Jacobfeuerborn, CTO of Deutsche Telekom AG and VDE President, Jeffrey Gao, President of the Transmission Network Product Line, Huawei Technologies, Erich Auer, Head of System Engineering, Tesat-Spacecom GmbH & Co.KG and Peter Winzer, Director of Optical Subsystems Research, Nokia Bell Labs.
From student to expert level, from academia to industry, ECOC’s special tutorials, invited and contributed papers will analyse the impact and role of photonic technologies in present and future core, metro and converged access networks addressing the major trends and innova- tions beyond state of the art. From more than 600 submitted papers, the Technical Programme Committee (TPC), composed by world renowned experts and chaired by distinguished scien- tists, constructed an amazing programme for you addressing continuously ongoing hot topics such as spatial division multiplexing (SDM), data-centre communications, advanced modulation Matthias Berger, Nokia, Nuremberg formats, digital signal processing (DSP), super-channel transport and routing, network function virtualization (NFV) as well as rising star topics such as advanced Silicon and InP integrated optics, radio over fibre technologies for emerging 5G mobile communication or visible light communication (VLC). Because of the high interest, free-space optical communication for space and satellite applications was selected as a special topic for this year’s ECOC. New develop- ments and trends on emerging and highly forward-looking research in photonics will be addres- sed in a complementary CLEO (Conference on Lasers and Electro-Optics) focus meeting. The post-deadline paper sessions on Thursday afternoon will give attendees the opportunity to hear new and significant research in rapidly advancing areas at the earliest possible stage.
The conference will be accompanied by an exhibition of leading-edge companies in the photonic system, sub-system and component space. The exhibition is expected to attract more than 300 exhibitors from all over the world. Don’t miss the opportunity to meet them!
Please also do not miss the social events, we have especially organised for you: the Get Ronald Freund, Together, the Welcome Reception and the Conference Dinner for which we selected the Classic Fraunhofer Heinrich Hertz Remise, one of the most attractive locations in and around Düsseldorf for a memorable event. Institute, Berlin To a very large extent, the success of ECOC 2016 will depend on your active participation.
We are looking forward to seeing you in Düsseldorf!
General Chairs Matthias Berger, Nokia, Nuremberg Ronald Freund, Fraunhofer Heinrich Hertz Institute, Berlin
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6 ECOC 2016 Topics
1 Fibres, Fibre Devices and Fibre Amplifiers
Optical fibres, their design, fabrication and characterisation, physics of light propagation in optical fibres, fibre amplifiers and fibre lasers, as well as fibre based devices and specialty optical fibres for telecommunication and other applications.
2 Waveguide and Optoelectronic Devices
Design, fabrication, testing of performances and reliability of devices and components used to generate, amplify, detect, route, interconnect and process optical signals for information transport and processing, routing and interconnecting. Technologies include planar and 3D waveguides, bulk optics, based on various material systems.
3 Digital and Optical Signal Processing
Modeling, design, and implementation of digital and/or optical techniques, for signal processing for long-haul, Metro or access net- works. This area includes digital signal processing algorithms for transmitters and coherent receivers, error correction coding, optical regeneration and any other schemes for impairment mitigation. Analog signal processing subsystems and engines for broadband wireless to fibre segment interfacing and vice-versa are also covered.
4 Subsystems for Optical Networking and Datacoms
Modeling, design, implementation and test of optical, optoelectronic, or electrical subsystems, including line terminals with advanced modulation formats and functionalities, performance monitoring techniques and devices, add-drop multiplexers, optical switches, optical packet routers, optical interconnects, original measurement equipment, and for space applications. In addition, the area considers interconnection devices, subsystems and architectures that address the challenges of Datacom and Computercom.
5 Point-to-Point Transmission Systems
Modeling, design, lab and field implementation of optical transmission fiber links and laser communication in free space, highlighting system level implications of physical impairments and impairment mitigation techniques. Contributions to this area are concerned with aspects such as capacity, reach, flexibility of optical transmission Systems and solutions to overcome the current limitations. Pa- pers illustrating the transmission benefits of novel fibres, devices, subsystems and combined multiplexing techniques are welcome. Quantum communication systems based on optical fibre and free-space optical links are also covered.
6 Core, Metro and Data Center Networks
Modeling, design, architecture, planning, and scaling of optical transport for optical circuit and packet switched core, metro, inter as well as intra data center, and inter satellite networks. This also includes control, orchestration, and management functions, as well as the integration with higher layer network and data center services. It also covers aspects of successful network deployments and field trials.
7 Access, Local Area and Home Networks
Networking aspects of broadband optical access, localarea and home networks. It covers FTTx, passive optical networks, radio-over-fibre systems, optical wireless and free space systems, hybrid wireless/optical solutions, inbuilding networks. It also comprises aspects of cost and energy savings, successful mass deployments and field trials. The topic of optical interconnects is covered within the 4th topical area.
7 ECOC 2016 Committees
ECOC 2016 General Chairs ECOC 2016 TPC Subcommittees
SC 1 - Fibres, Fibre Devices and Fibre Amplifiers Chair: Hans Limberger Kasyapa Balemarthy, OFS, USA Tim Birks, Bath University, UK Peter Ingo Borel, OFS Fitel, Denmark Camille-Sophie Brès, EPFL, Switzerland Benjamin Eggleton, University of Sydney, Australia Matthias Berger, Ronald Freund, Ivana Gasulla, Universitat Politécnica de Valencia, Spain Nokia, Fraunhofer Heinrich Hertz Hans Limberger, EPFL, Switzerland Nuremberg Institute, Berlin Hanne Ludvigsen, Aalto University, Finland
Patrice Mégret, University of Mons, Belgium ECOC 2016 Technical Programme Chairs Francesco Poletti, ORC, UK Kunimasa Saitoh, Hokkaido University, Japan Marco Santagiustina, Universita di Padova, Italy Bernhard Schmauß, Universität Erlangen-Nürnberg, Germany Pierre Sillard, Prysmian, France
SC 2 - Waveguide and Optoelectronic Devices Chair: Andreas Umbach Peter Krummrich, Christian Schäffer, Liam Barry, Dublin City University, Ireland Technische Universität Helmut-Schmidt-Universität, Romain Brenot, Nokia Thales, France Dortmund Hamburg Joe Campbell, Virginia University, USA Antonio Fincato, STMicroelectronics, Italy Myung-Ki Kim, KAIST, Korea ECOC 2016 Local Organising Committee Sang-Shin Lee, Kwangwoon University, Korea Volker Schanz, VDE ITG, Frankfurt Sylvie Menezo, CEA-LETI, France Hatice Altintas, VDE Conference Services, Frankfurt Pascual Muñoz, VLC Photonics, Spain Bert Offrein, IBM, Switzerland Marc Sorel, Glasgow University, UK Current EMC Members Leo Spiekman, Aeon Corporation, USA Yikai Su, Shanghai Jiao Tong, China Per O. Andersson, Ericsson, Sweden Takuo Tanemura, University of Tokyo, Japan Jean-Pierre Hamaide, Nokia, France Hiroyuki Uenohara, Tokyo Institute of Technology, Japan José Capmany, Universidad Politécnica de Valencia, Spain Andreas Umbach, Finisar Corporation, Germany Piero Gambini, ST Microelectronics, Italy Dries Van Thourhout, imec – Ghent University, Belgium Ronald Freund, Fraunhofer Heinrich Hertz Institute, Germany Leif Katsuo Oxenløwe, Technical University of Denmark Jürg Leuthold, ETH Zurich, Switzerland SC 3 - Digital and Optical Signal Processing Andreas Kirstädter, University of Stuttgart, Germany Chair: Helmut Grießer Ton Koonen, COBRA TU Eindhoven, The Netherlands Peter Andreksson, Chalmers University of Technology, Sweden David Richardson, ORC University of Southampton, UK Dimitrios Apostolopoulos, National TU Athens, Greece Giancarlo Prati, Scuola Superiore S. Anna, Pisa, Italy Antonella Bogoni, CNIT, Italy Christian Lerminiaux, University of Troyes, France John Cartledge, Queen‘s University, USA Will Stewart, University of Southampton, UK Andrew Ellis, Aston University, UK Peter Van Daele, IMEC iMinds- Ghent University, Belgium Helmut Grießer, ADVA Optical Networking, Germany Yves Jaouën, IMT - Telecom Paritech, France Leif Oxenløwe, Technical University of Denmark Current ECOC IAC Members Valerio Pruneri, Institut de Ciencies Fotoniques, Spain Rod Alferness, University of California, Santa Barbara, USA Masatoshi Suzuki, KDDI R&D Laboratories, Japan Simon Fleming, University of Sydney, Australia Benn Thomsen, UCL, UK Toshio Morioka, Technical University of Denmark Naoya Wada, National Institute of Information and Communication Jintong Lin, Beijing University of Posts and Telecommunications, China Technology (NICT), Japan Robert Tkach, Nokia Bell Labs, USA Ping-Kong Alex Wai, Hong Kong Polytechnic University, Hong-Kong
8 ECOC 2016 Committees
ECOC 2016 TPC Subcommittees ECOC 2016 TPC Subcommittees
SC 4 - Subsystems for Optical Networking and for Datacoms SC 7 - Access, Local Area and Home Networks Chair: Andreas Leven Chair: Dirk Breuer Laurent Bramerie, ENSSAT/Université de Rennes 1, France Kota Asaka, NTT Network Service Systems Laboratories, Japan Michael Galili, Technical University of Denmark Dirk Breuer, Deutsche Telekom AG, Germany David Hillerkuss, ETH Zurich, Switzerland Guillermo Carpintero, Universidad Carlos III de Madrid, Spain Toshihiko Hirooka, Tohoku University, Japan Philippe Chanclou, Orange Labs, France Andreas Leven, Nokia, Germany Stefan Dahlfort, Ericsson, Sweden Mario Martinelli, Politecnico di Milano, Italy Roberto Gaudino, Politecnico di Torino, Italy Shu Namiki, National Institute of Advanced Industrial Science Yuefeng Ji, Beijing Univ of Posts and Telecommunications, China and Technology, Japan Kwangjoon Kim, ETRI, Korea Richard Pitwon, Xyratex, UK Junichi Nakagawa, Mitsubishi Electric, Japan Oded Raz, COBRA - TU Eindhoven, Netherlands Derek Nesset, BT, UK Clint Schow, University of California, USA Yan Shi, Genexis, Netherlands Xin Yin, imec – Ghent University, Belgium Alexandros Stavdas, University of Peloponnese, Greece Wende Zhong, Nanyang Technological University, Singapore Eduward Tangdiongga, COBRA - TU Eindhoven, Netherlands Dora Van Veen, Nokia, USA Chia-Chien Wei, National Sun Yat-Sen University, Taiwan SC 5 - Point-to-Point Transmission Systems Chair: Klaus Petermann Gabriel Charlet, Nokia, France René-Jean Essiambre, Nokia, USA Yann Frignac, Institut Mines-Télécom/Télécom SudParis, France Giancarlo Gavioli, Nokia, Italy Magnus Karlsson, Chalmers University of Technology (CTH), Sweden Gordon Ning Liu, Huawei Technologies Co. Ltd., China Yutaka Miyamoto, NTT Corporation, Japan Chigo Okonkwo, COBRA - TU Eindhoven, Netherlands Hiroshi Onaka, Fujitsu, Japan Klaus Petermann, Technische Universität Berlin, Germany Werner Rosenkranz, Christian-Albrechts-Universität Kiel, Germany Rob Smets, SURFnet, Netherlands
SC 6 - Core Metro and Data Center Networks Chair: Sébastien Bigo Achim Autenrieth, ADVA Optical Networking, Germany Sébastien Bigo, Nokia Bell Labs, France Steinar Bjørnstad, Trans Pocket AS, Norway Piero Castoldi, Scuola Superiore Sant’Anna, Italy Carlo Cavazzoni, Telecom Italia, Italy Juan Pedro Fernandez Palacios, Telefonica, Spain Kiyoshi Fukuchi, NEC, Japan Andreas Gladisch, Deutsche Telekom Laboratories, Germany Paola Iovanna, Ericsson R&D, Italy Nobuhiko Kikuchi, Hitachi, Japan Raul Muñoz, Centre technologic de telecommunicacions de catalunya, Spain Mario Pickavet, iMinds – Ghent University, Belgium Dimitra Simeonidou, University of Bristol, UK Jesse Simsarian, Nokia, USA Ioannis Tomkos, Athens Information Technology Center, Greece Elaine Wong, University of Melbourne, Australia Lena Wosinska, KTH Royal Institute of Technology, Sweden
9 Training Courses Sunday, September 18, 2016 • 09:00 - 13:00
09:00 - 13:00 • Room 110 09:00 - 13:00 • Room 112 Training Course: Training Course: Laser systems on Photonic Integrated Circuits ePIXfab Training cource on the state of the art in Silicon Phonotnics
Training Course Leader: Dr. Erwin Bente (COBRA Institute), (NL) Course aim To provide an insight into the field of Silicon photonics by looking This training course is an introduction to the fundamentals and into the recent progres made in this field and challenges associated the widely varying possibilities and applications of integrated se- with it. The course will also provide an understanding on how to miconductor laser systems that can be realized using open enter the field and start prototyping a Silicon photonics IC. access photonic integrated circuits based on Indium Phos- phide (InP) substrates. Industrially proven InP technology platforms Target audience have in recent years been opened up for use by anyone interested Industrial/academic engineers or researchers, with at least a Basic in realizing such photonic integrated circuits. background of photonic Integration, who wish to acquire knowledge This course provides a comprehensive introduction to designers about the current art in Silicon photonics. wishing to create integrated circuits which include lasers, ampli- fiers, phase modulators and a range of other important building Course Description blocks on the JePPIX photonic integration technology platforms. Future developments in the field of datacom/telecom and sensing This training course will complement the presentations at the Eu- will require a high level of photonic integration. Silicon Photonics ropean Photonic Integration Forum 2016 to be held in conjunction is widely seen as a key enabling technology as it leverages from with the Exhibition. established CMOS technology allowing low cost manufacturing In the first part of this course the basics of the integration technolo- even for moderate volumes. While the field was predominantly a gy and the fundamental optical circuit components are discussed. research field up to a few years ago, we now see the emergence Particular emphasis will be on the semiconductor optical amplifier. of industrial silicon photonics products ranging from short-reach In the second part, the basic principles and an approach for desig- datacom transceivers to high capacity coherent transceivers and ning laser cavities are presented. This is followed by a presentation from optical coherence tomography systems to lab-on-a-chip devices. of dynamical modeling and simulation techniques. This will b e illus- The science and technology of Silicon Photonics has made tre- trated with examples for lasers and photonic circuits. Continuous mendous progress since its inception. But has it answered all the wave, widely tunable and pulsed laser systems will be described. challenges associated with it? The main theme of this course is to answer this question by looking into recent progress and break Benefits and Learning Objectives throughs associated with Silicon Photonics and open challenges. Understanding the basic principles used in InP based photonic Specifically the course will address: integration technology Recent progress made on component level development in Understanding how to create single chip laser circuits from Silicon Photonics photonic building blocks Recent application specific progress made by Silicon Photo- Insight into the fundamentals and a design methodology for nics, both in the field of high speed transceivers as well as in integrated laser cavities the field of sensing Recent evolutions in the prototyping and manufacturing Understanding how to integrate multiple lasers on the same platforms for Silicon Photonics as well as the complementing chip and with other circuits services and tools (design, MPW-service, packaging...) Developing an overvew of possible applications through ex- amples of realized circuits Program Learn about open access InP technology platform capabilities 09:00 - 09:40: Recent developments in Silicon Photonics components and building blocks Intended Audience 09:40 -10:20: State of the art in Silicon Photonics Transceivers The course is intended to give an introduction to the possibilities 10:20 -10:30: Short break of open access InP photonic integration technology. The course 10:30 -11:00: State of the art in sensing based on Silicon will benefit graduate students as well as industrial and academic Photonics researchers who are considering or engaged in the design and ap- 11:00 -11:30: Evolutions in Silicon Photonics Technology plication photonic integrated circuits. platforms, Services and Tools Practical Details Lecturers (provisional) Participation is free of charge but registration is required. Registrati- Prof. Dries Van Thourhout (Ghent University - imec) on is made by sending an email to coordinator(at)jeppix.eu. Further Dr. Lars Zimmermann (IHP) information on the training and forum will be avaiable at jeppix.eu Prof. Roel Baets (Ghent University - imec) Dr. Abdul Rahim (Ghent University)
Practical Details The training course is organized by the European Silicon Photonics Alliance ePIXfab (www.epixfab.eu). Participation is free of charge for the ECOC participants, but registration is mandatory. The cour- se will take place at the venue of ECOC2016 on Sunday Septem- ber 18 from 09:00-11:30. The number of seats is limited. For regis- tration an email should be sent to [email protected]. Requests for further details about the training course can also be addressed to the course coordinator Dr. Abdul Rahim (abdul.ra- [email protected], phone: +32-9-331 48 43) 10 EU Symposium Sunday, September 18, 2016 • 09:00 - 18:00
09:00 - 18:00 • Room 14 4th Optical Interconnect in Data Centers EU-Symposium
Tolga Tekin (Fraunhofer IZM/TU Berlin, Germany) polymers, glass, III-Vs, and plasmonics will enable generic building Richard Pitwon (Seagate, United Kingdom) blocks (transmitters, modulators, receivers, switches, optochips, Nikos Pleros (AUTH, Greece) multi- and single-mode optical PCBs, chip- and board-to-board Emmanouel Varvarigos (CTI ‘Diophantus’, Greece) connectors) to extend the performance beyond Tb/s and to reduce Dimitris Apostolopoulos (ICCS/NTUA, Greece) the energy by more than 50%. PhoxTroT is a European Union-funded IP project. Grant agreement Abstract no: 318240. European Commission, Seventh Framework Program The symposium is focused on high-performance, low-energy (FP7), ICT - Information and Communication Technologies; and cost and small-size optical interconnects across the different http://cordis.europa.eu/fp7/ict hierarchy levels in data center. The proliferation of mobile data applications is causing a dramatic shift in the location in which data is stored from client based or mobile storage to Cloud data centres Introduction with projections that around 60 % of all data will be stored in the Cloud by 2020. Tolga Tekin (PhoxTroT) The projected increase in capacity, processing power and band- width density in data centre environments must be addressed by Session 1: The end-user perspective the migration of high density optical interconnect into the data communication enclosures. The conversion point between electri- Bart van Caenegem (European Commission, Belgium) cal to optical interconnects will move ever closer to the on-board Richard Pitwon (Seagate, UK) processing complexes, whether these be CPUs, data storage Katharine Schmidtke (Facebook) controllers, FPGAs, routers or switches. This migration is already Lê Nguyên Bình (Huawei Technologies Ltd., GER) strongly reflected in the research, development and strategic acti- Susannah Heck (Kaiam Corporation, USA) vities of mainstream organisations in the data centre and broader ICT space and the emergence of a new technology eco-system. −−Round table discussion This technology migration is already strongly reflected in the re −−Coffee Break search, development and strategic activities of mainstream orga- nisations in the data centre and broader ICT space and the emer- Session 2: Bringing technology to market I gence of a new technology eco-system. Motivated by recent breakthroughs and emerging technologies in Elad Mentovich (Mellanox) short reach optical interconnect and the evolution of data centre Marika Immonen (TTM Mail) architectures, this symposium aims to highlight the latest achie- Joni Mellin (ams) vements on optical system solutions and architectures, that are Kobi Hasharoni (Compass EOS) placing photonics among the key enabling technologies of data- Kazuhiko Kurata (PETRA) com and computercom evolution. −−Round table discussion We intend to draw out and discuss the key technology enablers −−Lunch Break and inhibitors to widespread commercial proliferation of photonic interconnect in “mega” data centre environments and how the opti- Session 3: Bringing technology to market II cal interconnect community can collectively help to address these. The topics addressed will centre on passive and active embedded Hideyuki Nasu (Furukawa) photonic interconnect technologies including optical circuit boards, Charles Baudot (ST Micro) polymer and glass waveguides, III-Vs, silicon photonics, photonic Felix Betschon (Variooptics) crystals and plasmonics in data centers. Loukas Paraschis (Infinera) Peter De Dobbelaere (Luxtera) Previous Symposia −−Round table discussion 3rd Optical Interconnect in Data Centers Symposium, −−Coffee Break ECOC 2015, Valencia 2nd Optical Interconnect in Data Centers Symposium, Session 4: What comes next? ECOC 2014, Cannes 1st Optical Interconnect in Data Centers Symposium, Harold Haas (University of Edinburgh, UK) Laser Optics Berlin 2014 Paraskevas Bakopoulos (National TU Athens, GR) Takaaki Ishigure (Keio University, JP) Bert Offrein & Roger Dangel (IBM Research) EU PhoxTrot Huiyun Liu (UCL, UK) PhoxTroT.eu is focusing on on-board, board-to-board and rack-to- −−Round table discussion rack optical interconnects. The goal of this large-scale EU research effort is the deployment of optimized technologies to tailor dedi- cated interconnect layers towards high-performance, low-energy and low-cost Data Center and High-Performance Computing Systems. A „mix & match“ technology by synergizing the different fabrication platforms such as CMOS electronics, Si-photonics,
11 Workshops Sunday, September 18, 2016 • 13:30 - 18:00
13:30 - 18:00 • Room 18 + 19 WS 1: Progress and Challenges in Signal Processing and Channel Modelling for Space Division Multiplexed Trans- mission Systems
Organizer: Benn Thomsen (UCL, UK)
Content
To date the most impressive single fibre capacity results have uti- Session 1: Approaches to DSP free MDM lised Space Division multiplexing either within multiple cores or within a single multimode core or combination thereof. In the 12 Optical MIMO Processing (in Modal Basis) for Direct- years since the Mode Division Multiplexing (MDM) flavour of Space Detection MDM Division Multiplexing (SDM) for coherent systems was first propo- Karthik Choutagunta (Stanford University, USA) sed and demonstrated by Hsu et al. we have come a considerable way. From Hsu’s first demonstration of 2x2 MIMO at 100Mbit/s Elliptical core fibres MDM without DSP per channel over 100m of 62.5um multimode fibre, to the most Ezra Ip (NEC Laboratories America, USA) recently demonstrated 30x30 MIMO at 60Gbit/s per channel over 23 km of specially designed Few Mode Fibre by Fontaine, et al. OAM fibres for DSP free MDM These impressive results have all used offline MIMO processing to Siddharth Ramachandran (Boston University, USA) demonstrate the potential capacity of such systems, the challenge now is to develop real-time signal processing technology to show that such systems can outperform conventional single mode fibre Session 2: Channel Modelling and Implementation approaches and make this a compelling technology to deploy. Multimode fibre channel modelling in the linear and This workshop aims to present the state of the art in both receiver nonlinear regime and transmitter based signal processing for spatially multiplexed Georg Rademacher (TU Berlin, DE) systems, and in channel design/modelling of multimode fibre sys- tems. In particular it will aim to: Multimode optical amplification performance and implications for channel equalisation • Provide a summary of the state of the art in both fibre design, Yongmin Jung (Optoelectronics Research Center, University of amplification and signal processing. Southamption, UK) • Identify where the key implementation challenges lie. • Explore solutions to these challenges. Session 3: MIMO-DSP
A key question in the design of MDM systems is whether to en- The challenges of mode division multiplexed transmission gineer the channel to minimise or maximise the modal mixing and with 30+ modes the implications that this is likely to have on system performance Nick Fontaine (Nokia Bell Labs, USA) and the MIMO DSP complexity. This workshop will present views from both sides of this design choice. Optimising MIMO-DSP for different crosstalk and distance regimes Kai Shi (University College London (UCL), UK)
Taking MIMO-DSP from offline to online implementation Sebastian Randel (Karlsruhe Institute of Technology, DE)
15:30 - 16:00 Coffee Break | Foyer CCD |
18:00 - 19:30 Get Together | Wintergarden Restaurant CCD | 12 Workshops Sunday, September 18, 2016 • 13:30 - 18:00
13:30 - 18:00 • Room 17 WS 2: Exploring the real value of flexible optical networks
Organizers: Dimitrios Apostolopoulos (National Technical University of Athens, GR), Camille Delezoide (Nokia Bell Labs, FR)
Content
The world’s insatiable demand for bandwidth is stretching physi- Session 1 cal layer capacity; it is only a matter of years before we are faced with throughputs that are beyond the reach of current static optical Flexible optical networks: Latest concepts and networks. Moreover, the changing nature of traffic toward more developments volatile patterns renders the conventional approach of over-provi- Lena Wosinska (KTH Royal Institute of Technology, SE) sioning of resources increasingly inefficient. Operators are finding that room for economically viable growth is shrinking. Flexible opti- Programmable, multi-rate optical transmission systems cal networks are being touted as a means of avoiding the capacity enabling flexible optical networks crunch and increasing costefficiency, through the introduction of Antonio Tartaglia (Ericsson Telecomunicazioni, IT) adaptability in modulation format and elasticity in spectrum utiliza- tion, by dropping the fixed grid and allowing dynamic adjustment Advances in DSP-based optical performance monitoring of throughput and wavelength allocation. Maxim Kuschnerov (Coriant, DE)
Realizing flexible networks will require a combination of disruptive Quality of Transmission (QoT) modelling and monitoring and cross-layer innovations. In addition to multi-rate, multi-format, Andrea Carena (Politecnico di Torino (PoliTo), IT) malleable-spectrum optical components, also needed are the tools to enable programmability and dynamic operation: Spectrally-effi- Multiflow transponders for elastic networks cient modulation formats, novel DSP for linear and nonlinear im- Christos Kouloumentas (NTUA, GR) pairment monitoring and mitigation, enhanced transmission and link-engineering approaches which take physical impairments into Panel Discussion (~20 mins) consideration, as well as innovative dynamic control plane sche- mes. Session 2 Despite the promises, the challenge remains to precisely quantify the benefit -if any- of flexible deployments. For it to be a worthwhile Network and hardware virtualization towards a smart investment that will encourage market uptake, the additional fun- photonic cloud ctionality must ultimately benefit an operator’s bottom line, versus Reza Nejabati bati (University of Bristol, UK) static-operation alternatives. The role of elasticity in the future network This workshop aims to highlight the latest developments in flexible Kevin Sparks (Nokia, USA) optical network design, control and operation, focusing on the im- pact of novel subsystems leveraging coherent technology and soft- Techno-economic analysis of flexible optical network ware-defined operation. The challenges of design and real-world deployment implementation will be critically explored, and approached from all David Boertjes (Ciena, USA) facets and all layers. Reaping the benefits of flexibility – A telecom operator’s The workshop will include a moderated panel discussion on what perspective it will take to consolidate these emerging technologies into viable, Matthias Gunkel (DT, DE) commercial systems, attempting to gauge potential benefits, as well as costs, for telecom operators. What “flexible” features do we need in optical networks, and why? Gaya Nagarajan, Giuseppe Rizzelli (Facebook, UK)
Panel Discussion (~20 mins)
15:30 - 16:00 Coffee Break | Foyer CCD |
18:00 - 19:30 Get Together | Wintergarden Restaurant CCD | 13 Workshops Sunday, September 18, 2016 • 13:30 - 18:00
13:30 - 18:00 • Room 16 WS 3: Short range optical transmission for emerging 5G fronthaul, DCI and Metro Networks
Organizers: Gordon Ning Liu (Huawei Technologies Co. Ltd., China), Volker Jungnickel (HHI, Germany)
Content
With the rapidly increasing data traffic in 5G mobile fronthaul, data Session center interconnect (DCI), and metro networks, the growing band- width demand from high speed short range optical transmission will Requirements and emerging trends be much more than that from the long-haul optical transmission. Xiang Zhou (Google Inc., USA) Data center interconnection Especially, when using conventional digital transmission such as CPRI in CRAN architecture, 5G performance targets would imply Emerging Technologies for Metro Optical Networking a severe capacity crunch. Besides, there are tremendous amounts Xiang Liu (Huawei, USA) of optical equipments in short range optical transmission systems compared with the long-haul transmission systems and thus will Photonic Integration for Applications from Datacenter induce large cost and huge energy consumption. Therefore, the to DWDM power and cost efficiency should be key considerations for short Steven Wallace (Lumentum, Canada) range optical transmission besides the transmission performance. The workshop aims to bring together internationally recognized ex- Transmission schemes for future short reach systems perts from network operators, equipment/component vendors and Chao LU (Hong Kong Polytechnic University, Hong Kong) academia in order to provide a comprehensive overview of this im- portant field for next-generation short range optical transmission. Advanced modulation formats for 5G fronthaul WDM-PON Some demands, transmission schemes and optical components systems technologies which can be shared by 5G fronthaul, DCI and metro Annika Dochhan (ADVA Optical Networking SE, Germany) networks will be discussed in the first session. Then in the second session, the workshop will be focused on several new concepts, The required Fixed Access Network evolutions e.g. the Next Generation Fronthaul Interface (NGFI) based on Ana- Philippe Chanclou (Orange Labs, France) log or Ethernet technologies and using a new functional split bet- ween BBU and RRH. Making fronthaul efficient without killing it Frank Effenberger (Huawei Technologies, USA)
Converged, Ethernet-based next generation fronthaul Nathan Gomes (University of Kent, UK)
TBD Thomas Pfeiffer (Nokia Bell Labs, Germany)
15:30 - 16:00 Coffee Break | Foyer CCD |
18:00 - 19:30 Get Together | Wintergarden Restaurant CCD | 14 Workshops Sunday, September 18, 2016 • 13:30 - 18:00
13:30 - 18:00 • Room 15 WS 4: Fiber and waveguide based devices for 2 micron, is there the need?
Organizers: Camille Brés (EPFL, Switzerland), Periklis Petropoulos (University of Southampton, UK)
Content
The workshop will put forward a discussion on the recent and rapid Session development of fiber/waveguide based sources and devices for the short wave infrared (2 micron), and will debate whether there is Optical Components for enabling 2um applications a real need for this technology, especially in the context of telecom- Gary Stevens (Gooch and Housego, UK) munications. Amongst others, we are seeing the emergence of fi- berized components, off the shelf sources, high speed modulators, Semiconductor laser diodes and applications in the 2um directly modulated sources as well as demonstrations of 2 micron wavelength region communications in hollow core fibers. Is there a real potential or Brian Kelly (Eblana Photonics, UK) is it simply interesting physics? What components/technological developments/improvements would be needed to make the tech- Rare-earth doped fibre amplifiers in the 2um waveband: nology an implemented reality? Challenges and opportunities Shaif-Ul Alam (University of Southampton, UK) Discussion on non-telecom applications will also be welcome, e.g. on the development and potential of fiber-based supercontinuum III-V-on-silicon photonic integrated circuits for the 2um sources/combs and, Mid-IR oscillators. While many great and in- wavelength range teresting experimental demonstrations have been done, are the- Gunther Roelkens (University of Gent, Belgium) re the required applications and are fiber/waveguide approaches competitive? Photonic chip–based optical frequency comb for the 2 micron band This workshop aims to present the enabling technologies by ex- Michael Geiselmann (Ecole Polytechnique Fédérale de Lausanne, ploring their strengths, weaknesses and level of maturity, as well Switzerland) as to explore applications and challenges that these technologies can address. Thulium doped fiber femtosecond laser: markets and applications Nicolas Ducros (Novae, France)
Can the 2 micron window solve the capacity crunch? Noise MacSuibhne (Aston University, UK)
15:30 - 16:00 Coffee Break | Foyer CCD |
18:00 - 19:30 Get Together | Wintergarden Restaurant CCD | 15 Workshops Sunday, September 18, 2016 • 13:30 - 18:00
13:30 - 18:00 • Room 110 WS 5: Next Generation Ultra-Broadband Silicon Photonics Based Integrated Circuits
Organizers: Guang-Hua DUAN (III-V Lab, France) Abderrahim Ramdane (CNRS, France) Johann Peter Reithmaier (University Kassel, Germany) Jeremy Witzens (RWTH Aachen University, Germany)
Content
Increasing front panel data densities of data center switches as Session 1: Light Sources on Silicon and Comb Laser Based well as increasing reach and data rate of data center state-of-the- Transceivers art optical interconnects has motivated the emergence of Silicon Chair Guang-Hua Duan (III-V Lab, France) Photonics based integrated circuits. In parallel, metro and long- haul networks require transceivers with reduced size and power Advances on efficient light sources on silicon consumption. Silicon photonics is also a candidate for these mar- John Bowers (UCSB, USA) kets. This Workshop will gather prominent speakers from industry and academia and intends to give an update on the state of the art Efficient quantum dot based light sources for silicon on Silicon Photonics based integrated circuits, with emphasis on photonics the following two key areas: Johann Peter Reithmaier (University Kassel, Germany)
• Integration of efficient laser source solutions for silicon Advances on heterogeneous integration of III-V on silicon photonics with advanced material systems such as quantum Segolene Olivier (CEA LETI, France) dots. • Silicon based Photonic Integrated Circuits implementing High capacity silicon photonics based transceivers broadband wavelength division multiplexing. Young-Kai Chen (Nokia Bell Labs, USA)
Silicon photonics based high capacity transceivers with Organization hybridly integrated quantum dot lasers Yasuhiko Arakawa (University Tokyo, Japan) This workshop is organized in the framework of the EU funded projects BIG PIPES “Broadband Integrated and Green Photonic First panel discussion Interconnects for High Performance Computing and Enterprise Systems” and SEQUOIA “Energy efficient Silicon emitter using heterogeneous integration of III-V quantum dot and quantum dash Session 2: High Capacity silicon photonics based materials”. Transceivers and Super-Channel Architectures Chair Abderrahim Ramdane (CNRS, France) World-wide leading experts will be invited to give talks. The talks, complemented by BIG PIPES and SEQUOIA presentations, will be Combbased Silicon Photonics transmitters for short reach followed by a Q&A session involving a panel of all the Speakers. interconnects Jeremy Witzens (RWTH Aachen, Germany)
Highly spectrally efficient optical links Liam Barry (Dublin City University, Ireland)
Scaling datacenter optical interconnects Elad Mentovich (Mellanox Technologies, Israel)
Super-channel optical interconnects for datacenters Jörg-Peter Elbers (ADVA Optical Networking SE, Germany)
Silicon photonics based coherent transceivers Dr. Christopher Doerr (Acacia Communications, USA)
Second panel discussion
15:30 - 16:00 Coffee Break | Foyer CCD |
18:00 - 19:30 Get Together | Wintergarden Restaurant CCD | 16 Workshops Sunday, September 18, 2016 • 13:30 - 18:00
13:30 - 18:00 • Room 112 WS 6: Extending reach in long-haul WDM systems: What can be achieved with nonlinear mitigation techniques in fully loaded WDM transmission?
Organizers: Giancarlo Gavioli (Nokia Micro-Electronics Labs, Italy) David Millar (Mitsubishi Electric Research Laboratories, USA) Robert Killey (University College London, UK)
Content
Digital coherent technology has enabled compensation of linear Session 1 fiber impairments and the introduction advanced error-correction coding in optical transmission systems. Fiber nonlinearity has thus How much should we expect to gain from nonlinear become the dominant obstacle towards achieving the ultimate mitigation? capacity in optical transmission systems. Ronen Dar (Nokia Bell Labs, Holmdel, USA)
Over the recent years, different techniques have been proposed Overview of Nonlinearity Mitigation Techniques to mitigate for nonlinearities by means of digital and optical signal Rene-Jean Essiambre (Nokia Bell Labs, Holmdel, USA) processing and demonstrated to be effective toward intra-channel nonlinear distortion. This includes both digital and optical techniques Implementation considerations of digital-domain nonlinear for nonlinear channel inversion, or optimization of transmission pa- compensation in commercial systems rameters such as symbol rate and symbol distribution to enable Qunbi Zhuge (Ciena, Ottawa, Canada) nonlinear tolerant transmission. Digital integrated technology is now expected to be mature enough to enable the implementation Digital Nonlinear Compensation for 400G Transceiver with of such complex algorithms. Higher Order Modulation Zhenning Tao (Fujitsu Labs, Beijing, China) However, recent advancements in fiber propagation modeling have quantified and demonstrated that inter-channel nonlinearities Nonlinearity compensation benefits in experiments over become the dominant effect in fully loaded WDM transmission transoceanic distances using offline processing systems with implication on the effectiveness of intra-channel Alexei Pilipetskii (TE Subcom, Eatontown, USA) nonlinear mitigation. Commercial use cases of fiber nonlinearity compensation This workshop intends to provide a forum of debate on the Danish Rafique (ADVA, Germany) effectiveness of nonlinear mitigation techniques in fully loaded WDM transmission and to offer a comparative overview in terms NLC in Operator Networks - What can it add? of performance gain and technology complexity of the different Carsten Behrens (Deutsche Telekom, Germany) solutions for digital and optical nonlinear mitigation in the contest of long-haul dense WDM transmission systems. Session 2
Non-Linearity Mitigation by Multi-Subcarrier Transmission Targets: and Joint DSP Post-Processing Pierluigi Poggiolini (Politecnico di Torino, Italy) 1) This workshop intends to provide a forum of debate on the effectiveness of nonlinear mitigation techniques in fully loaded Better Compensation with Optical Phase Conjugation? long-haul WDM transmission systems. Andrew Ellis (Aston University, Birmingham, UK) 2) Provide a comparative overview in terms of performance gain Nonlinear signal noise interaction in fully loaded systems and technology complexity of the different solutions for digital Paolo Serena (Università di Parma, Italy) and optical nonlinear mitigation. 3) Address the complexity-cost and maturity of digital integrated What else can be done? Inter-channel nonlinear mitigation technology for implementation of nonlinear mitigation algorithms. and optical nonlinear mitigation Marco Secondini (Scuola Superiore Sant’Anna, Pisa, Italy) 4) Provide a theoretical review of the dominant nonlinearities and quantify the impact of intra-channel and inter-channel distortion Performance of nonlinearity tolerant constellations in fully in the contest of fully loaded WDM transmission Systems. loaded WDM systems John Cartledge (Queen‘s University, Kingston, Canada)
PMD and wideband nonlinearity compensation: Next bottleneck or fundamental limitation? Gabriele Liga (University College London, UK)
15:30 - 16:00 Coffee Break | Foyer CCD |
18:00 - 19:30 Get Together | Wintergarden Restaurant CCD | 17 Keynote Presentations Monday, September 19, 2016 • 10:00 - 12:30
10:00 - 12:00 • Room 1 Conference Opening and Keynotes
Matthias Berger, Nokia, Nuremberg; Ronald Freund, Fraunhofer Heinrich Hertz Institute, Berlin
10:15 - 10:45 • Room 1
„Optical Communication – Building the basis for best Customer Experience” Bruno Jacobfeuerborn CTO of Deutsche Telekom AG and VDE President
Abstract: The new integrated telecommunications standard 5G will enable communication in real time that is available anywhere and anytime. It will efficiently associate 50 billion „things“ and billions of customers, while crating various revo- lutionary use cases from autonomous driving to ultra HD Virtual Reality applications. Therefore, our industry is facing an tremendous demand regarding bandwidth and latency, that can only be met if we bring two things closer to the custo- mer: The intelligence of the network and fiber lines. To accelerate the extension of the fiber network and increase the cost efficiency, Deutsche Telekom is driving new che- aper alternatives to standard civil engineering. The aim is to create a portfolio of various installation techniques that can be combined and implemented in the most efficient manner, in consideration of the local basic conditions and customer needs. As an integrated operator, Deutsche Telekom is well positioned to incorporate the demands of different customer seg- ments into a joint and integrated fiber target architecture. Although boundaries between fixed and mobile access dissolve more and more, a strong fiber-based network will always remain the fundament of providing sustainable telecommuni- cation Services. Bruno Jacobfeuerborn: Director of Technology Telekom Deutschland GmbH and Chief Technology Officer (CTO) of Deutsche Telekom AG. Bruno Jacobfeuerborn has been Director of Technology at Telekom Deutschland GmbH since April 2010. In addition, he is Chief Technology Officer (CTO) of Deutsche Telekom AG, a position he has been holding since February 2012. Since 1989, Bruno Jacobfeuerborn has held various managing positions at Deutsche Telekom AG. From 2002 to 2007, Bruno Jacobfeuerborn was a member of the management team in his capacity as Managing Director of Technology, IT, Procurement and, until 2004, Customer Service at T-Mobile Netherlands in The Hague. At the same time, he headed the International Service Management unit at T-Mobile International. Subsequently, he was a member of the management team and Managing Director of Technology, IT and Procurement at Polska Telefonia Cyfrowa in Warsaw until June 30, 2009. Since July 1, 2009, Bruno Jacobfeuerborn has been responsible for Technology (both mobile and fixed network) in Germany.
10:45 - 11:15 • Room 1
OTN to CO, Key Implementation of Network Simplification Jeffrey Gao President, Transmission Network Product Line, Fixed Network Product Line, Huawei Technologies
Abstract: What is main challenges to transport network brought by new service traffic, such as 4K/8K, 5G and cloud service? How carrier work on their network architecture evolution driven by 3 main factors including new services, new techno- logies and cost reduction? Huawei’s understanding and strategy on network transformation and latest technologies to face these challenges and fit for the evolution requirement. Jeffrey Gao is since January 2015 the president of Transmission Network Product Line. From February 2011 to 2014, he was the Chief Strategy and Marketing Officer of Huawei Western Europe Region. From year 2008 to 2011, he was the Chief Strategy and Marketing Officer of Huawei Fixed Network Business Unit. Jeffrey Gao has lead the innovation cooperation project between VDF and Huawei since 2008, and there are many success case include BBNS, IP MW and PTN project. From year 2003 to 2008, Mr. Gao was the head of Huawei Datacom PLM, after joined in Huawei Technologies in 1997 Mr. Gao was working in Optical Transport area until 2003, Mr. Gao was also one of the winners of National Science and Technology Achievement Award of China in 2001 and 2002 respectively.
18 Keynote Presentations Monday, September 19, 2016 • 10:00 - 12:30
11:15 - 11:45 • Room 1
Optical Communication in Space Erich Auer TETS, Head of System Engineering, Tesat-Spacecom GmbH & Co.KG, Backnang
Abstract: The keynote will give an overview on space communication in general and focus specifically on optical com- munication in space. Todays spacecom is still dominated by radio transmission in all applicable and regulated frequency bands. Optical communication in space opens virtually unlimited capacities without regulations. Comparisons between radio and optical communication in space will be given. The current status of optical communication in space will be out- lined, giving some examples of what has already been implemented and demonstrated. An overview of the features and technologies of laser communication terminals for space will be presented. The keynote will conclude with an outlook on future applications of optical communication in space and on the needs for future, space proven technologies in this field. Erich Auer is an Electrical Engineer graduated and did his PhD at the University of Stuttgart. He works since April 2009 as Chief Technical Officer (CTO) for TESAT-Spacecom, a 100% daughter company of Airbus Defence & Space GmbH. TESAT, located in Backnang/Germany, is one of the leading suppliers of space communication payload equipment for satellites. From 2006 to 2009 he worked for Ericsson as Head of the Fixed Wireless R&D Engineering Germany. In the time frame from 2000 to 2006 he held the position as Head of the R&D Organisation of Marconi Communications in Backnang/Germany. In the years from 1995 to 2000 he was with Bosch Telecom as Head of the R&D Microwave Radio Systems and from 1988 to 1995 he worked for ANT Communications as Division Head in the field of Space Communi- cation. He is married and has two adult daughters.
11:45 - 12:15 • Room 1
From scaling disparities to integrated parallelism: A decathlon for a decade Peter J. Winzer Director, Optical Subsystems Research, Nokia Bell Labs, Holmdel, NJ
Abstract: The evolution of network traffic and communication technologies over the past 10+ years and their projections into the coming 10+ years reveal increasingly pronounced scaling disparities between traffic demands, routing capabili- ties, interface rates, and system capacities. Within a decade, we expect the need for 10+ Terabit/s transponders working over Petabit/s systems and networks. We discuss 10 technology paths to move our industry towards these bold goals.
Peter J. Winzer received his Ph.D. from the Vienna University of Technology, where he worked on space-borne lidar and laser communications for the European Space Agency. At Bell Labs since 2000, he has focused on many aspects of fiber-optic communications, including advanced optical modulation multiplexing, and detection. He has contributed to several high-speed optical transmission records from 100 Gb/s to 1 Tb/s and has been promoting spatial multiplexing to overcome the optical networks capacity crunch. He has widely published and patented and is actively involved with the IEEE Photonics Society and the Optical Society of America (OSA), including service as Editor-in-Chief of the IEEE/ OSA Journal of Lightwave Technology, Program Chair of ECOC 2009, and Program/General Chair of OFC 2015/17. Dr. Winzer is a Bell Labs Fellow, a Fellow of the IEEE and the OSA, and a Thomson Reuters Highly Cited Researcher.
19 Tutorials
Monday, September 19, 2016, 14:00-15:00 Room 18+19 Tuesday, September 20, 2016, 11:00-12:00 Room 18+19 SC 1 - Fibres, Fibre Devices and Fibre Amplifiers SC 3 - Digital and Optical Signal Processing
M.1.A.1 Tu.2.A.1 High Power Fibre Lasers: Fundamentals, Digital Signal Processing for Multilevel Recent Progress and Challenges Modulation Formats Michalis N. Zervas (Optoelectronics Research Seb J. Savory (University of Cambridge, UK) Centre, University of Southampton, UK)
Michalis N. Zervas holds a Royal Academy of Engineering Chair Seb Savory is a University Lecturer at Cambridge University. in Advanced Fibre Laser Technologies for Future Manufacturing in Having been sponsored by Nortel through his undergraduate the Optoelectronics Research Centre, University of Southampton. and postgraduate studies at Cambridge, he rejoined the Harlow His research activities include advanced optical fibre amplifier Laboratories in 2000. In 2005, he moved to UCL where he held configurations, high power fibre lasers, optical microresonators, a Leverhulme Trust Early Career Fellowship from 2005 to 2007, and non-linear fibre optics. He was a co-founder ofSouthampton before being appointed as a Lecturer (2007), Reader (2012) and Photonics Inc. a University of Southampton spin-off, now SPI Professor (2015). In January 2016 he returned to Cambridge as Lasers, manufacturing high power fibre lasers. He is a Fellow of the a University Lecturer and Fellow of Churchill College. Dr Savory Optical Society of America. is the Editor-in-Chief of IEEE Photonics Technology Letters and serves on the Steering Committee of the Optical Fiber Commu- nication conference having previously served as a General Chair (2015) and Program Chair (2013).
Tuesday, September 20, 2016, 09:00-10:00 Room 18+19 Wednesday, September 21, 2016, 09:00-10:00 Room 18+19 SC 2 - Waveguide and Optoelectronic Devices SC 4 - Subsystems for Optical Networking and for Datacoms
Tu.1.A.1 W.1.A.1 Application of photonic crystal and hetero- Advanced Silicon Photonics for geneous integration to ultra low energy Post-Moore Era lasers for optical interconnects and data- Koji Yamada (National Institute of Advanced center networks Industrial Science and Technology, Japan) Shinji Matsuo (Nippon Telegraph and Telephone Corporation, Japan)
Shinji Matsuo is a Senior Distinguished Researcher in NTT Device Koji Yamada received his B.E., M.E. and Ph.D. degrees in nuclear Technology Laboratories. He received a B.E. and M.E. in electri- engineering from Kyushu University, Japan, in 1986, 1988 and cal engineering from Hiroshima University in 1986 and 1988 and 2003, respectively. Currently, he is a group leader of Silicon Photo- a Ph.D. in electronics and applied physics from Tokyo Institute of nics Group in in National Institute of Advanced Industrial Science Technology in 2008. In 1988, he joined NTT, where he researched and Technology (AIST), Japan. From 1988 to 2015, in NTT labora- photonic functional devices using VCSELs. Since 2000, he has tories, he was engaged in studies on accelerator physics/enginee- been researching tunable lasers and low-operating energy directly ring for synchrotron light sources and studies on silicon photonic modulated lasers. He is a member of the JSAP, IEICE, and a Fellow platform. Since joining AIST in 2015, he continues studying silicon of IEEE. photonic platform.
20 Tutorials
Thursday, September 22, 2016, 09:00-10:00 Room 18+19 Wednesday, September 21, 2016, 11:00-12:00 Room 18+19 SC 5 - Point-to-Point Transmission Systems SC 7 - Access, Local Area and Home Networks
Th.1.A.1 W.2.A.1 Mitigation of Nonlinear Propagation Industrial Trends and Roadmap of Access Impairments by Digital Signal Processing Frank Effenberger (Huawei - Futurewei Techno- Takeshi Hoshida (Fujitsu Laboratories, Japan) logies, USA)
Takeshi Hoshida is a Project Director at Network Systems Labo- Frank Effenberger has worked in the optical access field at ratory in Fujitsu Laboratories Ltd., in Kawasaki, Japan. He received Bellcore, Quantum Bridge Communications (Motorola), and the B.E., M.E., and Ph.D. degrees in electronic engineering from Futurewei Technologies, where he is now the Vice President of the the University of Tokyo, Tokyo, Japan, in 1993, 1995, and 1998, fixed access network lab. His team works on forward-looking fiber, respectively. Since 1998, when he joined Fujitsu Laboratories Ltd., copper, and coax access technologies, with several “world’s first” Kawasaki, Japan, he has been engaged in the research and de- prototypes and trials. Frank is a Fellow of the OSA, the IEEE, and velopment of dense wavelength-division multiplexing optical trans- Huawei, and holds 77 US patents. mission systems. From 2000 to 2002, he was with Fujitsu Network Communications, Inc., Richardson, TX. Since 2007, he has also been with Fujitsu Limited, Kawasaki, Japan. He has authored or co-authored more than 150 conference and journal contributions, and has been serving as a member of techni- cal program committee in conferences such as OFC and OECC.
Wednesday, September 21, 2016, 14:00-15:00 Room 18+19 SC 6 - Core Metro and Data Center Networks
W.3.A.1 Roles and Benefits of Elastic Optical Networks in Beyond 100-Gb/s Era Masahiko Jinno (Kagawa University, Japan)
Masahiko Jinno is a Professor of Electronics and Information En- gineering at Kagawa University. Prior to joining Kagawa University in October 2012, he was a Senior Research Engineer, Supervisor at Network Innovation Laboratories, Nippon Telegraph and Tele- phone Corporation (NTT). Prof. Jinno is a Fellow of the Institute of Electronics, Information and Communication Engineers (IEICE) and a Senior Member of the Institute of Electrical and Electronics Engineers (IEEE).
21 Invited Talks
SC 1 - Fibres, Fibre Devices and Fibre Amplifiers SC 3 - Digital and Optical Signal Processing
Monday, September 19, 2016, 17:00 – 17:30 Room 18+19 Monday, September 19, 2016, 14:00 – 14:30 Room 17 Design and characterization of multicore Erbium-doped Adaptive Transceivers in Nonlinear Flexible Networks fibers David Ives (University of Cambridge, UK) Sophie Larochelle (Université Laval, Canada) Monday, September 19, 2016, 16:30 – 17:00 Room 17 Tuesday, September 20, 2016, 11:00 – 11:30 Room 112 Power Efficient Coherent Transceivers Optical Fibre Technologies for Future Communication Jonas Geyer (Acacia Communications, USA) Networks Perikles Petropoulous (University Southampton, USA) Tuesday, September 20, 2016, 10:00 – 10:30 Room 110 Joint Modulation and Coding Optimization for Long-Haul Wednesday, September 21, 2016, 09:30 – 10:00 Room 17 Nyquist-WDM Transmissions Multicore optical fiber grating arrays for sensing Rafael Rios-Muller (Bell Labs Nokia, France) applications Paul Westbrook (OFS Fitel, LLC, USA) Tuesday, September 20, 2016, 16:00 – 16:30 Room 17 Prospects for Real-Time Compensation of Fiber Non Wednesday, September 21, 2016, 11:30 – 12:00 Room 17 linearities Coupled Few-mode Multi-core Fibre for Ultra-high Spatial Michael Reimer (Ciena, USA) Density Space Division Multiplexing Taiji Sakamoto (Nippon Telegraph and Telephone Corporation, Wednesday, September 21, 2016, 09:00 – 09:30 Room 16 Japan) Probabilistically Shaped QAM for Independent Reach, Spectral Efficiency and Bit-rate Adaptation Wednesday, September 21, 2016, 14:00 – 14:30 Room 17 Fred Buchali (Nokia Bell Labs, Germany) Linear and Nonlinear Properties of OAM in Fibers Siddarth Ramachandran (University of Boston, USA) Wednesday, September 21, 2016, 11:30 – 12:00 Room 16 Scalable SD-FEC for Efficient Next-Generation Optical Networks Kenya Sugihara (Mitsubishi Electric Corporation, Japan)
SC 2 - Waveguide and Optoelectronic Devices SC 4 - Subsystems for Optical Networking and for Datacoms
Monday, September 19, 2016, 16:00 – 16:30 Room 110 Monday, September 19, 2016, 14:30 – 15:00 Room 16 High-Speed Directly Modulated Heterogeneously Injection-locked Homodyne Detection System for Integrated InP/Si DFB Laser Higher-order QAM Digital Coherent Transmission Geert Morthier (Ghent University, Belgium) Keisuke Kasai (Tohoku University, Japan)
Tuesday, September 20, 2016, 10:00 – 10:30 Room 18+19 Wednesday, September 21, 2016, 10:00 – 10:30 Room 18+19 Higher Speed VCSEL Links using Equalization High-Speed Photonics for Side-by-Side Integration with Daniel Kuchta (IBM - T. J. Watson Research Center, USA) Billion Transistor Circuits in Unmodified CMOS Processes Luca Alloatti (ETH, Switzerland) Tuesday, September 20, 2016, 16:30 – 17:00 Room 18+19 High Speed Silicon Organic Hybrid (SOH) Modulators Wednesday, September 21, 2016, 11:00 – 11:30 Room 112 Stefan Wolf (Karlsruhe Institute of Technology - KIT, Germany) High radix all-optical switches for software-defined data- centre networks Wednesday, September 21, 2016, 11:00 – 11:30 Room 110 Nick Parsons (Polatis, USA) Quantum-Dot Lasers Monolithically Grown on Silicon Substrates Wednesday, September 21, 2016, 12:00 – 12:30 Room 112 Huiyun Liu (University College London, UK) Coherent Optical Subcarrier Processing and Add/Drop Multiplexing Wednesday, September 21, 2016, 15:00 – 15:30 Room 112 Carsten Schmidt-Langhorst (Fraunhofer Heinrich Hertz Institute, Monolithic Electronic-Photonic Co-Integration in Photonic Germany) BiCMOS Lars Zimmermann (Leibniz-Institute - IHP, Germany) Thursday, September 22, 2016, 09:30 – 10:00 Room 16 High-Speed VCSELs for Datacom Thursday, September 22, 2016, 10:00 – 10:30 Room 17 Anders Larsson (Chalmers University of Technology, Sweden) Ultrafast laser inscription of 3D waveguides for SDM applications Robert Thomson (Heriot-Watt University, UK)
22 Invited Talks
SC 5 - Point-to-Point Transmission Systems SC 7 - Access, Local Area and Home Networks
Monday, September 19, 2016, 15:00 – 15:30 Room 15 Monday, September 19, 2016, 14:30 – 15:00 Room 110 Mutual information characterization of nonlinear fiber Protection Systems for optical access Networks channels Takashi Nishitani (Mitsubishi Electric Corporation, Japan) Tobias Eriksson (Chalmers University of Technology, Sweden) Tuesday, September 20, 2016, 09:15 – 09:45 Room 112 Tuesday, September 20, 2016, 09:00 – 09:30 Room 15 Optical Network Technologies for Wireless Communication Ultra-high capacity SDM/WDM transmission over multicore Network and multimode fibers Jun Terada (NTT Access Service Network System Laboratories, Takehiro Tsuritani (KDDI R&D Laboratories Inc., Japan) Japan)
Tuesday, September 20, 2016, 09:30 – 10:00 Room 15 Tuesday, September 20, 2016, 10:00 – 10:30 Room 112 Pb/s, Homogeneous, Single-mode Multi-Core Fiber Optics For 5G: How Can We Combine Low Cost With De- Systems manding Requirements? Ben J. Puttnam (NICT Photonic Network Laboratory, Japan) Antonio Tartaglia (BUCI DUIP PDU OM Systems & Technology Ericsson Telecomunicazioni S.p.A., Italy) Wednesday, September 21, 2016, 10:00 – 10:30 Room 15 Analytical and Semi-Analytical Models for Nonlinear Tuesday, September 20, 2016, 17:00 – 17:30 Room 18+19 Transmission Recent Progress on 25G EPON and beyond Ronen Dar (Nokia Bell Labs, USA) Vincent Houtsma (Bell Labs - Nokia, USA)
Wednesday, September 21, 2016, 15:00 – 15:30 Room 15 Wednesday, September 21, 2016, 12:00 – 12:30 Room 18+19 Solutions for 400Gbit/s Inter Data Center WDM Trans Cost effective 25 Gbps Optical Access Technology mission Dora van Veen (Nokia, USA) Annika Dochhan (ADVA Optical Networking, Germany) Wednesday, September 21, 2016, 14:30 – 15:00 Room 110 Burst-Mode Optical Amplifier Technologies for TWDM-PON Masamichi Fujiwara (NTT Access Service Network System Labo- ratories, Japan)
SC 6 - Core Metro and Data Center Networks
Monday, September 19, 2016, 15:00 – 15:30 Room 112 Building a Programmable Testbed Infrastructure in the UK to Support Network R&D David Salmon (JISC, UK)
Monday, September 19, 2016, 16:00 – 16:30 Room 112 A roadmap for evolving towards optical intra-data-center Networks Lars Ditmann (Danish Technical University, Denmark)
Tuesday, September 20, 2016, 09:00 – 09:30 Room 17 Operator use cases that benefit from multi-layer optimizati- on and application awareness Victor Lopez (Telefonica, Spain); Domenico Siracusa (CREATE- NET, Italy); Dimitrios Klonidis (AIT, Greece); Juan Pedro Fernández-Palacios (Telefónica I+D, Spain)
Tuesday, September 20, 2016, 12:00 – 12:30 Room 17 Elastic all-optical networks: a new paradigm enabled by the physical layer. How to optimize network Performances? Vittorio Curri (Politecnico di Torino, Italy)
Tuesday, September 20, 2016, 16:00 – 16:30 Room 15 Adaptive and Efficient Multilayer Elastic Optical Network Planning Takafumi Tanaka, (NTT, Japan)
Thursday, September 22, 2016, 09:00 – 09:30 Room 110 Can Metro Networks be the Next Playground for (true) Elastic Networks Patricia Layec (Nokia Bell Labs, France)
23 Optical Spectrum Analyzer
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160715_Telekom_Anzeige_1_1_GB.indd 7 06.09.16 10:42 CLEO Focus Meeting Tuesday, September 20, 2016 • 09:00 - 17:30
CLEO FOCUS MEETING FUNDAMENTAL PHOTONICS FOR FUTURE TELECOMMUNICATIONS
Following on from successful conferences held since 2006, the European Physical Society and CLEO Europe-EQEC in collaboration with the Chairs of ECOC 2016 are delighted to announce the organisation of a special CLEO Focus Meeting on Fundamental Photonics for Future Telecommunications, to be held as part of ECOC 2016. New developments and trends on emerging and highly forward-looking research in photonics will be at the heart of this special CLEO Focus Meeting, complementary to the regular ECOC sessions. The meeting will showcase state-of-the-art results which bridge the gap between basic science and applications. The scope includes, but is not limited to, digital and optical signal processing, nanophotonics, plasmonics, nonlinear optics, novel materials including metamaterials, novel devices, spatio-temporal complex nonlinear dynamics, optical angular momentum research, quantum optics, emerging ultrafast technologies, new concepts in optical generation including supercontinuum sources, optical rogue waves and frequency combs, multimode systems, beam manipulation and wave-guiding, and other optical communication and processing related topics.
■ Tuesday, September 20, 2016 10:00 Ultra-Stable Optical Frequency and Accurate Timing Signal Dissemination Using Telecommunication Net- CLEO 1: Spatiotemporal Control • Room 14 work (Invited) Olivier Lopez (LPL - CNRS - Paris 13 University, FR); Chair: Sergei K. Turitsyn (Aston University & Photonics Research Nicolas Quintin (LPL - Paris 13 University - CNRS, FR); Group, UK) Fabio Stefani (SYRTE - PARIS Observatory - CNRS - UPMC, FR); Anthony Bercy (LPL - CNRS - Paris 13 09:00 Frequency Stability in Optical Networks: Challenges, University, FR); Nicolas Chiodo (LPL - Paris 13 Universi- Implementation and Implications (invited) ty - CNRS, FR); Fabrice Wiotte (LPL - CNRS - Paris 13 Stojan Radic (University of California, San Diego, USA) University, FR); Emilie Camisard (RENATER, FR); Chriistian The role of frequency carrier stability in optical networks Chardonnet (LPL - CNRS - Paris 13 University, FR); Gior- is discussed. We show that so-called nonlinear capacity gio Santarelli (LP2N - CNRS - Bordeaux University, FR); limit for fiber transmission was established erroneously and Paul-Eric Pottie (SYRTE - CNRS - Observatoire de Paris has no physical basis in any optical network of practical - UPMC, FR); Anne Amy-Klein (LPL - Paris 13 University - interest. CNRS, FR) Optical fibre links have been developed to transfer an 09:30 Pulse Combining and Compression in Multi-core ultrastable optical frequency between distant laboratories Fibers for time and frequency metrology and high-precision mea- Igor Chekhovskoy (Novosibirsk State University & Institute surements. We will review the specificity of this technique, of Computational Technologies, RU); Alexander Rubenchik its performance and a few applications. (Lawrence Livermore National Laboratory, USA); Olga Shtyrina (Novosibirsk State University & Institute of Com- 10:30 - 11:00 Coffee Break putational Technologies, RU); Sergei K. Turitsyn (Aston University & Photonics Research Group, UK); Mikhail Fedoruk (Novosibirsk State University & Institute of Com- CLEO 2: Optical Information Processing • Room 14 putational Technologies, RU) We investigate pulse compression and combining effi- Chair: Stefan Wabnitz (University of Brescia, Italy) ciency for multi-core fibers of different structures. Coherent combining in one core with efficiency over 80% and pulse 11:00 Photonic Reservoir Computing for Ultra-Fast Infor- compression few hundreds times are demonstrated. We mation Processing Using Semiconductor Lasers analyse the influence of perturbations of input pulses. (Invited) Ingo Fischer, Julian Bueno, Daniel Brunner, Miguel Soriano 09:45 Spatiotemporal Nonlinear Interactions in Multimode and Claudio Mirasso (IFISC (UIB-CSIC), ES) Fibers Neuro-inspired computational concepts like reservoir Katarzyna Krupa (ICB UMR CNRS 6303 Université de computing can now be implemented in telecommunica- Bourgogne Franche-Comté & XLIM UMR CNRS 7252 tion-compatible hardware, with high hardware and energy Université de Limoges, FR); Alessandro Tonello (XLIM efficiency and exhibiting excellent computing performance. UMR CNRS 7252 Université de Limoges, FR); Abdelkrim This provides interesting perspectives for applications in Bendahmane (Université de Bourgogne, FR); Richard telecommunication. Dupiol (ICB UMR CNRS 6303 Université de Bourgogne Franche-Comté, FR); Badr Shalaby, Marc Fabert (XLIM 11:30 Enhanced nonlinear spectral compression in fibre by UMR CNRS 7252 Université de Limoges, FR); Alain sinusoidal phase modulation Barthelemy (XLIM Institut de Recherche, FR); Guy Millot Christophe Finot (University of Burgundy, FR); (CNRS/Université de Bourgogne, FR); Stefan Wabnitz Sonia Boscolo (Aston University, UK) (University of Brescia, IT); Vincent Couderc (Université de We propose a simple approach to enhance the spectral Limoges, FR) compression arising from nonlinear pulse propagation in We observe experimentally a novel spatiotemporal a Kerr medium. We numerically show that an additional dynamics of multimode fibers allowing for a new type of sinusoidal temporal phase modulation enables efficient parametric instability and an original phenomenon of light reduction of the intensity level of spectral side lobes. self-organisation. Our experiments agree well with theo- retical predictions and numerical simulations based on the Gross-Pitaevskii equation.
26 CLEO Focus Meeting Tuesday, September 20, 2016 • 09:00 - 17:30
11:45 Linear and Nonlinear Frequency-Division CLEO 3: Optoelectronics • Room 14 Multiplexing Mansoor Isvand Yousefi (Telecom ParisTech, FR); Xianhe Chair: Stojan Radic (University of California, San Diego, USA) Yangzhang (Technical University of Munich, DE) Achievable rates of WDM and nonlinear frequency- 16:00 Subwavelength Index Engineered Structures: division multiplexing (NFDM) are computed as a function Fundamental Building Blocks for the Next of transmit power. The NFDM rate increases monotonically Generation Photonic Integrated Circuits (Invited) with power, in contrast to the WDM rate which character- Pavel Cheben (NRC Institute for Microstructural Sciences, istically vanishes at high powers. The improvement results CA); Danxia Xu (NRC Institute for Microstructural Scienc- from nonlinear signal multiplexing. es, DE) Subwavelength engineered all-dielectric metamaterial 12:00 Periodic Nonlinear Fourier Transform Based Trans- structures are likely to become key building blocks for the missions with High Order QAM Formats next generation of integrated photonic circuits. This unique Morteza Kamalian, Kopae (Aston University & Aston technology allows synthesis of an effective photonic medi- Institute of Photonic Technologies, UK); Jaroslaw Prilepsky um with an unprecedented control of material properties. (Aston University & Aston Institute of Photonic Technolo- We present an overview of emerging implementations, gies, UK); Son Le (Aston University, UK); Sergei K. Turitsyn including high-efficiency broadband fibre-chip surface (Aston University & Photonics Research Group, UK) grating couplers and edge couplers, ultra-broadband split- We propose, for the first time, a technique of construct- ters, sensors and mid-infrared waveguide components, to ing signals with high order QAM formats (128--512 QAM) name a few. for periodic nonlinear Fourier transform based systems. The proposed method effectively eliminates the inverse 16:30 New Ultrafast Laser Sources and Nonlinear Devices transformation stage reducing significantly the system‘s Based on TM:II-VI Semiconductors complexity. Sergey Vasilyev, Igor Moskalev, Mike Mirov, Viktor Smolski and Sergey Mirov (IPG Photonics Mid-IR Lasers, USA); 12:15 Programmable single-photon to single-atom Valentin Gapontsev (IPG Photonics Corporation, USA) quantum interface Transition-metal-doped II-VI semiconductors possess a Juergen Eschner, Christoph Kurz, Pascal Eich, Michael unique blend of physical, spectroscopic, optical, and tech- Schug and Philipp Müller (Saarland University, DE) nological parameters. These materials enable high power Integration of quantum photonic systems into future lasers in important middle-infrared range; they are also telecommunication technologies, for example for quantum well suited for generation and efficient nonlinear frequency cryptography, requires interfacing single photons as quan- conversion of ultra-short optical pulses. tum information carriers with single atoms as quantum memories. We demonstrate a programmable interface for 16:45 Fundamental and Applied Aspects of Submonolayer bi-directional quantum state conversion between single Quantum Dots as Active Medium in Opto-electronics photons and single trapped atomic ions. Bastian Herzog, Mirco Kolarczik, Yücel Kaptan, Benjamin Lingnau, Kathy Lüdge, Jan-Hindrik Schulze and Ricardo 12:30 Sources for Integrated Quantum Information Pro- Rosales (Technische Universität Berlin, DE); Dieter Bim- cessing (Invited) berg (Technical University of Berlin, DE); Andre Strittmatter Christine Silberhorn, Benjamin Brecht, Christof Eigner, (Technische Universität Berlin, DE); Udo Pohl, Ulrike Wog- Harald Hermann, Stephan Krapick, Kai-Hong Luo, Regina gon and Nina Owschimikow (Technische Universität Berlin, Kruse, Raimund Ricken and Linda Sansoni (University DE) of Paderborn & Faculty of Sciences, DE); Viktor Quiring Submonolayers promise to combine the high gain of (Universitaet Paderborn, DE) quantum wells with the stability of quantum dots. We Integrated optics provides a promising platform for the investigate the carrier dynamics by phase sensitive het- implementation of highly complex and compact circuits for erodyne pump-probe experiments and find a fast <2ps quantum information applications. Integrated waveguide relaxation and high gain, accompanied by large nonlineari- sources feature high brightness and interferometric stabil- ties. ity. Here we present our work on advanced multi-channel devices. 17:00 Realization of Arbitrary Complex Apodization Pro- files in Integrated Waveguide Bragg Gratings on SOI 13:00 - 14:00 Lunch Break Hamed Pishvaibazargani (Institut National de la Recherche Scientifique (INRS), CA); Jose Azana (INRS, CA) 14:00 - 16:00 Exhibition Only We implement waveguide Bragg gratings (BGs) with misaligned sidewall corrugations in order to realize profiles. In particular a very challenging grating design, namely photonic Hilbert transformer, has user-defined complex apodization been successfully demonstrated on SOI.
17:15 Nonlinear Integrated Photonics in Lithium Niobate by Direct Femtosecond Laser Writing Sebastian Kroesen, Lukas Wesemann, Kemal Tekce and Jörg Imbrock (Institute of Applied Physics, University of Münster, DE); Cornelia Denz (Institute of Applied Physics, University of Münster, DE) We report on the monolithic fabrication of integrated optical elements in lithium niobate by direct femtosecond laser writing. Advanced designs and processing schemes enable a novel synthesis of complex refractive index struc- tures and tailored nonlinearity. 27 CLEO Focus Meeting Wednesday, September 21, 2016 • 09:00 - 12:30
■ Wednesday, September 21, 2016 We experimentally and numerically investigate the impact of coherent and incoherent seeding of the modu- lation instability process in a nonlinear fiber ring cavity. Our CLEO 4: Nonlinear Cavities • Room 14 results highlight the sensitivity of the nonlinear dynamics in term of sideband bandwidth and temporal coherence. Chair: Bertrand Kibler (C NRS / Université Bourgogne Franche- Comté, FR) 10:00 Comb Peculiarities of the Dispersion-managed Soliton in the Hybrid Mode-locked Erbium-doped 09:00 Using Kerr combs for coherent optical communi All-fiber Ring Laser cations (Invited) Dmitriy Dvoretskiy, Stanislav Sazonkin, Maxim Negin, Yanne Chembo (FEMTO-ST Institute, FR) Dmitry Shelestov, Alexey Pniov and Valery Karasik (Bau- Kerr optical frequency combs can be used as man Moscow State Technical University, RU); Alexander multi-wavelength sources for coherent optical fiber tele- Krylov (Fiber Optics Research Center of the RAS, RU); communication networks. We here discuss some results Elena Obraztsova (A M Prokhorov General Physics Insti- perspectives and challenges in this emerging field. tute of the RAS, RU) We studied optical comb peculiarities of the ultra-short 09:30 Chipscale Frequency combs: From soliton physics to dispersion-managed soliton generation in the erbium- coherent telecommunication doped all-fiber ring laser hybrid mode-locked with Carbon: Michael Geiselmann, Victor Brasch, Martin Pfeiffer and Boron Nitride Single-Walled Nanotubes in the co-action Karpov Maxim (Ecole Polytechnique Federale de Laus- with a nonlinear polarization evolution. anne, CH); Junqiu Liu and Hairun Guo (EPFL, CH); Grig- oriy Lihachev (Lomonosov Moscow State University, RU); 10:15 Kerr Frequency Combs in a Bichromatically Pumped Michael Gorodetsky (M. V. Lomonosov Moscow State Nonlinear Fiber Ring Cavity University, RU); Tobias Kippenberg (Ecole Polytechnique Abdelkrim Bendahmane (Université de Bourgogne, FR); Federale de Lausanne, CH) Davide Ceoldo (Università di Brescia, Brescia, IT); Julien We generate soliton Kerr frequency combs in a silicon Fatome and Guy Millot (CNRS/Université de Bourgogne, nitride microresonator. These combs are fully coherent FR); Tobias Hansson and Daniele Modotto (Università di and are used as channel generator for coherent telecom- Brescia, Brescia, IT); Stefan Wabnitz (University of Brescia, munication. With the right dispersion engineering we can Italy); Bertrand Kibler (CNRS / Université Bourgogne broaden the spectrum to 75THz span around 1550nm. Franche-Comté, FR) We report numerical and experimental studies of four- 09:45 Seeding of Modulation Instability in a Nonlinear Fiber wave mixing processes emerging from dual-frequency Ring Cavity pumping of a passive fibre ring cavity. We observe the Abdelkrim Bendahmane (Université de Bourgogne, FR); emission of a periodic train of nearly-background-free Julien Fatome (CNRS/Université de Bourgogne, FR); soliton pulses associated with Kerr frequency combs. Christophe Finot (University of Burgundy, FR); Guy Millot (CNRS/Université de Bourgogne, FR); Bertrand Kibler 10:30 - 11:00 Coffee Break (CNRS / Université Bourgogne Franche-Comté, FR)
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CLEO 5: Lasers and instabilities • Room 14 12:00 Extremely Pulsating Solitons in a Mode-locked Fiber Laser Chair: Yanne Chembo (FEMTO-ST Institute, FR) Junsong Peng (AstonUniversity, UK); Nikita Tarasov, Srikanth Sugavanam and Dmitry Churkin (Aston University, 11:00 Real-Time Single-Shot Diagnostics of Mode-Locked UK) Lasers (invited) Extremely pulsating solitons were observed experimen- Georg Herink (University of Goettingen & UCLA, DE); tally in a mode-locked fiber laser. The solitons changed Felix Kurtz (University of Goettingen, DE); Bahram Jalali their intensity by an order of magnitude and exhibited time (University of California, Los Angeles, USA); Claus Ropers shift with a period of 1100 cavity roundtrips; meanwhile (University of Goettingen, DE); Daniel Solli (UCLA, USA) their optical spectrum breathed and compressed periodi- The combination of photonic time-stretch techniques cally. and real-time electronics enables rapid single-shot spec- tral acquisition over millions of consecutive laser pulses. 12:15 High-order linearly-polarized random Raman fiber We present the first real-time spectral view onto the evo- laser for telecom applications lution of femtosecond-pulses from noise, onto stable and Ekaterina Zlobina and Sergey Kablukov (Institute for meta-stable multi-pulse operation. Automation and Electrometry SB RAS, RU); Sergey Babin (Institute for Automation and Electrometry SB RAS & No- 11:30 Real Time Measurements of Noise-induced Rogue vosibirsk State University, RU) Waves Generated by Modulation Instability in Optical We demonstrate an efficient linearly polarized random Fibre lasing in a 1.8-km PM fiber up to the 5th order Stokes Mikko Närhi (Tampere University of Technology, FI); Ben- component at ~1360 nm. Potential applications and jamin Wetzel (INRS-EMT, CA); Cyril Billet (Université de problems of further expansion to longer wavelengths are Franche-Comté, FR); Thibaut Sylvestre (Femto-ST Institute discussed. & CNRS, FR); Shanti Toenger and Jean-Marc Merolla (FEMTO-ST Institute, FR); Roberto Morandotti (INRS-EMT, CA); Frederic Dias (University College Dublin, IR); Goëry Genty (Tampere University of Technology, FI); John Dudley (Université de Franche-Comté, FR) Using a parametric temporal magnifier system, we re- port for the first time on the direct temporal measurement of rogue waves and breather-like structures arising from spontaneous modulation instability.
11:45 FBG Reflectivity Impact on RIN in Ultralong Laser Amplifiers Giuseppe Rizzelli Martella (CSIC - Instituto de Optica, ES); Md Asif Iqbal (Aston University, UK); FRsca Gallazzi and Paweł Rosa (CSIC - Instituto de Optica, ES); Ming- ming Tan (Aston University & AIPT, UK); Pedro Corredera (CSIC - Instituto de Optica, ES); Juan Diego Ania-Casta- non (CSIC - Instituto de Optica, ES); Paul Harper (Aston University, UK) We analyse, both numerically and experimentally, the Relative Intensity Noise transfer in ultra-long Raman laser amplifiers isolating the combined effect of front-FBG reflectivity and pump power split and quantitatively show- ing their impact on a 100 km, 2nd-order, bidirectionally pumped configuration.
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Visit us at Booth 29 350! www.VPIphotonics.com | [email protected] Technical Programme Monday, September 19, 2016 • 14:00 - 15:30
M.1.A: Room 18+19 M.1.B: Room 17 M.1.C: Room 16 High Power FiberSC1 Lasers DSP for ReceiverSC3 Subsystems High Speed SubsystemsSC4 Chair: Hans G. Limberger (EPFL & Gr-Sci-HL, CH) Chair: Naoya Wada (NICT, JP) Chair: Laurent Bramerie (Foton CNRS UMR & ENSSAT / Université de Rennes 1, FR)
M.1.A.1 • 14:00 Tutorial M.1.B.1 • 14:00 Invited M.1.C.1 • 14:00 High Power Fibre Lasers: Fundamentals, Recent Progress Adaptive Transceivers in Nonlinear Flexible Networks On Single-Carrier 400G Line Side Optics Using PM-256QAM and Challenges David Ives (University of Cambridge, UK); Alex Alvarado (Universi- Hung-Chang Chien, Jianjun Yu (ZTE (TX) Inc., USA) Michael Zervas (University of Southampton & SPI Lasers, UK); ty College London, UK); Seb J Savory (University of Cambridge, For the first time, 400G line side interface based on single-car- Christophe Codemard (SPI Lasers, UK) UK) rier PM-256QAM is proposed and experimentally demonstrated, We review the fundamental properties and latest power scaling Transceiver adaptation is essential within an optical network to reaching 1.04-dBQ BTB system margin to the SD pre-FEC limit in fibre lasers, including limitations imposed by fibre nonlinearities, make effective use of the physical layer resources. We investigate through fast-converging polarization-tracking blind equalization transverse modal instabilities and other parasitic effects. Their the types of a daptation, the granularity of control and its effect on and LUT nonlinearity compensation. impact on the industrial applications space is also considered. network data throughput.
M.1.C.2 • 14:15 180-Gb/s (90-GBd QPSK) Single Carrier Transmitter Using a Thin Film Polymer on Silicon I/Q Modulator Gregory Raybon, Junho Cho,and Andrew Adamiecki (Nokia Bell Labs, USA); Peter Winzer (Bell Labs, USA); Luis Carvalho, Julio Cesar Oliveira (BrPhotonics, BR); Agnieszka Konczykowska and Jean-Yves Dupuy (III-V Lab, FR); Filipe Jorge (Nokia Thales III-V Lab, joint la: Bell Labs and Thales Research and Technology, FR) We demonstrate high-speed (90-GBd) modulation of a thin film polymer on Silicon (TFPS) I/Q modulator achieving single-polariza- tion quadrature phase shift keyed (QPSK) data rates of 180 Gb/s.
M.1.B.2 • 14:30 M.1.C.3 • 14:30 Invited Accurate and Robust Channel Spacing Estimation Based Injection-locked Homodyne Detection System for Higher- on Periodic Training Sequence in Denser Nyquist-WDM order QAM Digital Coherent Transmission System Keisuke Kasai, Masato Yoshida, Toshihiko Hirooka, Masataka Ying Zhao, Huihui Li, Xiaofei Su, Liang Dou and Zhenning Tao Nakazawa (Tohoku University, JP) (Fujitsu R&D Center Ltd., PRC); Shoichiro Oda (Fujitsu Laborato- We describe recent advances in a homodyne-detection system ries Ltd., JP); Yasuhiko Aoki (Fujitsu Limited, JP); Takeshi Hoshida with injection locking and its application for higher-order QAM and Jens C. Rasmussen (Fujitsu Laboratories Limited, JP) coherent transmission. Injection locking enables precise optical We propose an accurate and robust channel spacing estima- carrier-phase synchronisation with a simple receiver configuration. tion method based on a designed periodic training sequence. We demonstrate a 320 Gbit/s, 256QAM-160 km transmission. Experiment results show that estimation error is less than 50MHz and the method is immune to chromatic dispersion, polarization effects and fiber nonlinearity.
M.1.B.3 • 14:45 Linewidth-Tolerant Carrier Phase Estimation for N-PSK Based on Pilot-Assisted N/2th-power Method Tomofumi Oyama (Fujitsu Laboratories Ltd, JP); Takeshi Hoshida, Hisao Nakashima (Fujitsu Limited, JP); Takahito Tanimura (Fujitsu Laboratories Ltd., JP); Yuichi Akiyama (Fujitsu Limited, JP); Jens C. Rasmussen (Fujitsu Laboratories Ltd., JP) We propose a novel pilot-assisted carrier phase estimation method to reduce cycle slips. We numerically confirm that carrier phase recovery based on proposed method outperforms conventional V&V method in BER performance in large linewidth condition without causing any cycle slips.
M.1.B.4 • 15:00 M.1.C.4 • 15:00 Time Recovery for Spectrally-Sliced Optical Receivers 100 GSa/s BiCMOS DAC Supporting 400 Gb/s Dual Channel Valery Nobl Rozental, André Souza, Sandro M. Rossi, Andrea Transmission Chiuchiarelli, Juliano Rodrigues Fernandes de Oliveira and Jacklyn Karsten Schuh, Fred Buchali, Wilfried Idler, Qian Hu, Wolfgang D. Reis (CPqD, Division of Optical Technologies, BR) Templ (Nokia, Bell Labs, DE); Anna Bielik, Lars Altenhain, Henning We propose and experimentally demonstrate a symbol Langenhagen, Jörg Rupeter, Ulrich Dümler, Tobias Ellermeyer, Rolf synchronization method for spectrally-sliced optical receivers with Schmid and Michael Möller (MICRAM Microelectronic GmbH, DE) MIMO equalizer signal reconstruction in a PM-16QAM 56-GBd We demonstrate generation of a 32Gbaud 16QAM dual polar- 20x400G testbed. A novel timing error detector extracts sampling ization dual channel signal from one laser utilizing novel 100GSa/s phase information from equalizer coefficients. BiCMOS digital-to-analog converters. Fiber transmission over 2200 km of SSMF is also demonstrated outperforming a 64 GBaud system by 25% in reach.
M.1.B.5 • 15:15 M.1.C.5 • 15:15 Widely Linear Blind Adaptive Equalization for Transmitter Single-Detector, Single-ADC, Switched Coherent Optical IQ-Imbalance/Skew Compensation in Multicarrier Systems Receiver for High Symbol Rate Systems Experiments Edson Porto da Silva (Technical University of Denmark, DK); Gregory Raybon, Junho Cho and Andrew Adamiecki (Nokia Bell Darko Zibar (DTU Fotonik, department of Photonic Engineering, Labs, USA); Peter Winzer (Lucent Technologies, USA); Nicolas K Technical University of Denmark, DK) Fontaine (Bell Labs/Nokia, USA); Jean-Yves Dupuy and Agnieszka Simple analytical widely linear complex-valued models for Konczykowska (III-V Lab, FR); Filipe Jorge (Nokia Thales III-V Lab, IQ-imbalance and IQ-skew effects in multicarrier transmitters are joint la: Bell Labs and Thales Research and Technology, FR); Peter presented. To compensate for such effects, a 4$\times$4 MIMO Pupalaikis (LeCroy Corporation, USA); Roger Delbue, B Bhat and widely linear adaptive equalizer is proposed and experimentally Patrick Connally (Teledyne Lecroy, USA); Roland Ryf (Bell Labs, validated. Nokia, USA); Ellsworth C. Burrows (Bell Labs, Nokia, USA) We demonstrate a polarization-diversity coherent receiver with 100-GHz electrical bandwidth using only a single photodetector and a single high-speed analog-to-digital converter (ADC). We verify receiver performance using 90-GBd polarization-multiplexed QPSK test signals.
15:30 - 16:00 Coffee Break | Exhibition Hall | 30 Technical Programme Monday, September 19, 2016 • 14:00 - 15:30
M.1.D: Room 15 M.1.E: Room 110 M.1.F: Room 112 Probabilistic ShapingSC5 Coherent PON SC7 Advanced OpticalSC6 Networking Chair: Gabriel Charlet (Nokia Bell Labs, FR) Chair: Roberto Gaudino (Politecnico di Torino, IT) Chair: Lena Wosinska (KTH Royal Institute of Technology, SE)
M.1.D.1 • 14:00 M.1.E.1 • 14:00 M.1.F.1 • 14:00 Experimental Comparison of Gains in Achievable Informa- Demonstration of 100 Gb/s/λ-based Coherent PON System Impact of Traffic Profile on the Performance of Spatial tion Rates from Probabilistic Shaping and Digital Back- Using New Automatic Gain Controlled EDFA with ASE Superchannel Switching in SDM Networks propagation for DP-256QAM/1024QAM WDM Systems Compensation Function for Upstream Pre-Amplification Behnam Shariati and Dimitrios Klonidis (Athens Information Edson Porto da Silva, Metodi Yankov, Francesco Da Ros, Soren Naoki Suzuki, Hiroshi Miura, Kenichi Uto (Mitsubishi Electric Technology, GR); Domenico Siracusa and Federico Pederzolli Forchhammer, Michael Galili, Leif Oxenløwe (Technical University Corporation, JP) (CREATE-NET, IT); Jose Manuel Rivas (Athens Information Tech- of Denmark, DK); Darko Zibar (DTU Fotonik, depertment of Pho- We demonstrate the first prototype real-time 100 Gb/s/λ-based nology, GR); Luis Velasco (Universitat Politècnica de Catalunya tonic Engineering, Technical University of Denmark, DK) Coherent-PON. With an improved upstream received sensitivity (UPC), ES); I Tomkos (AIT Greece, GR) Gains in achievable information rates from probabilistic shaping of -38.1 dBm, a large loss budget of 39.1 dB over 80 km was We compare the performance of three SDM switching and digital backpropagation are compared for WDM transmission achieved by a new AGC-EDFA with ACF and a simplified DSP. paradigms under different traffic profiles. We show that their of 5x10-GBd DP-256QAM/1024QAM up to 1700 km reach. The performance is highly traffic dependent. We also show that combination of both techniques its shown to provide gains of up increasing the spectral switching granularity, significantly improves to 0.5 bits/QAM symbol. the performance of spatial group switching.
M.1.D.2 • 14:15 M.1.E.2 • 14:15 M.1.F.2 • 14:15 Field Demonstration of 1 Tbit/s Super-Channel Network Bidirectional symmetric 8 x 10.7 Gb/s WDM-PON over 108 Comparison of SDM and WDM on Direct and Indirect Opti- Using Probabilistically Shaped Constellations km installed fiber using low complexity polarization-insen- cal Data Center Networks Wilfried Idler, Fred Buchali, Laurent Schmalen and Eugen Lach sitive coherent ONUs Yifan Liu, Hui Yuan, Adaranijo Peters and Georgios Zervas (Uni- (Nokia Bell Labs, DE); Ralf-Peter Braun (Deutsche Telekom M. Sezer Erkilinc, Domanic Lavery, Kai Shi, Benn C Thomsen, versity of Bristol, UK) T-Labs, DE); Georg Böcherer, Patrick Schulte and Fabian Steiner Polina Bayvel, Robert I Killey (University College London, UK); Seb We benchmark Data Centre topologies under SDM and WDM (Technische Universität München, DE) J Savory (University of Cambridge, UK) transport in terms of network capacity, utilization, blocking prob- We successfully tested the suitability of probabilistically shaped Polarization-time block-coded OFDM-QPSK downstream ability, cost and power consumption. SDM offers cost and power constellations in field environment. We performed 1 Tbit/s channels are robustly detected using a polarization-insensitive benefits than WDM while Spine-Leaf demonstrates all-round best 4-carriers super-channel transmission in the German nationwide coherent receiver, consisting of only a 3-dB coupler and single performance among all topologies. backbone network with an extended family of probabilistically balanced PD. 8x10.7 Gb/s channels are bidirectionally transmit- shaped constellations using 16QAM, 36QAM and 64QAM. ted over 108km installed fiber achieving a 1:16-way passive split.
M.1.D.3 • 14:30 M.1.E.3 • 14:30 Invited M.1.F.3 • 14:30 Study of electrical subband multiplexing at 54 GHz modu- Protection Systems for optical access networks Experimental Demonstration of a Flexible Filterless and lation bandwidth for 16QAM and probabilistically shaped Takashi Nishitani (Mitsubishi Electric Corporation, JP) Bidirectional SDM Optical Metro/Inter-DC Network 64QAM A PON needs a protection scheme to ensure the system’s George M. Saridis (University of Bristol, UK); Benjamin J Fred Buchali, Wilfried Idler, Karsten Schuh and Laurent Schmalen reliability. Fast protection switching is important for outage-free Puttnam (National Institute of Information and Communications (Nokia Bell Labs, DE); Georg Böcherer, Fabian Steiner and Patrick maintenance and rapid recovery from failure. This paper introduc- Technology, JP); Ruben S Luís (NICT, USA); Werner Klaus, Takaya Schulte (Technische Universität München, DE); Tobias A. Eriksson es two PON protection systems for fast protection switching in Miyazawa and Yoshinari Awaji (National Institute of Information (Nokia Bell Labs, DE) under 50ms. and Communications Technology (NICT), JP); Georgios Zervas We showed 14% and 9% reach gain for electrical subband and Dimitra Simeonidou (University of Bristol, UK); Naoya Wada multiplexed 16QAM and PS-64QAM signals at 54GHz modulation (NICT, JP) bandwidth. A detailed analysis exhibits up to 40% gain for best We experimentally evaluate a filterless, all-optical network subbands. using architecture-on-demand nodes and MCF-based links for metro and inter-data centre communication. We demonstrate that bidirectional SDM networking with elastic super-channels can eliminate drop-and-waste while supporting hitless dynamic bandwidth allocation.
M.1.D.4 • 14:45 M.1.F.4 • 14:45 Capacity Approaching Transmission using Probabilistic Cost Benefit Quantification of SDM Network Implementa- Shaping and DBP for PFE Constrained Submarine Optical tions based on Spatially Integrated Network Elements Links Jose Manuel Rivas and Behnam Shariati (Athens Information Robert Maher, Domanic Lavery, Gabriele Liga, Milen Paskov Technology, GR); Antonia Mastropaolo (Scuola Superiore and Alex Alvarado (University College London, UK); Tobias Sant’Anna, IT); Dimitrios Klonidis, I Tomkos (AIT Greece, GR) Fehenberger (Technical University of Munich (TUM), DE); Polina We perform a techno-economic analysis of different SDM Bayvel (UCL, UK) network implementations considering spatially-integrated trans- Probabilistic constellation shaping and DBP enables the re- ceivers, amplifiers and switches. We quantify the cost reduction of duction in per-channel launch power by 2.2 dB, in a 150 channel the SDM schemes compared to conventional approaches based 11000 km submarine link. For a fixed PFE voltage of 12 kV, the on parallel-fiber systems. total system throughput is increased by 64%.
M.1.D.5 • 15:00 Invited M.1.E.4 • 15:00 M.1.F.5 • 15:00 Invited Mutual information characterization of nonlinear fiber 22-dB Dynamic Range, Real-Time Burst-Mode Reception Building a Programmable Testbed Infrastructure in the UK channels of Digital Coherent 20-Gb/s QPSK PON Upstream Signals to Support Network R&D Tobias A. Eriksson (Nokia Bell Labs, DE); Tobias Fehenberger Ryo Koma (NTT Access Network Service Systems Laborato- David Salmon (Jisc, UK) (Technical University of Munich (TUM), DE) ries, NTT Corporation, JP); Masamichi Fujiwara (NTT Access Availability of network testbed infrastructures for the UK Achievable information rates are investigated for different coher- Network Service Systems Laboratories, JP); Jun-ichi Kani (NTT, academic network research communities is currently at a scale ent transmission scenarios. By using four-dimensional channel JP); Sang-Yuep Kim (NTT Access Network Service Systems never previously realised. These infrastructures will be described, statistics, taken over two polarizations or two consecutive Laboratories, JP); Takahiro Suzuki (NTT & NTT Access Network together with some of the project work being undertaken and the time slots, gains compared to conventional two-dimensional Service Systems Laboratory, JP); Hideki Mori and Tomoyuki Wada prospects for future developments. demappers are found, even for links without inline dispersion (NTT Advanced Technology Corp., JP); Ken-Ichi Suzuki (NTT, JP); compensation. Akihiro Otaka (NTT Corporation, JP) We report, for the first time, real-time burst-mode digital coher- ent reception wherein frame power differences are considered. 20-Gb/s QPSK burst signals with 22-dB dynamic range are successfully received by SOA-based optical power equalizer and burst-mode DSP.
M.1.E.5 • 15:15 Field-Trial of Low-Cost Coherent UDWDM-PON with Real- Time Processing, λ-Monitoring and EPON Coexistence Ivan Cano, Josep Prat, Jeison Tabares, Juan Camilo Velásquez Micolta, Saeed Ghasemi, Victor Polo and Guang Yong Chu (Universitat Politècnica de Catalunya, ES); Marco Presi, Ernesto Ciaramella, Mario Rannello, Fabio Bottoni, Massimo Artiglia and Giulio Cossu (Scuola Superiore Sant’Anna University, IT); Robert Pous, Gregorio Azcárate and Chantal Vila (Promax, ES); Helen Debregeas-Sillard (III-V Lab, FR); Gemma Vall-llosera (Ericsson Research, SE); Albert Rafel (BT, UK) An UDWDM-PON with simple real-time ASK and DPSK trans- ceivers is validated in a field-trial with deployed fibre achieving -47 dBm sensitivity at BER=2e-3 with 1.25 Gbit/s effective user bitrate. Real data traffic transmission and EPON coexistence are also demonstrated.
15:30 - 16:00 Coffee Break | Exhibition Hall | 31 Technical Programme Monday, September 19, 2016 • 16:00 - 17:30
M.2.A: Room 18+19 M.2.B: Room 17 M.2.C: Room 16 Fiber AmplifiersSC1 for SDM DSP for Short ReachSC3 Pulse AmplitudeSC4 Modalation I Chair: Pierre Sillard (Prysmian, FR) Chair: Dimitrios Apostolopoulos (National Techni- Chair: Michael Galili (Technical University of cal University of Athens & Institute of Communi- Denmark, DK) cation and Computer Systems, GR)
M.2.A.1 • 16:00 M.2.B.1 • 16:00 M.2.C.1 • 16:00 Upgraded Efficient pumping scheme for amplifier arrays with shared Reach Enhancement for WDM Direct-Detection Subcarrier 100-Gbaud PAM-4 intensity-modulation direct-detection pump laser Modulation using Low-Complexity Two-Stage Signal-Signal transceiver for datacenter interconnect Alan Gnauck (Nokia Bell Labs, USA); Peter Winzer (Bell Labs, Beat Interference Cancellation Miquel A. Mestre (Nokia Bell Labs, FR); Filipe Jorge (Alcatel Thales USA); Robert Jopson, Ellsworth Burrows (Nokia Bell Labs, USA) Zhe Li, M. Sezer Erkilinc and Robert Maher (University College III-V Lab, joint la: Bell Labs and Thales Research and Technology, tbd London, UK); Lidia Galdino (Optical Networks Group, University FR); Haik Mardoyan and Jose Manuel Estaran (Nokia Bell Labs, College London, UK); Kai Shi, Benn C Thomsen, Polina Bayvel FR); Fabrice Blache (Alcatel-Thales III-V Lab, FR); Philippe Angelini and Robert I Killey (University College London, UK) and Agnieszka Konczykowska (III-V Lab, FR); Muriel Riet (Alcatel We describe a novel low-complexity SSBI cancellation scheme, Thales III-V Lab, joint la: Bell Labs and Thales Research and Tech- and experimentally investigate its performance in a 7×25 Gb/s nology, FR); Virginie Nodjiadjim (Alcatel-Thales 3-5 Lab, FR); Jean- WDM direct-detection single-sideband 16QAM Nyquist-subcar- Yves Dupuy (III-V Lab, FR); Sebastien Bigo (Nokia Bell Labs, FR) rier modulation system. The scheme achieves a doubling of the We demonstrate an IM/DD PAM-4 optical transceiver operating transmission reach. at 84 and 100 Gbaud, and achieve successful demodulation after 1 km and 500 m of standard single mode fiber, respectively. Electrical generation is enabled by an integrated high-speed selector power DAC.
M.2.A.2 • 16:15 M.2.B.2 • 16:15 Cladding Pumped Seven-Core EDFA Using an Absorp- Artificial Neural Networks for Linear and Non-Linear Im- tion-Enhanced Erbium Doped Fibre pairment Mitigation in High-Baudrate IM/DD Systems Yukihiro Tsuchida, Koichi Maeda and Kengo Watanabe (Furukawa Jose Manuel Estaran, Rafael Rios-Müller, Miquel A. Mestre (Nokia Electric co., Ltd., JP); Koki Takeshima (KDDI R&D Laboratories Bell Labs, FR); Filipe Jorge (Alcatel Thales III-V Lab, joint la: Bell Inc., JP); Toru Sasa, Tsunetoshi Saito and Shigehiro Takasaka Labs and Thales Research and Technology, FR); Haik Mardoyan (Furukawa Electric co., Ltd., JP); Yu Kawaguchi and Takehiro (Nokia Bell Labs, FR); Agnieszka Konczykowska and Jean-Yves Tsuritani (KDDI R&D Laboratories, Inc., JP); Ryuichi Sugizaki Dupuy (III-V Lab, FR); Sebastien Bigo (Bell Labs, Alcatel-Lucent, FR) (Furukawa Electric co., Ltd., JP) We propose using artificial neural networks onto IM/DD optical We fabricate a seven-core erbium doped fibre that has links to infer simultaneously linear and non-linear channel res enhanced absorption cores. We demonstrate C-band clad- ponse. We experimentally exploit this information on an 84-GBd ding-pumped amplification with 20 dB gain, 6 dB NF, 15 dBm 4-PAM system, proving up to 10x BER improvement over FFE output power, and -53 dB core-to-core averaged crosstalk. after 1.5-km SSMF.
M.2.A.3 • 16:30 M.2.B.3 • 16:30 Invited M.2.C.2 • 16:30 Novel 6-Mode Fibre Amplifier with Large Erbium-Doped Power Efficient Coherent Transceivers 112 Gb/s PAM-4 Using a Directly Modulated Laser with Linear Area for Differential Modal Gain Minimization Jonas C Geyer, Christian Rasmussen, Bhupen Shah, Torben Niel- Pre-Compensation and Nonlinear Post-Compensation Yuta Wakayama (KDDI R&D, JP); Koji Igarashi (Osaka University, sen and Mehrdad Givehchi (Acacia Communications, Inc., USA) Yuliang Gao, John C Cartledge, Scott Yam and Ali Rezania JP); Daiki Soma, Hidenori Taga and Takehiro Tsuritani (KDDI R&D We review critical areas in the design process of power efficient (Queen’s University, CA); Yasuhiro Matsui (Finisar Corp, USA) Laboratories, Inc., JP) coherent transceivers, and we highlight the achievable power For 112 Gb/s PAM-4 short reach transmission using a directly We demonstrate a cladding-pumped six-mode fibre amplifier saving by designing for a particular application as well as power modulated laser, the end-to-end frequency response is used to with a widely erbium-doped distribution over the core for uniform and cost savings when using higher order modulation. pre-compensate bandwidth limitations and a Volterra equalizer is overlap between spatial modes and the gain medium. The used to post-compensate nonlinear signal distortion. differential modal gain of less than 3.3 dB was achieved in the entire C-band.
M.2.A.4 • 16:45 M.2.C.3 • 16:45 Core-pumped 10-mode EDFA with Cascaded EDF 112 Gb/s PAM-4 Optical Signal Transmission over 100-m Configuration OM4 Multimode Fiber for High-Capacity Data-Center Masaki Wada and Taiji Sakamoto (NTT Corporation, JP); Shinichi Interconnects Aozasa (NTT Corporation & NTT Access Network Service Sys- Fotini Karinou, Nebojsa Stojanovic, Cristian Prodaniuc and Qiang tems Laboratories, JP); Takayoshi Mori, Takashi Yamamoto and Zhang (Huawei Technologies Duesseldorf GmbH, DE); Thomas Kazuhide Nakajima (NTT Corporation, JP) Dippon (Keysight Technologies Deutschland GmbH, DE) We experimentally demonstrate a 10-mode fibre amplifier 112 Gb/s PAM-4 transmissions over 100-m OM4 MMF is consisting of EDFs with a step-and-ring erbium concentration demonstrated using a multi-mode 850-nm VCSEL. Results show profile. We achieve a low differential modal gain below 3.5 dB and that BER below the FEC limit can be achieved when employing a low noise figure (4.5-7.0 dB) with a core-pumped configuration equalization (FFE/MLSE) at the receiver. MLSE complexity vs. in the C-band. performance is also investigated.
M.2.A.5 • 17:00 Invited M.2.B.4 • 17:00 M.2.C.4 • 17:00 Upgraded Design and characterization of multicore erbium-doped Non-linearity Compensation of High-Speed PAM4 Signals 100 GHz EML for High Speed Optical Interconnect fibers from Directly-Modulated Laser at High Extinction Ratio Applications Sophie LaRochelle, Cang Jin and Younes Messaddeq (Université Nobuhiko Kikuchi and Riu Hirai (Center for Technology Innovation, Oskars Ozolins (Acreo Swedish ICT, SE); Miguel Olmedo (Royal Insti- Laval, CA) Hitachi Ltd., JP); Takayoshi Fukui (Oclaro Japan, JP) tute of Technology, SE); Xiaodan Pang ( Acreo Swedish ICT AB, SE); We discuss the design and performance of double-cladding We propose a new non-linear waveform compensation scheme Simone Gaiarin (Technical University of Denmark, DK); Aditya Kakkar multicore erbium-doped fibers for space-division multiplexing. We for DML-based PAM signals applicable either at transmitter or and Aleksejs Udalcovs (KTH Royal Institute of Techology, SE); Klaus describe optimization of signal core and pump annular-cladding receiver-side, and its effectiveness is verified with 56-Gbit/s PAM4 Engenhardt and Tadeusz Asyngier (Tektronix GmbH, PL); Richard to improve pumping efficiency and demonstrate designs leading experiments with less than 0.1-dB sensitivity penalties up to 8.9- Schatz (Kista Photonic Research Centre (KPRC), Royal Institute of to gain >19 dB and noise figure <6 dB. dB extinction ratio. Technology (KTH), SE); Jie Li (Acreo Swedish ICT AB, SE); Fredrik Nordwall (Tektronix GmbH, SE); Urban Westergren (Kista Photonic Research Centre (KPRC), Royal Institute of Technology (KTH), SE); Darko Zibar (DTU Fotonik, depertment of Photonic Engineering, Technical University of Denmark, DK); Sergei Popov (Royal Institute of Technology, SE); Gunnar Jacobsen (Acreo AB, SE) We report on a 116 Gbit/s OOK, 4PAM and 105 Gbit/s 8PAM optical transmitter using InP-based integrated EML for intercon- nect applications with up to 30 dB static extinction ratio and over 100 GHz 3-dB bandwidth with 2 dB ripple. M.2.B.5 • 17:15 Experimental Investigation of Impulse Response Shortening for Low-Complexity MLSE of a 112-Gbit/s PAM-4 Transceiver Sjoerd van der Heide (Eindhoven University of Technology & ADVA Optical Networking SE, NL); Nicklas Eiselt (Technical University of Denmark, DK); Helmut Griesser (ADVA Optical Networking SE, DE); Juan Jose Vegas Olmos (Technical University of Denmark, DK); Idelfonso Tafur Monroy (Technical University of Denmark, Denmark & ITMO University, RU); Chigo Okonkwo (Eindhoven University of Technology, NL) An optimized channel shortening method for reduced com- plexity MLSE detection enables the compensation of severe in- ter-symbol interference. Experimental investigations demonstrate the benefit on the performance for a severely bandwidth limited 112-Gbit/s PAM-4 transmission system with residual chromatic dispersion.
18:00 - 20:30 Welcome Reception | Foyer CCD | 32 Technical Programme Monday, September 19, 2016 • 16:00 - 17:30
M.2.D: Room 15 M.2.E: Room 110 M.2.F: Room 112 Short Distance DirectSC5 Detection Systems Transmitters I SC2 Data Center NetworksSC6 Chair: Gordon Ning Liu (Huawei Technologies Chair: Romain Brenot (III-V Lab & Nokia Bell Chair: Steinar Bjørnstad (NTNU, NO) Co. Ltd., PRC) Labs, FR)
M.2.D.1 • 16:00 M.2.E.1 • 16:00 Invited M.2.F.1 • 16:00 Invited Experimental Demonstration of 112-Gbit/s PAM-4 over up High-Speed Directly Modulated Heterogeneously Integra A roadmap for evolving towards optical intra-data-center to 80 km SSMF at 1550 nm for Inter-DCI Applications ted InP/Si DFB Laser networks Nicklas Eiselt (Technical University of Denmark, DK); Sjoerd van Geert Morthier and Amin Abbasi (Ghent University, BE); Jochem Lars Dittmann (Technical University of Denmark, DK); Anna der Heide (Eindhoven University of Technology & ADVA Optical Verbist, Shahram Keyvaninia and Xin Yin (Ghent University - Manolova Fagertun (Telia Denmark, DK); Valerija Kamchevska, Networking SE, NL); Helmut Griesser (ADVA Optical Networking IMEC, BE); Johan Bauwelinck (Ghent University - iMinds, BE); Michael Galili, Leif Oxenløwe, Sarah Ruepp and Michael S. Berger SE, DE); Michael Eiselt (ADVA, DE); Chigo Okonkwo (Eindhoven Gunther Roelkens (Ghent University - IMEC, BE); Francois Lelarge (Technical University of Denmark, DK) University of Technology, NL); Juan Jose Vegas Olmos (Technical (Alcatel Thales III-V Lab, FR); Guang-Hua Duan (III-V Lab, FR) The paper focuses on presenting an updated view on the University of Denmark, DK); Idelfonso Tafur Monroy (Technical We discuss how InP membrane laser diodes, heterogeneously state of the art in data centre networks. The EU project COSIGN University of Denmark, Denmark & ITMO University, RU) integrated on SOI can be designed for high speed operation. has provided optical DCN roadmaps, strategies and a tech- We experimentally demonstrate 112-Gbit/s PAM-4 over 80 km This is illustrated with several static and dynamic characteristics no-economic analysis of the involved industrial partners’ value SSMF at 1550 nm. It is shown, that a channel shortening filter of fabricated lasers. We finally report link experiments with the proposition. (CSF) matched to the memory of a subsequent MLSE significantly modulated lasers. improves the performance while keeping complexity manageable.
M.2.D.2 • 16:15 Single Wavelength 248-Gb/s transmission over 80-km SMF Based on Twin-SSB-DMT and Direct Detection Liang Zhang and Tianjian Zuo (Huawei, PRC); Qiang Zhang (Hua- wei Technologies Duesseldorf GmbH, DE); Jie Zhou, Enbo Zhou and Gordon Ning Liu (Huawei Technologies Co. Ltd., PRC) We propose a single-polarization direct-detection twin-SSB- DMT system. Enabled by MIMO-array DSP, transmissions of 248-Gb/s over 80-km SMF with a BER of 1.8e-2 ( M.2.D.3 • 16:30 M.2.E.2 • 16:30 M.2.F.2 • 16:30 Upgraded 112-Gbit/s Intensity-Modulated Direct-Detect Vesti- 10-40 Gbit/s Hybrid III-V/Si wavelength-tunable transmitter Flexible Architecture and Control Strategy for Metro-Scale gial-Sideband PAM4 Transmission over an 80-km SSMF for short- and long-reach communications Networking of Geographically Distributed Data Centers Link Guilhem de Valicourt, Chia-Ming Chang, Young-Kai Chen and Matteo Fiorani (KTH Royal Institute of Technology, SE); Payman Jeffrey Lee, Noriaki Kaneda and Young-Kai Chen (Nokia Bell Sethumadhavan Chandrasekhar (Nokia Bell Labs, USA); Anaelle Samadi and Yiwen Shen (Columbia University, USA); Lena Labs, USA) Maho (III-V Lab, FR); Romain Brenot (III-V Lab & Nokia Bell Labs, Wosinska (KTH Royal Institute of Technology, SE); Keren Bergman Employing vestigial-sideband 4-level pulse amplitude modula- FR); Po Dong (Nokia Bell Labs, USA) (Columbia University, USA) tion (VSB-PAM4), single-channel as well as five-channel DWDM We demonstrate an ultra-compact hybrid tunable III-V/Si This paper proposes a flexible architecture and control strategy 112-Gbit/s per wavelength transmission is experimentally demon- transmitter with more than 28 nm tuning range. We successfully to enable adaptive resource allocation in metro-scale inter data strated over an 80-km standard single-mode fiber. Chromatic achieved modulation up to 40 Gbit/s and transmission over 20 center networks. Experimental implementation and numerical dispersion is compensated using digital signal processing at the (100) km at 25 (10) Gbit/s. evaluations are presented, proving substantial benefits in terms of receiver. transmission time and resource usage. M.2.D.4 • 16:45 M.2.E.3 • 16:45 Improvement in Bandwidth-Limitation Tolerance and 50km Error Free Transmission at 10Gb/s with an Integrated Achievement of 1-Sps Chromatic-Dispersion Pre-com- Hybrid III-V on Silicon Directly Modulated DFB Laser and pensation Using Polarization-Interleaved 4-Level/7-Level Ring Resonator Coding PAM Antonin Gallet (III-V lab, a joint lab of Nokia, Thales and CEA, FR); Shuto Yamamoto, Akira Masuda, Hiroki Kawahara, Shingo Kawai Alexandre Shen and Dalila Make (Alcatel Thales III-V Lab, FR); and Mitsunori Fukutoku (NTT, JP) Guang-Hua Duan (III-V Lab, FR); Ségolène Olivier (CEA-Leti, FR); We have achieved polarization-interleaved 4-level/7-level Guillaume Levaufre (III-V lab, a joint lab of Nokia, Thales and CEA coding PAM transmission using 1-Sps pre-compensation for Leti, FR); Stéphane Malhouitre (CEA-Leti, FR); Nils Girard (III-V lab, chromatic dispersion with a narrow-electrical-bandwidth limitation a joint lab of Nokia, Thales and CEA Leti, FR); Francois Lelarge based on numerical simulations. We experimentally confirm the (Alcatel Thales III-V Lab, FR); Romain Brenot (III-V Lab & Nokia Bell scheme feasibility using 112-Gb/s signal and 20-GHz bandwidth Labs, FR); Jean-Guy Provost (Alcatel Thales III-V Lab, FR) limitation in a conventional direct-detection system. A directly-modulated Hybrid III-V/SOI DFB laser and a ring resonator are integrated on a single chip. Thanks to the ring resonator filter which provides extinction ratio enhancement, error free transmission at 10Gb/s over 50 km single mode fibre is demonstrated. M.2.D.5 • 17:00 M.2.E.4 • 17:00 M.2.F.3 • 17:00 Transmission and Direct Detection of 300-Gbps DFT-S Two-Section RSOA with Enhanced Modulation-Cancelling ARON: Application-Driven Reconfigurable Optical Network- OFDM Signals Based on O-ISB Modulation with Joint Effect for Self-Seeded Colorless WDM Transmitter ing for HPC Data Centers Image-Cancellation and Nonlinearity-Mitigation Peng Zhou, Wenhui Zhan and Takuo Tanemura (University of Guojun Yuan (Institute of Computing Technology & Chinese Yuanquan Wang (Fudan University, PRC); Jianjun Yu and Hungc- Tokyo, JP); Masaru Mukaikubo (Oclaro Japan, Inc., JP); Yoshiaki Academy of Sciences, PRC); Roberto Proietti (University of Cali- hang Chien (ZTE (TX) Inc, USA); Xinying Li and Nan Chi (Fudan Nakano (University of Tokyo, JP) fornia, Davis, USA); Xiaoli Liu (Institute of Computing Technology, University, PRC) We propose and demonstrate novel RSOA design with Chinese Academy of Sciences, PRC); Alberto Castro Casales By utilizing joint image-cancellation and nonlinearity-mitigation segmented electrodes to enhance the modulation cancelling (University of California, Davis, USA); Dawei Zang and Ninghui algorithms, we experimentally demonstrate record 300-Gbps and effect without sacrificing the bandwidth for self-seeded colorless Sun (Institute of Computing Technology, Chinese Academy of 240-Gbps direct-detection optical independent-sideband DFT-S WDM transmitter applications. Optimal driving condition is derived Sciences, PRC); CheYu Liu (University of California, San Diego, OFDM signals at BTB and transmission over 160-km SSMF with numerically and confirmed experimentally at 10 Gb/s. USA); Cao Zheng (ECE University of California Davis, PRC); the BER less than 2×10-2, respectively. S. J. Ben Yoo (University of California, Davis, USA) We designed and experimentally demonstrated an appli- cation-driven adaptive network that supports fast topology reconfiguration by wavelength routing to match applications’ communication characteristics. Even in a small-scale system, 1.25× performance improvement is achieved by performing network reconfiguration. M.2.D.6 • 17:15 M.2.E.5 • 17:15 M.2.F.4 • 17:15 49 Gbit/s Direct-Modulation and Direct-Detection Trans- Novel Approach for Self-Seeded Cavity based on Reflective Scalability Assessment of the OPSquare Architecture mission over 80 km SMF-28 without Optical Amplification Electro Absorption Modulator Semiconductor Optical for High-capacity and Large-connectivity Data Center or Filtering Amplifier Networks Zhixin Liu (University of Southampton, UK); M. Sezer Erkilinc (Uni- Anaelle Maho (III-V Lab, FR); Sophie Barbet (Alcatel-Thales III-V Wang Miao (Eindhoven University of Technology, NL); Fulong versity College London, UK); Brian Kelly (Eblana Photonics, IR); Lab, IT); Karim Mekhazni (III-V Lab, FR); Romain Brenot (III-V Lab Yan (Eindhoven University of Technology & TU/e, PRC); Nicola John Carroll (Dublin City University, IR); Richard Phelan (Eblana & Nokia Bell Labs, FR) Calabretta (COBRA Research Institute, NL) Photonics, IR); Benn Thomsen and Robert Killey (University Col- We propose a novel approach for self-seeded cavities by The OPSquare data center network performance are investigat- lege London, UK); David J Richardson (University of Southamp- replacing the usual RSOA by a REAMSOA. With discrete com- ed for different modulation format and high-capacity 4×25Gb/s ton, UK); Polina Bayvel (University College London, UK); Radan ponents, we only achieved transmission on 50km at 2.5Gbit/s, waveband, 28Gb/s PAM4 and 40Gb/s DMT traffic. Results show Slavík (ORC, University of Southampton, UK) although each device can operate up to 20Gbit/s. >8 dB dynamic range with <3 dB penalty for optical switches at We demonstrate direct-modulation of a discrete mode laser us- scale of 64×64. ing Discrete Multi-Tone modulation for transmission distances up to 100 km in the 1550 nm band. A large operational temperature range (0-65degC) is also demonstrated. 18:00 - 19:30 Welcome Reception | Foyer CCD | 33 Technical Programme Tuesday, September 20, 2016 • 09:00 - 10:30 Tu.1.A: Room 18+19 Tu.1.B: Room 17 Tu.1.C: Room 16 Light Sources forSC2 Interconnects Multi-Layer SDNSC6 Advanced ModulationSC4 Chair: Sylvie Menezo (CEA-LETI, FR) Chair: Raul Muñoz (CTTC, ES) Chair: David Hillerkuss (ETH Zurich, CH) Tu.1.A.1 • 09:00 Tutorial Tu.1.B.1 • 09:00 Invited Tu.1.C.1 • 9:00 Applications of photonic crystal and heterogeneous inte- Operator use cases that benefit from multi-layer optimiza- Duobinary Pulse-Shaped Complex Modulation of Directly gration to ultra-low-energy lasers for optical interconnects tion and application awareness Modulated Lasers and datacenter networks Victor Lopez (Telefonica, ES); Domenico Siracusa (CREATE-NET, Di Che (The University of Melbourne & National ICT Australia, AU); Shinji Matsuo (NTT Corporation, JP) IT); Dimitrios Klonidis (AIT, GR); Juan Pedro Fernández-Palacios Feng Yuan (University of Melbourne, AU); Hamid Khodakarami This tutorial reviews the latest developments in membrane (Telefónica I+D, ES) (University of Tehran, IR); William Shieh (University of Melbourne, lasers, including photonic crystal lasers and heterogeneously inte- Multi-layer optimization enables the operators to optimize their USA) grated lasers on Si. These devices are directly modulated with low packet and transport resources. The application awareness will We propose duobinary pulse shaping for the complex mod- operating energy. Heterogeneous integration technologies enable provide potential savings as well as will offer a better adaptation ulation of directly modulated lasers, which significantly relieves us to fabricate large-scale photonic integrated circuits. to the network services to the applications. the optical spectrum expansion induced by frequency chirp. The newly designed 3-tap MLSE decoder is verified via both simula- tion and 10-Gbaud PAM-4 experiment. Tu.1.C.2 • 09:15 Eight Dimensional Optimized Modulation for IM-DD 56 Gbit/s Optical Interconnections Using 850 nm VCSELs Xiaofeng Lu and Anna Tatarczak (Technical University of Denmark, DK); Idelfonso Tafur Monroy (Technical University of Denmark, Denmark & ITMO University, RU) A novel 8-dimensional optimized modulation format is designed and compared with PAM-n in a 28-GBd 850 nm VCSEL based IM-DD system, enabling the transmission on 100GBASE-SR4 FEC threshold over various 100 m MMF links. Tu.1.B.2 • 09:30 Tu.1.C.3 • 09:30 Peer SDN Orchestration: End-to-End Connectivity Service Stable WDM-Signal-and-LO-frequency Synchronisation and Provisioning Through Multiple Administrative Domains Transmission Employing Multi-Carrier Light Sources and a Ricard Vilalta and Arturo Mayoral (CTTC, ES); Victor Lopez and Multi-Core Fibre for Coherent Photonic Networks Víctor Uceda (Telefónica, ES); Ramon Casellas, Ricardo Martinez Kunihiko Mori, Fukutaro Hamaoka, Kengo Horikoshi (NTT Corpo- and Raul Muñoz (Centre Tecnologic de Telecomunicacions de ration, JP); Mitsunori Fukutoku (NTT Innovation Laboratories, JP) Catalunya (CTTC), ES); Alejandro Aguado, Jaume Marhuenda, We successfully demonstrate a novel technique for synchron- Reza Nejabati and Dimitra Simeonidou (University of Bristol, UK); ising optical frequencies in WDM signals and LO lights. We can Noboru Yoshikane, Takehiro Tsuritani and Itsuro Morita (KDDI R&D simultaneously stabilise the polarisations of multi-carrier LO lights, Laboratories, JP); Thomas Szyrkowiec (ADVA Optical Networking which are transmitted with SDM-WDM signals via a multi-core & Technische Universität München, DE); Achim Autenrieth (ADVA fibre for digital coherent detection. Optical Networking, DE) This papers proposes the usage of Control Orchestration Protocol (COP) as an East-West interface in order to interconnect different SDN controllers (peer model) through multiple administra- tive domains. An experimental validation of network connectivity provisioning is presented in an international testbed. Tu.1.B.3 • 09:45 Tu.1.C.4 • 09:45 First demonstration of SDN-controlled Multi-Layer Resto- 64-Gb/s Optical Transmission Using DFB-EAM Transmit- ration and its advantage over Optical Restoration ter and SOA-PIN-TIA Receiver with -23.5-dBm Record Itay Maor, Ori Gerstel (Sedona Systems Ltd., IL); Victor Lopez Sensitivity (Telefonica, ES); Thomas Szyrkowiec (ADVA Optical Networking Philippe Angelini (III-V Lab, FR); Fabrice Blache (Alcatel-Thales & Technische Universität München, DE); Achim Autenrieth (ADVA III-V Lab, FR); Filipe Jorge (Alcatel Thales III-V Lab, joint la: Bell Optical Networking, DE); Bernd Pruessing, Nuno Borges (Coriant Labs and Thales Research and Technology, FR); Christophe Cail- GmbH, DE); Fisher FU (Huawei Technologies, PRC); Guiu Fabre- laud (Alcatel-Thales III-V Lab, FR); Michel Goix, Karim Mekhazni, gas (Nokia, ES); Juan P. Fernández-Palacios (Telefónica I+D, ES) Bernadette Duval (III-V Lab, FR); Franck Mallécot (Alcatel-Thales We demonstrate a full implementation of centrally orchestrated III-V Lab, FR); Philippe Charbonnier, Jean-Yves Dupuy (III-V Lab, multi-layer restoration over commercial optical and IP gear. The FR); Mohand Achouche (Alcatel-Thales III-V Lab, FR) process considers the behavior of the IP layer. Compared to This paper reports a transmission system for next generation optical restoration, the packet loss is 54% lower. short-reach high-speed optical communications. It consists of a 63-GHz DFB-EAM transmitter and a SOA-PIN-TIA receiver with -23.5-dBm sensitivity (BER=10-9) at 64 Gb/s in NRZ-OOK opera- tion, yielding penalty<0.5 dB over 2-km transmission. Tu.1.A.2 • 10:00 Invited Tu.1.B.4 • 10:00 Higher Speed VCSEL Links using Equalization Interoperable Multi-Domain Delay-aware Provisioning Daniel Kuchta (IBM T.J. Watson Research Center, USA) using Segment Routing Monitoring and BGP-LS Adver- With FFE Equalization, VCSEL-based links using NRZ modu- tisement lation have been demonstrated error-free to 71Gb/s at 850nm, Francesco Paolucci (Scuola Superiore Sant’Anna, IT); Víctor 56Gb/s at 1530nm, and 50Gb/s to 90C. This paper will review Uceda (Telefonica, ES); Andrea Sgambelluri (KTH Royal Institute this progress and speculate on the realization of 100Gb/s serial of Technology, SE); Filippo Cugini (CNIT, IT); Oscar González de links. Dios (Telefonica I+D, ES); Victor Lopez and Luis M. Contreras (Telefonica, ES); Paolo Monti (KTH Royal Institute of Technology, SE); Paola Iovanna, Fabio Ubaldi and Teresa Pepe (Ericsson, IT); Piero Castoldi (Scuola Superiore Sant’Anna, IT) This paper demonstrates a multi-domain SDN orchestrator using delay information to provision network services using BGP- LS and a novel monitoring system enabled by Segment Routing. Moreover, it is the first implementation and interoperability of the BGP-LS extensions for TE metrics. Tu.1.B.5 • 10:15 Experimental Demonstration of Policy-based Dynamic End- to-End Provisioning over Multi-Layer Network using SDN Jaume Marhuenda, Alejandro Aguado, Sarvesh Sanjay Bidkar, Emilio Hugues-Salas, Reza Nejabati and Dimitra Simeonidou (University of Bristol, UK) Contemporary transport networks require dynamic multi-layer service provisioning to support ever-growing application traffic. We present a software platform architecture based on SDN principles combined with a network policy engine to experimen- tally demonstrate dynamic multi-layer provisioning over a national dark-fibre network. 10:30 - 11:00 Coffee Break | Exhibition Hall | 34 Technical Programme Tuesday, September 20, 2016 • 09:00 - 10:30 Tu.1.D: Room 15 Tu.1.E: Room 110 Tu.1.F: Room 112 SDM TransmissionSC5 I Coding and ReceiversSC3 Optical Access forSC7 5G Chair: Yutaka Miyamoto (NTT Network Innovation Chair: Yves Jaouën (Telecom ParisTech, FR) Chair: Yan Shi (Genexis, NL) Laboratories, JP) Tu.1.D.1 • 09:00 Invited Tu.1.E.1 • 09:00 Tu.1.F.1 • 09:00 Ultra-high capacity SDM/WDM transmission over multicore A Low-complexity Implementation of Full-rate Polariza- 5G Transport in Future Access Network and multimode fibers tion-Time Codes for PDL Mitigation in Single-Carrier Opti- Dirk Breuer (Deutsche Telekom T-Labs, DE); Erik Weis (Deutsche Takehiro Tsuritani (KDDI R&D Laboratories, Inc., JP) cal Transmissions using the Constant Modulus Algorithm Telekom, Laboratories, DE); Klaus Grobe (ADVA, DE); Sandro Recent progress and future challenges on high-capacity spatial Elie Awwad, Patrice Tran (Nokia Bell Labs, FR); Gabriel Charlet Krauss (Deutsche Telekom AG, DE); Francesco Musumeci (Po- division multiplexing (SDM) transmission technologies using multi- (Bell Labs, Alcatel-Lucent, FR) litecnico di Milano, IT); Jose Alfonso Torrijos Gijon (Telefonica I+D, core and multimode fibers are reviewed and discussed. We demonstrate through simulations and experimental ES); Björn Skubic (Ericsson AB, SE) measurements a low-complexity implementation of the 2x2 Silver Techno-economic results for 5G back/fronthaul based NG- code to mitigate PDL in a single-carrier PDM system using CMA PON2 with PtP-WDM-PON overlay and WR-WDM-PON for equalization. The obtained gains are compared to the optimal different RAN splits are presented for an urban area. It is shown ones achieved by an ML decoder. that the convergence benefit with residential access decreases significantly for high bit rate interfaces. Tu.1.E.2 • 09:15 Tu.1.F.2 • 09:15 Invited Full-Channel Parallel Measurement of 4x20-Gb/s All-Optical Optical Network Technologies for Wireless Communication OFDM Signals by Using Loop-Assisted Coherent Matched Network Detector Jun Terada, Tatsuya Shimada, Tatsuya Shimizu and Akihiro Otaka Takahide Sakamoto (National Institution of Information and Com- (NTT Corporation, JP) munications Technology, JP); Guo-Wei LU (Institute of Innovative This paper describes trends of 5G mobile networks and RAN Science and Technology, Tokai University & National Institute of technologies. The Ethernet-based vBBU is expected to support Information and Communications Technology (NICT), JP); Naokat- several types of BBU and PON with low-latency scheme is a su Yamamoto (National Institute of Information and Communica- good candidate for MFH transmission in 5G networks. tions Technology, JP) We demonstrate measurement of 4x20-Gb/s all-optical OFDM signals by using loop-assisted coherent matched detector. All-op- tical OFDM signal is projected onto the time-frequency domain first; then, all sub-channels are restored through digital matrix processing, without relying on optical FFT. Tu.1.D.2 • 09:30 Invited Tu.1.E.3 • 09:30 Pb/s, Homogeneous, Single-mode Multi-Core Fiber Quadrature Decomposition of a 20 Gbaud 16-QAM Signal Systems into 2×4-PAM Signals Benjamin J Puttnam (National Institute of Information and Com- Abel Lorences-Riesgo (Chalmers University of Technology, SE); munications Technology, JP); Ruben S Luís (NICT, USA); Tobias A. Eriksson (Nokia Bell Labs, DE); Mikael Mazur and Jun Sakaguchi, Werner Klaus, Jose Manuel Delgado Mendinueta, Peter A Andrekson (Chalmers University of Technology, SE); Yoshinari Awaji and Naoya Wada (National Institute of Information Magnus Karlsson (Chalmers University of Technology & Photonics and Communications Technology (NICT), JP); Erik Agrell (Chalm- Laboratory, SE) ers University of Technology, SE) We propose a novel phase-sensitive processor capable of We discuss multi Pb/s transmission using homogeneous, operating at low nonlinear phase shifts. With a nonlinear phase single-mode, multi-core fibers. We outline the key components shift of 2×15 rad, quadrature decomposition is demonstrated with of a recent high capacity demonstration, the consequences of penalty of 0.5 dB at BER=10e-3. fiber properties and the potential for enhanced efficiency from spatial-super-channel transmission. Tu.1.E.4 • 09:45 Tu.1.F.3 • 09:45 Receiver Memory Requirement in Mode Delay Compensat- Performance Demonstration of Real Time Compressed ed Few-Mode Fibre Spans with Intermediate Coupling CPRI Transport Christian Sanchez, Filipe M. Ferreira, Naoise Mac Suibhne, Zakaria Tayq, Antoine Quere, Luiz Anet Neto, Philippe Chanclou, Stylianos Sygletos and Andrew Ellis (Aston University, UK) Fabienne Saliou and Kamil Grzybowski (Orange Labs, FR); The required receiver time window after propagation through Christelle Aupetit-Berthelemot (XLIM - University of Limoges, FR); few-mode fibre is studied for a broad range of coupling and mode Sun Yoo and Sung Hong (Solid, KR) delay span configurations. Under intermediate coupling, effective A real time CPRI compression solution is experimentally mode delay compensation is observed for a compensation period investigated. Tests have been performed on a LTE fronthaul link of 25km. measuring its impact on EVM and latency. The obtained results show a 73% compression compliant with 3GPP specifications. Tu.1.D.3 • 10:00 Tu.1.E.5 • 10:00 Invited Tu.1.F.4 • 10:00 Invited Demonstration of 0.52 Pb/s Potential Transmission Capaci- Joint Modulation and Coding Optimization for Long-Haul Optics For 5G: How Can We Combine Low Cost With ty over 8,830 km using Multicore Fiber Nyquist WDM Transmissions Demanding Requirements? Alexey Turukhin, Hussam G. Batshon, Matthew Mazurczyk and Rafael Rios-Müller, Jeremie Renaudier, Gabriel Charlet (Nokia Bell Antonio Tartaglia (Ericsson Telecomunicazioni S.p.A., IT) Yu Sun (TE Subcom, USA); Carl Davidson (Tyco Telecommunica- Labs, FR) 5G is the opportunity for optical technologies to become in- tions, USA); Jin-Xing Cai (TE SubCom, USA); Oleg Sinkin (Tyco We review modulation format choice and optimization for creasingly relevant across all networking domains. We will review Telecom, USA); William Patterson (Tyco Electronics Subsea Com- long-haul optical communications systems taking into account how state-of-the-art industrial technologies are evolving to meet munications, USA); Gregory Wolter and Maxim Bolshtyansky (TE channel coding implementation constraints such as overhead and its most demanding requirements and discuss the challenge of Subcom, USA); Dmitri Foursa (Tyco Telecommunications, USA); decoder architecture as well as transmitter impairments. finding the best cost structures. Alexei Pilipetskii (Tyco Electronics Subsea Communications, USA) We demonstrate feasibility of 0.52Pb/s transmission over 8,830km using a 12-core fiber, C+L band EDFAs, and a new cod- ed modulation format. Compared to optimal 8QAM with the same 4.86b/s/Hz spectral efficiency, our modulation scheme achieves 1.0dB improvement in receiver sensitivity. 10:30 - 11:00 Coffee Break | Exhibition Hall | 35 Technical Programme Tuesday, September 20, 2016 • 11:00 - 12:30 Tu.2.A: Room 18+19 Tu.2.B: Room 17 Tu.2.C: Room 16 Digital Signal ProcessingSC3 Network AutomationSC6 Measurement andSC4 Control Chair: Benn C Thomsen (University College Chair: Sebastien Bigo (Bell Labs, Alcatel-Lucent, Chair: Toshihiko Hirooka (Tohoku University, JP) London, UK) FR) Tu.2.A.1 • 11:00 Tutorial Tu.2.B.1 • 11:00 Tu.2.C.1 • 11:00 Digital Signal Processing for Multilevel Modulation Formats A Learning Living Network for Open ROADM Networks OSNR System Margin Estimation by Nonlinear Noise Insen- Seb J Savory (University of Cambridge, UK) Shoichiro Oda, Masatake Miyabe and Setsuo Yoshida (Fujitsu sitive OSNR Monitor In this tutorial we explore digital signal processing (DSP) Laboratories Ltd., JP); Toru Katagiri and Yasuhiko Aoki (Fujitsu Tomohiro Yamauchi and Shoichiro Oda (Fujitsu Laboratories Ltd., techniques for multilevel modulation formats. We detail both Limited, JP); Jens C. Rasmussen (Fujitsu Laboratories Limited, JP); Liang Dou and Xiaofei Su (Fujitsu R&D Center, PRC); Takeshi transmitter DSP (encoding, modulation, equalisation and filtering) JP); Martin Birk and Kathy Tse (AT&T Laboratories, USA) Hoshida (Fujitsu Laboratories Limited, JP); Yasuhiko Aoki (Fujitsu and receiver DSP (equalisation, filtering, synchronisation, demod- We experimentally demonstrate a “living network” that autono- Limited, JP); Zhenning Tao (Fujitsu R&D Center Ltd., PRC); Jens ulation and decoding) after which we discuss current research mously keeps record of its path-level performance. The more ser- C. Rasmussen (Fujitsu Laboratories Limited, JP) challenges. vices are added, the more accurate the performance of a newly to We propose an OSNR system margin estimation technique be established service is estimated which enables operation close based on nonlinear noise insensitive OSNR monitoring. We ex- to performance limits. perimentally demonstrate its accuracy less than 0.3dB estimation error for five-subcarrier DP-16QAM superchannel in disper- sion-uncompensated transmission with various fiber launched power and various reaches. Tu.2.B.2 • 11:15 Tu.2.C.2 • 11:15 Bringing Data Analytics to the Network Nodes Deep Learning Based OSNR Monitoring Independent of Alba Vela, Anna Via, Marc Ruiz and Luis Velasco (Universitat Modulation Format, Symbol Rate, Chromatic Dispersion Politècnica de Catalunya (UPC), ES) Takahito Tanimura (The University of Tokyo & Fujitsu Laboratories Monitoring every 15 minutes imposes long traffic anomaly Ltd., JP); Takeshi Hoshida, Tomoyuki Kato, Shigeki Watanabe and detection times and thus, the monitoring frequency needs to be Jens C. Rasmussen (Fujitsu Laboratories Limited, JP); Makoto increased to reduce those times, which entails large amount of Suzuki and Hiroyuki Morikawa (The University of Tokyo, JP) monitoring data collected. Consequently, we propose bringing A deep neural network (DNN) is employed for optical data analytics to the nodes. performance monitoring. We show that DNN-based monitor successfully estimates OSNR of signals modulated in different formats and symbol rates in the presence of chromatic dispersion and polarization rotation without prior knowledge. Tu.2.B.3 • 11:30 Tu.2.C.3 • 11:30 A Machine Learning Approach for Dynamic Optical Channel Nonlinear Spatially Resolved Interferometer for Distance Add/Drop Strategies that Minimize EDFA Power Excursions Resolved Power and Gain Tilt Measurement Yishen Huang (Columbia University, USA); Wiem Samoud (Institut Andrew D. Shiner, Andrzej Borowiec, Michael Reimer, Douglas W Mines Telecom, Telecom ParisTech, CNRS LTCI, FR); Craig Gut- Charlton and Maurice O’Sullivan (Ciena Corporation, CA) terman (Columbia University, USA); Cedric Ware (Institut Mines- A new experimental technique for making distance resolved Télécom, Télécom ParisTech, CNRS LTCI, FR); Mounia Lourdiane measurements of the wavelength dependent power profile and (TELECOM SudParis, FR); Gil Zussman, Payman Samadi and gain evolution in multi-span telecommunications fiber links is Keren Bergman (Columbia University, USA) demonstrated. Results for a 10x80km span link agree with directly We demonstrate a machine learning approach to characterize measured powers to within 0.3 dB. channel dependence of power excursions in multi-span EDFA networks. This technique can determine accurate recommen- dations for channel add/drop with minimal excursions and is applicable to different network designs. Tu.2.B.4 • 11:45 Tu.2.C.4 • 11:45 Adaptive Guard-band Assignment with Adaptive Spectral Polarization Controller for Si photonic integrated circuits Profile Equalizer to Improve Spectral Usage of Impair- with an active closed loop control ment-Aware Elastic Optical Network Vito Sorianello (CNIT-Laboratory of Photonic Networks, IT); Ga- Hitoshi Takeshita, Hidemi Noguchi, Jun-ichi Abe, Shinsuke Fujisa- briele De Angelis, Philippe Velha, Tommasso Cassese and Valerio wa, Akio Tajima (NEC Corporation, JP) Preite (Scuola Superiore Sant’Anna, IT); Alberto Bianchi (Ericsson We propose an adaptive guard-band assignment method that Telecomunicazioni, IT); Francesco Testa (Ericsson Lab Italy, IT); solves its over-assignment problem and an adaptive spectral Marco Romagnoli (PGT Photonics, IT) profile equalizer to enhance its capability. Simulation and experi- A polarization insensitive silicon photonic circuit for the man- mental results demonstrate a 12.5% spectral usage improvement agement of any arbitrary polarization state of light coming from a and feasibility for application to actual networks. fiber linked to a remote source is demonstrated. WDM channels with a common arbitrary polarization at the input are automatically equalized. Tu.2.A.2 • 12:00 Tu.2.B.5 • 12:00 Invited Tu.2.C.5 • 12:00 Transmitter Impairment Mitigation and Monitoring for High Elastic all-optical networks: a new paradigm enabled by 2D Passive Optical Beam-steering Module with 7 Scan Baud-Rate, High Order Modulation Systems the physical layer. How to optimize network performances? Lines within 12.2°×5.6° for Free-space Indoor Communi- Chris Fludger, Theo Kupfer (Cisco Optical GmbH, DE) Vittorio Curri, Mattia Cantono, Roberto Gaudino (Politecnico di cation Receiver-based compensation algorithms for transmitter Torino, IT) Chin Wan Oh (Eindhoven University of Technology, NL); Robbert impairments such as timing skew, gain and offset imbalance and Physical layer equipment is the enabling technology for the van der Linden (Eindhoven University of Technology & Genexis quadrature error are presented. We demonstrate monitoring and elastic use of networks. We propose the statistical network BV., NL); Gustaaf Sutorius (Keysight Technologies, NL); Eduward diagnosis functions based on signal processing coefficients. assessment process as benchmarking method. As an example Tangdiongga (Eindhoven University of Technology, NL); Ton we compare PM-mQAM vs. TDHMF transceivers on a Pan-EU Koonen (COBRA, Eindhoven University of Technology, NL) network topology, considering three fibers. We experimentally demonstrate a two-dimensional (2D) passive optical beam-steering module constructed using reflection and transmission gratings for angular coverage of 12.2°×5.6° with seven scanning lines. We vigorously evaluate the 2D beam- steered system with OOK, 4-PAM and DMT transmission. Tu.2.A.3 • 12:15 Sequential MAP Detection for High Baud-Rate Systems with Pattern-Dependent Distortions Ali Bakhshali (Queens University, CA); Wai-Yip Geoffrey Chan, Ali Rezania, John C Cartledge (Queen’s University, CA) A sequential MAP detection strategy with a wide range in its performance-complexity trade-off is proposed to ameliorate pattern-dependent distortions due to transmitter and receiver limitations. A complexity reduction by a factor of 7 is reported based on the experimental results. 12:30 - 14:00 Lunch Break | Exhibition Hall | 14:00 - 16:00 Exhibition Only 36 Technical Programme Tuesday, September 20, 2016 • 11:00 - 12:30 Tu.2.D: Room 15 Tu.2.E: Room 110 Tu.2.F: Room 112 SDM TransmissionSC5 II MM-Wave DevicesSC2 Novel Fibre TechnologiesSC1 Chair: Rene Essiambre (Nokia, USA) Chair: Pascual Muñoz (VLC Photonics, ES) Chair: Camille-Sophie Bres (EDFL, CH) Tu.2.D.1 • 11:00 Tu.2.E.1 • 11:00 Tu.2.F.1 • 11:00 Invited Exploiting Selective Excitation of Strongly Coupled Modes 40 dB-Rejection Sharp-Edge Integrated SOI Phase-Shifted Optical Fibre Technologies for Future Communication to Reduce DMGD in Multi-mode Transmission Systems Bragg Grating Filter for Microwave Photonics Networks John van Weerdenburg (Eindhoven University of Technology, Giovanni Serafino (Scuola Superiore Sant’Anna, IT); Claudio Porzi Periklis Petropoulos (University of Southampton, UK) NL); Jose Antonio-Lopez and Juan Alvarado-Zacarias (CREOL, (Consorzio Nazionale Interuniversitario per le Telecomunicazioni, New transmission technologies need to be developed to satisfy USA); Denis Molin (Prysmian Group, FR); Marianne Bigot-Astruc IT); Philippe Velha and Nicola Andriolli (Scuola Superiore Sant’An- the ever increasing demand for communication traffic. This paper (Draka Communications, FR); Roy van Uden and Huug de Waardt na, IT); Paolo Ghelfi (CNIT, IT); Antonella Bogoni (Scuola Superiore reviews some recent research on optical fibre technology that (Eindhoven University of Technology, NL); Ton Koonen (COBRA, Sant’Anna, IT) aims at addressing this challenge. Eindhoven University of Technology, NL); Rodrigo Anezcua-Correa An integrated, high-order phase-shifted Bragg-grating realizing (CREOL, USA); Pierre Sillard (Prysmian, FR); Chigo Okonkwo steep-sloped optical passband filter with measured 41.5 dB out- (Eindhoven University of Technology, NL) of-band rejection and a transition bandwidth roll-off of 288 GHz/ By exploiting strong coupling in higher-order modes, we exper- nm is demonstrated in passive Silicon-on-Insulator technology imentally demonstrate reduced differential mode group delay by and verified in two different microwave photonics applications. a factor of 3. Comparing LP02+LP21 with respect to LP01+LP11 3-mode transmission, a 27% reduction in equalizer length is shown after 53.4km MMF transmission. Tu.2.D.2 • 11:15 Tu.2.E.2 • 11:15 Nonlinear Distortion in Mode Delay Compensated Few- Wavelength-tunable True Time Delay for Multi-beam Radio Mode Fibre Spans with Intermediate Coupling Beamformer in Multi-Gbps Satellite Communication Filipe M. Ferreira, Christian Sanchez, Naoise Mac Suibhne, Stylia- Netsanet Tessema (University of Eindhoven & COBRA Research nos Sygletos and Andrew Ellis (Aston University, UK) Institute, NL); Zizheng Cao (Eindhoven University of Technology, Nonlinear distortion in delay-compensated spans for intermedi- NL); J. H. C. (Johan) van Zantvoort (University of Eindhoven, NL); ate coupling is studied for the first time. Coupling strengths under Eduward Tangdiongga and A. B. (Bart) Smolders (Eindhoven -30dB/100m allow distortion reduction using shorter compensa- University of Technology, NL); Ton Koonen (COBRA, Eindhoven tion lengths and higher delays. For higher coupling strengths no University of Technology, NL) significant penalty results from shorter compensation lengths. We present a Si3N4 photonic integrated chip providing wavelength-dependent true time delay for forming multiple radio beams: a number of multi-Gbps connections from home-to-multi- ple satellites can be supported simultaneously. Tu.2.D.3 • 11:30 Upgraded Tu.2.E.3 • 11:30 Tu.2.F.2 • 11:30 10-Mode Mode-Multiplexed Transmission with Inline Fully-Packaged 71-76 GHz Coherent Photonic Mixer Experimental demonstration of Compact and Robust Amplification featuring WR-12 Output for CRoF Backhauling All-Fiber Orbital Angular Momentum Generator Roland Ryf, Haoshuo Chen, Nicolas K Fontaine, Amado and Besher Khani and Vitaly Rymanov (University of Duisburg-Essen, Xinglin Zeng, Yan Li, Jian Wu and Yongjie Tian (Beijing University Velázquez-Benítez (Nokia Bell Labs, USA); Jose Antonio-Lopez, DE); Jörg Honecker (u2t Photonics AG, DE); Andreas Gerhard of Posts and Telecommunications, PRC); Q Mo (Fiberhome Juan Alvarado-Zacarias and Zeinab Sanjabi Eznaveh (CREOL, Steffan (Finisar Berlin, DE); Andreas Stöhr (University of Duis- Telecommunication Technologies Co. Ltd, PRC); Wei Li (Beijing USA); Cang Jin (Université Laval & COPL, CA); Bin Huang (Nokia burg-Essen, DE) University of Posts and Telecommunications, PRC) Bell Labs, USA); Sun Hyok Chang (ETRI, KR); Burcu Ercan (UC Here, we report on a novel fully-integrated 70 GHz band (71- An all-fiber scalar orbital angular momentum generator is Davis, USA); Cedric Gonnet (Prysmian Group, FR); Marianne 76 GHz) rectangular-waveguide-type coherent photonic mixer demonstrated by cascading mode selective coupler and few Bigot-Astruc and Denis Molin (Draka Communications, FR); (WR12-CPX) module for coherent radio-over-fiber (CRoF) back- mode-polarization maintaining fiber. With the compactness and Frank Achten (Prysmian Group, NL); Pierre Sillard (Prysmian, FR); haul links, featuring a high-speed balanced photodetector and a robustness, this generator may play a key role in space division Rodrigo Anezcua-Correa (CREOL, USA) rectangular waveguide output (WR-12) for direct fiber-to-the-an- multiplexing systems. We demonstrate combined wavelength- and mode-multi- tenna connectivity. plexed transmission over a fiber with 10 spatial modes using all multimode components including an erbium-doped amplifier, an acousto-optics switch and a splitter arranged as a recirculating loop. Tu.2.E.4 • 11:45 Tu.2.F.3 • 11:45 Optoelectronic comb generation and cross-injection Microbending effects in hollow-core photonic bandgap locking of photonic integrated circuit for millimetre-wave fibers generation Eric Numkam Fokoua, Yong Chen, David J Richardson and Andrzej Jankowski (III-V Lab Thales Research & Technology and Francesco Poletti (University of Southampton, UK) CEA-LETI, FR); Gael Kervella (III-V Lab, FR); Mourad Chtioui We developed a model for the study of how microbends affect (Thales Air Systems, FR); Marco Lamponi (Huawei Technologies, the operation of hollow-core photonic bandgap fibers. Increased FR); Frédéric Van Dijk (Alcatel Thales III-V Lab, FR) loss due to intermodal coupling is predicted. Preliminary exper- We demonstrate how a monolithically integrated heterodyne imental observations are in good agreement with the model’s source was used for a 33.6 GHz signal generation using an predictions. optical solution by a combination of cross-optical injection locking inside the chip and electrical injection locking at the RF signal 7th sub-harmonic. Tu.2.D.4 • 12:00 Tu.2.E.5 • 12:00 Tu.2.F.4 • 12:00 Study of Inter-Modal Four Wave Mixing in Two Few-Mode Narrow Linewidth Operation (<10 kHz) in Self-injection- Dispersion-Flattened Composite Highly Nonlinear Fibre Fibres with Different Phase Matching Properties locked Tunable DFB Laser Array (SIL-TLA) Integrated with Optimised for Broadband Pulsed Four-Wave Mixing Francesca Parmigiani, Yongmin Jung (Optoelectronics Research Optical Feedback Planar Lightwave Circuit (PLC) Mads Lillieholm, Michael Galili and Leif Oxenløwe (Technical Centre, University of Southampton, Southampton, UK); Søren M. Hiroyuki Ishii, Naoki Fujiwara and Kei Watanabe (NTT Corporation, University of Denmark, DK) M. Friis (Technical University of Denmark, DK); Qiongyue Kang JP); Shigeru Kanazawa (NTT Photonics Laboratories, NTT We present a segmented composite HNLF optimised for miti- and Ioannis Begleris (Optoelectronics Research Centre, University Corporation, JP); Mikitaka Itoh, Hirokazu Takenouchi and Yutaka gation of dispersion-fluctuation impairments for broadband pulsed of Southampton, Southampton, UK); Peter Horak and Periklis Miyamoto (NTT Network Innovation Laboratories, JP) four-wave mixing. The HNLF-segmentation allows for pulsed Petropoulos (University of Southampton, UK); Karsten Rottwitt A novel self-injection-locked tunable DFB laser array (SIL-TLA) FWM-processing of a 13-nm wide input WDM-signal with -4.6-dB (Technical University of Denmark, DK); David J Richardson (Uni- integrated with an optical feedback planar lightwave circuit (PLC) conversion efficiency versity of Southampton, UK) is proposed. The fabricated device operates with a stable single We experimentally study inter-modal four-wave mixing (FWM) mode and a narrow linewidth of <10 kHz over the full C-band. in few-mode fibres with different phase matching properties. The possibility of transmitting two spatial modes without inter-modal FWM cross-talk in the C-band is presented. Tu.2.E.6 • 12:15 Tu.2.F.5 • 12:15 Mitigation of Mode Partition Noise in Quantum-Dash Fabry- Mode-Selective Fiber Laser Using a Photonic Lantern Perot Mode-Locked Lasers using Manchester Encoding Ning Wang (University of Central Florida, USA); Jose Anto- Mohamed Essghair Chaibi (University of Rennes 1, FR); Laurent nio-Lopez, Juan Alvarado-Zacarias and Zeinab Sanjabi Eznaveh Bramerie and Sebastien Lobo (ENSSAT / Université de Rennes 1, (CREOL, USA); He Wen (Tsinghua University, PRC); Pierre FR); Christophe Peucheret (University of Rennes 1, FR) Sillard (Prysmian, FR); Sergio Leon-Saval (University of Sydney The use of Manchester encoding with balanced detection is & Sydney Astrophotonic Instrumentation Laboratory (SAIL), AU); proposed in order to overcome the mode partition noise (MPN) Axel Schulzgen (University of Central Florida, USA); Rodrigo limit of quantum-dash mode-locked lasers used as multi wave- Anezcua-Correa (CREOL, USA); Guifang Li (University of Central length sources. Successful MPN mitigation is demonstrated for a Florida, USA) 10-mode laser at 10Gbit/s We experimentally demonstrate a transverse mode-selective fiber laser using a photonic lantern. The output modes of laser are switchable among the 6 LP modes supported by the gain fiber. Their slope efficiency, optical spectra, and mode profiles are measured. 12:30 - 14:00 Lunch Break | Exhibition Hall | 14:00 - 16:00 Exhibition Only 37 Technical Programme Tuesday, September 20, 2016 • 16:00 - 17:30 Tu.3.A: Room 18+19 Tu.3.B: Room 17 Tu.3.C: Room 16 Modulators SC2 DSP for NonlinearitySC3 Mitigation Multicarier ModulationSC4 Chair: Andreas Umbach (Finisar, DE) Chair: John C Cartledge (Queen’s University, CA) Chair: Mario Martinelli (Politecnico di Milano, IT) Tu.3.A.1 • 16:00 Tu.3.B.1 • 16:00 Invited Tu.3.C.1 • 16:00 Multi-level Optical Signal Generation Using a Segmented- Prospects for Real-Time Compensation of Fiber 400 Gbit/s Real-Time All-Analogue FBMC/OFDM based on Electrode InP IQ-MZM with Integrated CMOS Binary Nonlinearities a Mode Locked Laser Drivers Michael Reimer, Maurice O’Sullivan, Qunbi Zhuge, Shahab Oveis Fernando Gutiérrez and Eamonn Martin (Dublin City University, Michael Vanhoecke (Ghent University, BE); Nikolaos Argyris Gharan, Andrzej Borowiec, Loren Berg and Priyanth Mehta (Ciena IR); Philip A Perry (University College Dublin, IR); Andrew Ellis (National Technical University of Athens, GR); Alessandro Aimone Corporation, CA) (Aston University, UK); Aravind Anthur (IIT Madras, India); Vivek (Fraunhofer HHI, DE); Stefanos Dris (National Technical University We estimate limits on capacity and reach improvements Panapakkam (CNRS Laboratory for Photonics and Nanostruc- of Athens, GR); Dimitrios Apostolopoulos (National Technical achievable through nonlinear compensation for realizable tures, FR); Quentin Gaimard (CNRS, FR); Kamel Merghem (CNRS University of Athens & Institute of Communication and Computer coherent transceivers over a range of network applications. Laboratory for Photonics and Nanostructures, FR); Francois Lel- Systems, GR); Koen Verheyen, Renato Vaernewyck (Ghent Uni- Methods for low-complexity electronic nonlinear compensation arge (Alcatel Thales III-V Lab, FR); Abderrahim Ramdane (CNRS/ versity, BE); Guy Torfs, Xin Yin, Erwin Bosman (Ghent University on regional long-haul and ultra-long-haul submarine applications LPN & Institut National des Télécommunications, FR); Liam Barry - IMEC, BE); Gerrit Fiol, Marko Gruner, Robert Klötzer (Fraunhofer are considered. (Dublin City University, IR) Institut für Nachrichtentechnik, Heinrich-Hertz-Institut, DE); Johan A real-time 20x21.6 Gbit/s WDM electro-optical transceiver is Bauwelinck (Ghent University - iMinds, BE); Hercules Avramopou- presented. Optical carriers were spaced by 37 GHz and each one los (National Technical University of Athens, GR) transmitted four orthogonally overlapping broadband subchan- We present a segmented-electrode InP IQ-MZM, capable of nels. Only analogue electronics were employed for the OFDM (de) multi-level optical signal generation (5-bit per I/Q arm) by employ- modulation and subcarrier synchronization. ing direct digital drive from integrated, low-power (1W) CMOS bi- nary drivers. Programmable, multi-level operation is demonstrated experimentally on one MZM of the device. Tu.3.A.2 • 16:15 Tu.3.C.2 • 16:15 Ultra-High Bandwidth InP IQ Modulator with 1.5 V Vπ Discrete Multi-tone Transmitter at Net Data Rate of 200 Yoshihiro Ogiso (NTT Device Innovation Center, NTT Corporation, Gbps Using a Digital-Preprocessed Analog-Multiplexed JP); Takashi Yamada, Josuke Ozaki and Yuta Ueda (NTT, JP); DAC Norihide Kashio (NTT Device Innovation Center, NTT Corporation, Hiroshi Yamazaki, Munehiko Nagatani, Shigeru Kanazawa, JP); Nobuhiro Kikuchi, Eiichi Yamada (NTT Corporation, JP); Hideyuki Nosaka, Toshikazu Hashimoto and Fukutaro Hamaoka Hiroyasu Mawatari and Hiromasa Tanobe (NTT, JP); Shigeru (NTT Corporation, JP); Yutaka Miyamoto (NTT Network Innovation Kanazawa (NTT Photonics Laboratories, NTT Corporation, JP); Laboratories, JP) Hiroshi Yamazaki (NTT Corporation, JP); Yoshitaka Ohiso (NTT We demonstrated 214-Gbps/λ single-polarization discrete Photonics Laboratories, NTT Corporation, JP); Takuro Fujii, Mit- multi-tone optical transmission using a digital-preprocessed an- suteru Ishikawa and Masaki Kohtoku (NTT Corporation, JP) alog-multiplexed DAC based on two CMOS sub-DACs. Diversity We propose a new high-bandwidth (> 67 GHz) and low-Vπ (< synthesis utilizing image signal was introduced to enhance the 1.5 V) InP-based IQ modulator for more flexible modulation for- performance. A bit error rate below 3.8x10-3 was obtained. mats, and demonstrate the first up to 120-Gbaud IQ modulations without optical pre-equalization. Tu.3.A.3 • 16:30 Invited Tu.3.B.2 • 16:30 Tu.3.C.3 • 16:30 High-Speed Silicon-Organic Hybrid (SOH) Modulators Equalization-Enhanced Phase Noise in Nonlinear Inverse Real-Time Hardware Demonstration of 180 Gbps DFT-S Stefan Wolf, Wladislaw Hartmann, Matthias Lauermann, Heiner Synthesis Transmissions OFDM Receiver Based on Digital Sub-banding Zwickel, Yasar Kutuvantavida, Clemens Kieninger, Wolfgang Son Le and Ian Phillips (Aston University, UK); Jaroslaw Prilepsky, Alex Tolmachev, Maxim Meltsin, Rolf Hilgendorf and Mordechay Freude, Christian Koos (Karlsruhe Institute of Technology (KIT), DE) Morteza Kamalian, Kopae (Aston University & Aston Institute of Orbah (Technion - Israel Institute of Technology, IL); Yitzhak Birk We report on recent progress in high-speed SOH modulators. Photonic Technologies, UK); Andrew Ellis and Paul Harper (Aston (Technion, IL); Shalva Ben Ezra (Finisar, IL); Moshe Nazarathy We demonstrate generation of 100 Gbit/s on-off-keying (OOK) University, UK); Sergei K. Turitsyn (Aston University & Photonics (Technion, Israel Institute of Technology, IL) and 252 Gbit/s 16QAM signals, as well as amplifier-less, DAC- Research Group, UK) In just 3 FPGAs we realize fastest (180 Gbps) real-time less 16QAM signaling at peak-to-peak voltages 0.4 Vpp. Thermal We experimentally investigate, for the first time, the perfor- filter-bank based DFT-S CO-OFDM 16-QAM 25 GHz Rx, at record stability at 80°C was shown. mance penalty due to equalization-enhanced phase noise in 1.06 samples/symbol (7.3 b/Hz), demonstrating dual polarization nonlinear inverse synthesis transmissions with QPSK and 16QAM SMF transmission. Extrapolated ASIC would save <50% power. OFDM modulation formats. Tu.3.B.3 • 16:45 Tu.3.C.4 • 16:45 Blind Adaptive XPM Model Based Digital Backpropagation 56 Gb/s DMT Transmission with VCSELs in 1.5 um for Subcarrier-Multiplexing Systems Wavelength Range over up to 12 km for DWDM Intra-Data Fangyuan Zhang (McGill University, CA); Qunbi Zhuge (Ciena Center Connects Corporation, CA); Meng Qiu, Mathieu Chagnon and David Plant Annika Dochhan (ADVA Optical Networking SE, DE); Nicklas (McGill University, CA) Eiselt (Technical University of Denmark, DK); Robert Hohenleitner We propose a low complexity blind adaptive digital back- (Vertilas GmbH, DE); Helmut Griesser (ADVA Optical Networking propagation (DBP) scheme for subcarrier multiplexing (SCM) SE, DE); Michael Eiselt (ADVA, DE); Markus Ortsiefer (VERTILAS systems and experimentally demonstrate its fast convergence to GmbH, c/o GATE Garching, DE); Christian Neumeyr (VERTILAS, the optimal performance without any prior knowledge of the link GmbH, DE); Juan Jose Vegas Olmos (Technical University of parameters. Denmark, DK); Idelfonso Tafur Monroy (Technical University of Denmark, Denmark & ITMO University, RU); Jörg-Peter Elbers (ADVA AG Optical Networking, DE) We demonstrate up to 12 km, 56 Gb/s DMT transmission using high-speed VCSELs in the 1.5 um wavelength range for future 400Gb/s intra-data center connects, enabled by vestigial sideband filtering of the transmit signal. Tu.3.A.4 • 17:00 Tu.3.B.4 • 17:00 Record-high Modulation-efficiency Depletion-type Si-based Demonstration of Coherent Transmission Reach Tripling by Optical Modulator with In-situ B Doped Strained SiGe Layer Frequency-Referenced Nonlinearity Pre-compensation in on Si Waveguide for 1.3 um Wavelength EDFA-only SMF Link JJunichi Fujikata, Masataka Noguchi (Photonics Electronics Tech- Eduardo Temprana, Evgeny Myslivets, Vahid Ataie, Bill Ping Piu nology Research Association, JP); Jaehoon Han (The University of Kuo and Nikola Alic (University of California San Diego, USA); Tokyo, JP); Shigeki Takahashi (Photonics Electronics Technology Vijay Vusirikala and Vinayak Dangui (Google Inc, USA); Stojan Research Association, JP); Mitsuru Takenaka (The University of Radic (University of California, San Diego, USA) Tokyo, JP); Takahiro Nakamura (Photonics Electronics Technology A 200% reach extension in a coherent WDM link is demonstrat- Research Association, JP) ed for the first time by relying on mutually referenced frequency We develop depletion-type Si optical modulator with strained carriers. The reach tripling was achieved by transmitter-side SiGe on lateral Si pn junction. Owing to in-situ B doping for SiGe, nonlinear impairment cancellation. we achieve high modulation efficiency of 0.6-0.67 Vcm at 1.3 um wavelength with clear eye opeing at 28 Gbps. Tu.3.A.5 • 17:15 Tu.3.B.5 • 17:15 Characterization and Digital Pre-compensation of Elec- Polarization Effects in Nonlinearity Compensated Links tro-optic Crosstalk in Silicon Photonics I/Q Modulators Ivan Fernandez de Jauregui Ruiz, Amirhossein Ghazisaeidi, Elie Xi Chen, Po Dong, Sethumadhavan Chandrasekhar, Kwang- Awwad, Patrice Tran and Gabriel Charlet (Nokia Bell Labs, FR) woong Kim, Borui Li, Haoshuo Chen, Andrew Adamiecki, Alan We experimentally assess the impact of PDL and PMD on Gnauck and Peter Winzer (Nokia Bell Labs, USA) the performance of nonlinear compensation algorithms in Electro-optic crosstalk in Silicon Photonics I/Q modulators dispersion unmanaged links. We show that perturbative nonlinear is characterized and up to -19 dB crosstalk is found. Digital compensation is more robust to PDL, but more sensitive to PMD pre-compensation is performed which shows up to 3.7 dB Q2 compared to filtered digital-backpropagation. factor improvement or 64-QAM signals. 38 Technical Programme Tuesday, September 20, 2016 • 16:00 - 17:30 Tu.3.D: Room 15 Tu.3.E: Room 110 Tu.3.F: Room 112 Elastic Optical NetworksSC6 III Nonlinear and QuantumSC5 Techniques Advanced ModulationSC7 for Access Chair: Piero Castoldi (Scuola Superiore Chair: Magnus Karlsson (Chalmers University of Chair: Dirk Breuer (Deutsche Telekom T-Labs, Sant’Anna, IT) Technology & Photonics Laboratory, SE) DE) Tu.3.D.1 • 16:00 Invited Tu.3.E.1 • 16:00 Tu.3.F.1 • 16:00 Adaptive and Efficient Multilayer Elastic Optical Network Design of 2-Soliton Spectral Phase Modulated Pulses Over Transmission of 100-Gb/s DSB-DMT over 80-km SMF Using Planning Lumped Amplified Link 10-G class TTA and Direct-Detection Takafumi Tanaka, Tetsuro Inui, Akihiro Kadohata and Akira Hirano Vahid Aref, Henning Buelow (Nokia Bell Labs, DE) Jie Zhou, Liang Zhang and Tianjian Zuo (Huawei, PRC); Qiang (NTT, JP); Wataru Imajuku (Kindai University, JP) Over a lumped amplified link, we explain numerically how to Zhang (Huawei Technologies Duesseldorf GmbH, DE); Sen We overview our current works on the heuristic IP-over-elastic design solitonic pulses keeping the same breathing period. We Zhang, Enbo Zhou and Gordon Ning Liu (Huawei Technologies optical network (EON) planning algorithms including modula- demonstrate experimentally the transmission of 2-Solitonic pulses Co. Ltd., PRC) tion-aware virtual topology planning in the planning phase and with QPSK spectral amplitude modulation over 1600 km with a We experimentally demonstrate 100-Gb/s DSB-DMT transmis- multiperiod multilayer network planning which adapts to dynamic low error rate. sion over 80-km SMF using 10-GHz TTA and Direct-Detection traffic conditions in the operational phase. technique. Maximum capacities up to 125 Gb/s, 106 Gb/s and 103 Gb/s are achieved with BER at 4.5×10-3 for BTB, 40-km and 80-km SMF transmissions, respectively. Tu.3.E.2 • 16:15 Tu.3.F.2 • 16:15 Transmission of Waveforms Determined by 7 Eigenvalues 25Gb/s PAM4 Adaptive Receiver Equalisation Require- with PSK-Modulated Spectral Amplitudes ments for Burst-Mode Transmission Systems Henning Buelow, Vahid Aref, Wilfried Idler (Nokia Bell Labs, DE) Marco Dalla Santa (Tyndall National Institute, University College 2-ns waveforms with 7 eigenvalues and their QPSK-modulated Cork, IR); Cleitus Antony (Tyndall National Institute, IR); Giuseppe spectral amplitudes were optimized by taking constraints of link, Talli (Tyndall National Institute & Tyndall National Institute, IR); Paul transmitter, and receiver into account. In experiment these signals Townsend (Tyndall National Institute, IR) were transmitted with a BER of 3.2E-3 over 1440-km of NZ-DSF Requirements for burst-mode equalisation in a 25Gb/s PAM4 fiber spans. system for passive optical network upstream traffic are analysed for different linear equaliser solutions, with transmission over 40km of fibre. The impact of chromatic dispersion, transmitter bandwidth restriction and non-linearities is considered. Tu.3.D.2 • 16:30 Tu.3.E.3 • 16:30 Tu.3.F.3 • 16:30 Broker-based Cooperative Game in Multi-Domain SD- 34.6 Tbit/s WDM Transmission Using Soliton Kerr Frequen- Demonstration and Analysis on PAM-4/8, DB-PAM-2/4 and EONs: Nash Bargaining for Agreement on Market-Share cy Combs as Optical Source and Local Oscillator DMT Formatted TDM-PON with 25Gbps, 40Gbps, 50Gbps Partition Pablo Marin, Juned N Kemal, Philipp Trocha and Stefan Wolf Capacity per Lane using Economical 10Gbps Transceivers Lu Sun (University of Science and Technology of China, PRC); (Karlsruhe Institute of Technology, DE); Arne Kordts, Karpov Chenhui Ye, Xiaofeng Hu, Kaibin Zhang (Alcatel-Lucent Bell Labs, Xiaoliang Chen (University of California, Davis & University of Sci- Maxim, Martin Pfeiffer and Victor Brasch (Ecole Polytechnique PRC) ence and Technology of China, USA); Shilin Zhu, Zuqing Zhu (Uni- Federale de Lausanne, CH); Wolfgang Freude (Karlsruhe Institute We demonstrate 25Gbps/40Gbps/50Gbps TDM-PONs using versity of Science and Technology of China, PRC); Alberto Castro of Technology (KIT), DE); Tobias Kippenberg (Ecole Polytechnique PAM-2/4/8, duo-binary PAM-2/4, and DMT formats on economi- Casales, S. J. Ben Yoo (University of California, Davis, USA) Federale de Lausanne, CH); Christian Koos (Karlsruhe Institute of cal 10Gbps transceivers. Based on the performance/cost analysis We model the cross-domain lightpath provisioning in multi-bro- Technology (KIT), DE) and comparison, we also introduce a general guidance on format ker based multi-domain SD-EONs as a cooperative game, We demonstrate massively parallel WDM transmission using choice for 25Gbps+ PONs. propose to obtain Pareto-efficient market-share partition for the Soliton Kerr frequency combs both as multi-wavelength source brokers with Nash bargaining, and design the system framework at the transmitter and as multi-wavelength local oscillator at the to realize the proposal. receiver. The viability of the concept is proven by transmitting 34.6Tbit/s over 75km. Tu.3.D.3 • 16:45 Tu.3.E.4 • 16:45 Tu.3.F.4 • 16:45 Time and Spectrum Aggregation in Metropolitan Network Heterodyne Coherent Scheme for Long Distance Quantum Demonstration of Upstream Flexible 2-/4-PAM Formats for for Heterogeneous Traffic Profile Key Distribution Using a Real Local Oscillator Practical PON Deployments Ion Popescu (KDDI R&D Laboratories, Inc., JP); Ahmed Triki (Insi- Sebastian Kleis, Christian Schaeffer (Helmut-Schmidt-University, Robbert van der Linden (Eindhoven University of Technology & titut mines Télécom, Télécom Bretagne, FR); Xiaoyuan Cao (KDDI DE) Genexis BV., NL); Xin Yin (Ghent University - IMEC, BE); Nguy- R&D Laboratories, Inc., JP); Annie Gravey (Institut Mines Telecom We present a novel heterodyne coherent scheme for secure en-Cac Tran (Genexis B.V., Eindhoven, NL); Johan Bauwelinck - Telecom Bretagne & UMR CNRS 6074 IRISA, FR); Takehiro Tsu- key distribution. In contrast to most other QKD schemes it is (Ghent University - iMinds, BE); Eduward Tangdiongga (Eindhoven ritani (KDDI R&D Laboratories, Inc., JP); Philippe Gravey (Télécom very practical because it works with a real free running LO at the University of Technology, NL); Ton Koonen (COBRA, Eindhoven Bretagne, FR); Noboru Yoshikane (KDDI R&D Laboratories, JP); receiver side. University of Technology, NL) Michel Morvan (Telecom Bretagne, FR) Adaptive 2-/4-PAM modulation in PONs leverages the distribu- We propose a new optical transport solution, TSAN, based tion of optical path losses to increase capacity. Upstream 2-/4- on variable bit rate packet transmission and passive switching. PAM burst transmission is demonstrated with a selectable fixed The expected CAPEX and OPEX savings in TSAN are assessed 4-tap FIR-filter, improving the performance of each gain mode of using scenarios based on current and next generation network the burst-mode receiver. architectures. Tu.3.D.4 • 17:00 Tu.3.F.5 • 17:00 Invited Comparing Networking Benefits of Digital Back-Propaga- Recent Progress on 25G EPON and beyond tion vs. Lightpath Regeneration Vincent Houtsma, Dora van Veen (Nokia Bell Labs, USA); Mattia Cantono, Roberto Gaudino, Pierluigi Poggiolini, Vittorio Ed Harstead (Alcatel-Lucent, BE) Curri (Politecnico di Torino, IT) An overview of recent developments in next generation high We compare the networking benefits of Ideal-Single-Channel speed PON and the progress being made in IEEE P802.3ca Digital-Back-Propagation (ISC- DBP) vs. Lightpath Regeneration working group on 25G EPON and beyond is given. as Quality-of-Transmission enhancing techniques. By analyzing three different topologies, we show that ISC-DBP has the poten- tial to substantially reduce the number of required regenerators in all-optical networks. Tu.3.D.5 • 17:15 Latency-aware Multi-layer Network Optimization in IP-over- WDM Core Networks C´ iril Rožic´, I Tomkos and Dimitrios Klonidis (Athens Information Technology, GR) We study the handling of latency-sensitive traffic in a IP/optical core network. We show the superiority of our proposed laten- cy-aware multi-layer network optimization approach, and evaluate the impact of propagation and electronic processing delays. 39 Technical Programme Wednesday, September 21, 2016 • 09:00 - 10:30 W.1.A: Room 18+19 W.1.B: Room 17 W.1.C: Room 16 Advanced SiliconSC4 Photonics Fiber Sensing andSC1 Measurement Signal Shaping SC3 Chair: Richard Pitwon (Seagate, UK) Chair: Patrice Mégret (University of Mons Chair: Andrew Ellis (Aston University, UK) (UMONS) & Faculté Polytechnique, BE) W.1.A.1 • 09:00 Tutorial W.1.B.1 • 09:00 W.1.C.1 • 09:00 Invited Advanced Silicon Photonics for Post-Moore Era High Dynamic Range Linear Optical Sampling with Coher- Probabilistically Shaped QAM for Independent Reach, Koji Yamada (National Institute of Advanced Industrial Science ence Recovery for Measuring Fibre Impulse Response Spectral Efficiency and Bit-rate Adaptation and Technology, JP) Fumihiko Ito and Naoto Kono (Shimane University, JP); Daisuke Fred Buchali, Wilfried Idler and Laurent Schmalen (Nokia Bell Telecom/Datacom traffic is growing explosively as device tech- Iida and Tetsuya Manabe (NTT Corporation, JP) Labs, DE); Georg Böcherer, Patrick Schulte and Fabian Steiner nology development guided by Moore’s law nears it end. Although Impulse responses of 2-mode fibres are measured by a method (Technical University of Munich, DE) silicon photonics technology offers immediate solutions, much based on linear optical sampling with newly developed amplitude In this paper we review probabilistically shaped constellations further evolution is needed in order to cope with the continual averaging technique with phase noise compensation. The inter- and experimentally investigate probabilistically shaped QAM growth expected in the future. modal coupling is observed with 10-ps time resolution and 80 dB systems operated at both high bit-rate and high reach requiring dynamic range. high baudrate transmission. We demonstrate up to 29% reach increase by probabilistic shaping. W.1.B.2 • 09:15 Measurement of Temperature-Induced Polarization Drift and Correlation in a 7-Core Fiber Mikael Mazur (Chalmers University of Technology, SE); Thierry Taunay (OFS Laboratories, USA); Tommy Geisler and Lars Grüner-Nielsen (OFS Fitel Denmark, DK); Magnus Karlsson (Chalmers University of Technology & Photonics Laboratory, SE); Peter A Andrekson (Chalmers University of Technology, SE) We study the correlation in polarization drift between different cores of a 7-core fiber subjected to temperature fluctuations. We present a method to quantify these changes and show that the drift in different cores is correlated to 98%. W.1.B.3 • 09:30 Invited W.1.C.2 • 09:30 Multicore optical fiber grating arrays for sensing applica- Low-Complexity Shaping for Enhanced Nonlinearity tions Tolerance Paul Westbrook, Tristan Kremp, Kenneth Feder, Thierry Taunay , Junho Cho, Sethumadhavan Chandrasekhar, Ronen Dar, Peter Eric Monberg, Hongchao Wu, Debra Simoff and Roy Ortiz (OFS Winzer (Nokia Bell Labs, USA) Labs, USA) We present a novel low-complexity signal shaping method We review recent advances in optical fiber sensor array which offers significant linear and nonlinear gains. The shaping technology aimed at next generation applications such as shape gain exceeds the coding gain, and the data rate can be easily sensing and enhanced scatter enabled distributed sensing. adapted by shaping. W.1.C.3 • 09:45 Implicit Constellation Shaping in Regenerative Optical Networks Laurent Schmalen, Fred Buchali (Nokia Bell Labs, DE) In this paper, we consider optical coherent networks with regenerative nodes. We show that by properly optimizing the re- generators, we can improve the network’s spectral efficiency with minor receiver modifications. This method automatically includes a fall-back to lower-order modulation formats. W.1.A.2 • 10:00 Invited W.1.C.4 • 10:00 High-Speed Photonics for Side-by-Side Integration with Four-Dimensional Trellis Coded Modulation for Flexible Billion Transistor Circuits in Unmodified CMOS Processes Optical Transponders Luca Alloatti (ETH Zurich, CH) Saleem Alreesh (Technische Universität Berlin, DE); Carsten Monolithic integration of photonics and electronics is key to Schmidt-Langhorst, Robert Emmerich, Pablo Wilke Berenguer, chip-to-chip optical interconnects. However, high-yield CMOS Colja Schubert and Johannes K. Fischer (Fraunhofer Heinrich nodes impose strict constraints on materials and design rules. We Hertz Institute, DE) review high-responsivity photodiodes and low-voltage modulators We experimentally demonstrate 4-D TCM based on PDM- for 12.5Gbaud links in an unmodified 45nm CMOS node. 16QAM, PDM-32QAM and PDM-64QAM formats . A multi-rate optical transponder is enabled by only a single encoder/decoder structure. The scheme is resilient to cycle-slip events due to its 90° phase rotation invariant property. W.1.C.5 • 10:15 Temporal Probabilistic Constellation Shaping for WDM Optical Communication Systems Metodi Yankov, Soren Forchhammer (Technical University of Denmark, DK) Finite state machine sources transmitting QPSK are studied as input to WDM optical fiber systems with ideal distributed Raman amplification. The probabilities of successive constellation sym- bols are shaped for nonlinear transmission and gains of around 500km (5-10%) are demonstrated. 10:30 - 11:00 Coffee Break | Exhibition Hall | 40 Technical Programme Wednesday, September 21, 2016 • 09:00 - 10:30 W.1.D: Room 15 W.1.E: Room 110 W.1.F: Room 112 Nonlinear DistortionsSC5 Photonics-BasedSC7 Wireless Access SDN and NFV SC6 Chair: Yann Frignac (Institut Mines-Télécom, FR) Chair: Guillermo Carpintero (Universidad Carlos III Chair: Achim Autenrieth (ADVA Optical Networ- de Madrid, ES) king, DE) W.1.D.1 • 09:00 W.1.E.1 • 09:00 Upgraded W.1.F.1 • 09:00 Experimental Study of Nonlinear Phase Noise and its Demonstration of a Real-Time FPGA-Based CPRI-Com- Multi-tenant 5G Network Slicing Architecture with Dynamic Impact on WDM Systems with DP-256QAM patible Efficient Mobile Fronthaul Transceiver Supporting Deployment of Virtualized Tenant Management and Or- Metodi Yankov, Francesco Da Ros, Edson Porto da Silva (Technical 53 Gb/s CPRI-Equivalent Data Rate Using 2.5-GHz-Class chestration (MANO) Instances University of Denmark, DK); Tobias Fehenberger (Technical Univer- Optics Arturo Mayoral, Raul Muñoz, Ricard Vilalta, Ramon Casellas and sity of Munich (TUM), DE); Luca Barletta (Politecnico di Milano, IT); Huaiyu Zeng and Xiang Liu (Futurewei Technologies, USA); Ricardo Martinez (Centre Tecnologic de Telecomunicacions de Darko Zibar (DTU Fotonik, depertment of Photonic Engineering, Sharief Megeed (Futurewei Technologies, Huawei R&D USA, Catalunya (CTTC), ES) Technical University of Denmark, DK); Leif Oxenløwe, Michael Galili, USA); Naresh Chand (Futurewei Technologies, USA); Frank We present and experimentally assess a multi-tenant network Soren Forchhammer (Technical University of Denmark, DK) Effenberger (Huawei Technologies, USA) slicing architecture that dynamically provides 5G slices (virtual A probabilistic method for mitigating the phase noise compo- We experimentally demonstrate a real-time CPRI-compatible network and cloud resources, and virtualized network functions) nent of the non-linear interference in WDM systems with Raman mobile fronthaul transceiver using 5-GSa/s DAC/ADC, Xilinx Virtex and SDN/NFV control instances for a full control of allocated amplification is experimentally demonstrated. The achieved 7 FPGA, and 2.5-GHz-class DML and APD. A CPRI-equivalent resources as if they were real. gains increase with distance and are comparable to the gains of aggregated throughput of 53 Gb/s is achieved with an one-way single-channel digital back-propagation. processing latency as low as 1.8 ms. W.1.D.2 • 09:15 W.1.F.2 • 09:15 Impact of WDM Channel Correlations on Nonlinear Trans- First Experimental Demonstration of Secure NFV Orches- mission tration over an SDN-Controlled Optical Network with Time- Ronen Dar, Sethumadhavan Chandrasekhar, Alan Gnauck, Borui Shared Quantum Key Distribution Resources Li, Junho Cho, Ellsworth Burrows and Peter Winzer (Nokia Bell Alejandro Aguado, Emilio Hugues-Salas, Paul Anthony Haigh, Labs, USA) Jaume Marhuenda, Alasdair Price, Phil Sibson, Jake Kennard, We study the impact of channel correlations on the accu- Christopher Erven, John Rarity and Mark Thompson (University mulation of nonlinear interference noise in WDM transmission of Bristol, UK); Andrew Lord (British Telecom, UK); Reza Nejabati experiments. Theoretical predictions, split-step simulations and and Dimitra Simeonidou (University of Bristol, UK) experimental measurements indicate negligible impact for QPSK We demonstrate, for the first time, a secure optical network ar- transmission, but notably strong artifacts for high-order QAM chitecture that combines NFV orchestration and SDN control with formats. quantum key distribution (QKD) technology. A novel time-shared QKD network design is presented as a cost-effective solution for practical networks. W.1.D.3 • 09:30 W.1.E.2 • 09:30 W.1.F.3 • 09:30 Independence of the Impact of Inter-Channel Non-Linear Full-Duplex Mobile Backhaul Transportation based on On-Demand Allocation of Control Plane Functions via SDN/ Effects on Modulation Format and System Implications Fiber-Wireless Integrated FSO and MMW Hybrid Links with NFV for Monitoring-enabled Flexi-grid Optical Networks Antonino Nespola and Luca Bertignono (Istituto Superiore Mario Adaptive Signal Processing to Combat Diverse Weather with Programmable BVTs Boella, IT); Gabriella Bosco, Andrea Carena and Pierluigi Poggi- Conditions Ramon Casellas, Josep M. Fabrega, Raul Muñoz, Laia Nadal olini (Politecnico di Torino, IT); Fabrizio Forghieri (Cisco Photonics Junwen Zhang, Gk Chang, Jing Wang and Mu Xu (Georgia Reixats, Ricard Vilalta, Michela Svaluto Moreolo and Ricardo Italy srl, IT) Institute of Technology, USA); Jianjun Yu (Fudan Univerisity, PRC); Martinez (Centre Tecnològic de Telecomunicacions de Catalunya We show by simulation that the impact of inter-channel non-lin- Lin Cheng (Georgia Institute of Technology, USA) (CTTC), ES) ear effects is independent of modulation format in long-haul We propose and experimentally demonstrate a novel full-duplex A modular SDN architecture for flexi-grid networks, relying on systems, once long-correlated non-linear phase-noise has been mobile backhaul network based on fiber-wireless integrated the NFV framework, allows on-demand allocation and composi- removed. We back-up the finding experimentally and investigate MMW and FSO hybrid links using adaptive diversity combining tion of virtualized control plane functions into instances, in a cost the system implications. technique. Performance improvements and enhanced reliability effective way. We demonstrate its use in the adaptive control of are validated under diverse weather conditions at 11.25-/8.4- BVTs Gb/s for down-/up-links. W.1.D.4 • 09:45 W.1.E.3 • 09:45 W.1.F.4 • 09:45 Experimental Analysis of Correlations in the Nonlinear PIC-enabled Dynamic Bidirectional Indoor Network Experimental Assessment of VDC Provisioning in SDN/ Phase Noise in Optical Fiber Systems Employing Optical Wireless and Millimeter-wave Radio OpenStack-based DC infrastructures with optical DCN Tobias Fehenberger (Technical University of Munich (TUM), DE); Techniques Albert Pagès, Fernando Agraz, Rafael Montero (Universitat Mikael Mazur (Chalmers University of Technology, SE); Tobias Ketamaw Mekonnen, Chin Wan Oh, Zizheng Cao and Amir Politècnica de Catalunya (UPC), ES); Giada Landi and Roberto A. Eriksson (Nokia Bell Labs, DE); Magnus Karlsson (Chalmers Masood Khalid (Eindhoven University of Technology, NL); Nicola Monno (Nextworks, IT); José I Aznar (I2cat, ES); Albert Viñés University of Technology & Photonics Laboratory, SE); Norbert Calabretta (COBRA Research Institute, NL); Eduward Tang- (Fundació i2CAT, Internet i Innovació Digital a Catalunya, ES); Hanik (Munich University of Technology, DE) diongga (Eindhoven University of Technology, NL); Ton Koonen Chris Jackson and Dimitra Simeonidou (University of Bristol, UK); A dual-link self-homodyne receiver is used to measure the (COBRA, Eindhoven University of Technology, NL) Salvatore Spadaro (Universitat Politecnica de Catalunya (UPC), ES) phase correlations introduced by the interplay of dispersion and We propose a hybrid radio-optical wireless system using a VDC provisioning requires the coordinated configuration of fiber nonlinearities. The dependence of the memory on the WDM photonic integrated chip to realize highly reconfigurable indoor several types of resources. We present a DC architecture for setup, signal power and transmission distance is experimentally networks which provide ultimate capacities per user. Bidirectional the orchestration and provisioning of VDC instances on top of demonstrated. transmission rates of >35Gb/s are demonstrated using dis- DCs with optical DCN and experimentally validate the proposed crete-multitone modulation. architecture. W.1.D.5 • 10:00 Invited W.1.E.4 • 10:00 W.1.F.5 • 10:00 Analytical and Semi-Analytical Models for Nonlinear Photonics-Aided over 100-Gbaud All-Band (D-, W- and Experimental Evaluation of YAMATO, a SDN Control Plane Transmission V-Band) Wireless Delivery for Joint and Fractional-Joint Switched SDM Optical Ronen Dar (Nokia Bell Labs, USA) Xinying Li (Fudan University, PRC); Jianjun Yu (ZTE (TX) Inc., USA); Networks We review recent advances in modeling nonlinear interference Jiangnan Xiao, Yuming Xu and Long Chen (Fudan University, Federico Pederzolli, Matteo Gerola and Andrea Zanardi (Cre- noise (NLIN) in WDM systems. We explore the time-domain PRC) ate-Net, IT); Xavier Forns and J. Ferran (W-Onesys, Barcelona, and frequency-domain representations of NLIN and discuss We experimentally demonstrate photonics-aided D-band ES); Domenico Siracusa (CREATE-NET, IT) techniques for evaluating its statistical properties and impact on (110GHz-170GHz) wireless mm-wave signal delivery with a record Managing (Fractional) Joint Switching will enable the deploy- system performance. baud rate of 46Gbaud and photonics-aided all-band (D-, W- and ment of cost-effective SDM networks. This paper describes a V-band) wireless mm-wave signal delivery with a record baud rate network model and the first control plane implementation handling of over 100Gbaud (400Gbps). these paradigms. We show, using an emulated testbed, that the system is responsive and scalable. W.1.E.5 • 10:15 W.1.F.6 • 10:15 80 Gbit/s 16-QAM Multicarrier THz Wireless Communica- Virtualized Routing and Frequency Allocation Functions in tion Link in the 400 GHz Band Elastic Optical Networks Shi Jia (Tianjin University, DK); Xianbin Yu (Zhejiang University, Quan Pham Van (Telecom Sudparis & Nokia Bell Labs, FR); PRC); Hao Hu (Technical University of Denmark, DK); Jinlong Yu Dominique G. Verchere (Nokia Bell Labs & France, FR); Selma (Tianjin University, PRC); Toshio Morioka (Technical University of Khebbache (Télécom SudParis, Institut Mines-Télécom, FR); Denmark, DK); Peter Uhd Jepsen (Denmark Technical University, Djamal Zeghlache (Institut Mines-Telecom, Telecom SudParis & DK); Leif Oxenløwe (Technical University of Denmark, DK) UMR 5157 CNRS - Samovar, FR); Patricia Layec and Arnaud We experimentally demonstrate a high-speed multicarrier THz Dupas (Nokia Bell-Labs, FR); Sebastien Bigo (Bell Labs, wireless communication system operating in the 400 GHz band. Alcatel-Lucent, FR) The use of spectrally efficient 16-QAM modulation and broadband Optical channels are configured according to changing data THz transceivers enable link data rates up to 80 Gbit/s. traffic demands through virtualized routing and frequency alloca- tion (VRFA) functions executed as SDN applications. Two algo- rithms are evaluated considering the trade-off between allocated DWDM frequency grid ranges and execution time. 10:30 - 11:00 Coffee Break | Exhibition Hall | 41 Technical Programme Wednesday, September 21, 2016 • 11:00 - 12:30 W.2.A: Room 18+19 W.2.B: Room 17 W.2.C: Room 16 Trends on PassiveSC7 Optical Network Multicore FibersSC1 Error CorrectionSC3 Chair: Philippe Chanclou (Orange Labs, FR) Chair: Kunimasa Saitoh (Hokkaido University, JP) Chair: Helmut Griesser (ADVA Optical Networking SE, DE) W.2.A.1 • 11:00 Tutorial W.2.B.1 • 11:00 W.2.C.1 • 11:00 Industrial Trends and Roadmap of Access 125 μm 5-core fibre with heterogeneous design suitable for Experimental Demonstration of Nonbinary LDPC Convolu- Frank Effenberger (Huawei Technologies, USA) migration from single-core system to multi-core system tional Codes for DP-64QAM/256QAM Optical access has grown in speed, from 50 Mb/s pi-PON to Tomohiro Gonda, Katsunori Imamura and Ryuichi Sugizaki (Furu- Toshiaki Koike-Akino (Mitsubishi Electric Research Laboratories 10 Gb/s XG-PON. Further capacity increases are envisioned to kawa Electric co., Ltd., JP); Yu Kawaguchi and Takehiro Tsuritani (MERL), USA); Kenya Sugihara (Mitsubishi Electric Corporation, employ multiple wavelengths and advanced line coding. This (KDDI R&D Laboratories, Inc., JP) JP); David Millar, Milutin Pajovic (Mitsubishi Electric Research paper reviews the current trends in access, and predicts a likely 125 μm 5-core fibre with heterogeneous core design suitable Laboratories (MERL), USA); Wataru Matsumoto (Mitsubishi roadmap. for the migration from single-core system to multi-core system Electric Corporation, JP); Alex Alvarado, Robert Maher, Domanic was designed and fabricated. This fibre has high space division Lavery and Milen Paskov (University College London, UK); multiplexing factor comparable to 19-core fibres. Keisuke Kojima and Kieran Parsons (Mitsubishi Electric Research Laboratories, USA); Benn C Thomsen (University College London, UK); Seb J Savory (University of Cambridge, UK); Polina Bayvel (UCL, UK) We show the great potential of nonbinary LDPC convolutional codes (NB-LDPC-CC) with low-latency windowed decoding. It is experimentally demonstrated that NB-LDPC-CC can offer a performance improvement of up to 5 dB compared with binary coding. W.2.B.2 • 11:15 W.2.C.2 • 11:15 Crosstalk-Managed Heterogeneous Single-Mode 32-Core Optimal Layered Scheduling for Hardware-Efficient Win- Fibre dowed Decoding of LDPC Convolutional Codes Yusuke Sasaki, Ryohei Fukumoto, Katsuhiro Takenaga and Toshiaki Koike-Akino (Mitsubishi Electric Research Laboratories Kazuhiko Aikawa (Fujikura Ltd., JP); Kunimasa Saitoh (Hokkaido (MERL), USA); Stark Draper (University of Toronto, CA); Ye Wang University, JP); Toshio Morioka (Technical University of Denmark, (Mitsubishi Electric Research Laboratories, USA); Kenya Sugihara DK); Yutaka Miyamoto (NTT Network Innovation Laboratories, JP) and Wataru Matsumoto (Mitsubishi Electric Corporation, JP); Da- A heterogeneous single-mode 32-core fibre with a cladding vid Millar and Kieran Parsons, Valeria Arlunno and Keisuke Kojima diameter of 243 μm is designed and fabricated. The highest (Mitsubishi Electric Research Laboratories, USA) core count in single-mode multi-core fibres and low worst-case We propose an optimal design method for layered scheduling crosstalk of less than −24 dB/1000 km in C-band are achieved in low-power windowed decoding of LDPC convolutional codes. simultaneously. Our optimal scheduling achieves up to a 70% complexity reduction and a 1 dB gain over conventional scheduling for limited decoding iterations. W.2.B.3 • 11:30 Invited W.2.C.3 • 11:30 Invited Coupled Few-mode Multi-core Fibre for Ultra-high Spatial Scalable SD-FEC for Efficient Next-generation Optical Density Space Division Multiplexing Networks Taiji Sakamoto, Takayoshi Mori, Masaki Wada, Takashi Yamamoto, Kenya Sugihara, Keisuke Dohi, Kazuo Kubo, Takashi Sugihara, Fumihiko Yamamoto, Kazuhide Nakajima (NTT Corporation, JP) Wataru Matsumoto, Kenji Ishii (Mitsubishi Electric Corporation, JP) We review our recent work on coupled few-mode multi- An SD-FEC has an even potential of a further optimization of a core fibre and describe a super-mode-based MCF design for spectral efficiency and a power consumption in optical networks. suppressing MIMO processing complexity. We also report 125 A scalable SD-FEC is the key idea that improves efficiency of um-cladding strongly coupled 3-mode 7-core fibre for reducing next-generation optical networks. inter-core non-uniformity induced differential mode delay. W.2.A.2 • 12:00 Invited W.2.B.4 • 12:00 W.2.C.4 • 12:00 Cost Effective 25 Gbps Optical Access Technology Compact 32-Core Multicore Fibre Isolator for High-Density Improvement on FEC performance by Turbo Equalization Dora van Veen, Vincent Houtsma (Nokia Bell Labs, USA) Spatial Division Multiplexed Transmission for Super-Nyquist WDM systems Overview and discussion of cost effective 25 Gb/s TDM-PON Yongmin Jung (Optoelectronics Research Centre, University of Shuai Yuan and Koji Igarashi (Osaka University, JP); Takehiro based on 10G optical components using electrical duobinary Southampton, Southampton, UK); Shaif-ul Alam (University of Tsuritani; Itsuro Morita (KDDI R&D Laboratories, Inc., JP) signalling and electronic equalization methods is presented. Southampton, UK); Yusuke Sasaki (Fujikura Ltd., JP); David J vIn Super-Nyquist WDM systems, maximum likelihood decoder Richardson (University of Southampton, UK) for duobinary shaping degrades the post-FEC BER performance. We present a fully integrated 32-core multicore fibre isolator We experimentally confirm that degradation of post-FEC BER with low insertion loss (average loss <0.8dB, core-to-core varia- characteristics can be remarkably suppressed by introducing tion <2dB) and low inter-core crosstalk (<-40dB). turbo equalization. W.2.B.5 • 12:15 W.2.C.5 • 12:15 Effects of Core Count/Layout and Twisting Condition on Improved Soft-Decision Forward Error Correction via Spatial Mode Dispersion in Coupled Multi-Core Fibers Post-Processing of Mismatched Log-Likelihood Ratios Tetsuya Hayashi (Sumitomo Electric Industries, Ltd., JP); Haoshuo Alex Alvarado (University College London, UK); Leszek Szczecins- Chen and Nicolas K Fontaine (Nokia Bell Labs, USA); Takuji Na- ki (INRS-EMT, CA); Tobias Fehenberger (Technical University of gashima (Sumitomo Electric Industries, Ltd., JP); Roland Ryf and Munich (TUM), DE); Polina Bayvel and Milen Paskov (University Rene Essiambre (Nokia Bell Labs, USA); Toshiki Taru (Sumitomo College London, UK) Electric Industries, Ltd., JP) Correction of soft information based on achievable information We investigated the dependence of the spatial-mode rates for SD-FEC is discussed. Linear scaling of LLRs is shown to dispersion (SMD) of coupled-core fibers on core count/layout offer gains of up to 0.75 dB for a rate 0.8 LDPC code in a channel and twisting conditions. The results indicate the importance of dominated by phase noise. the core count/layout design optimization taking account of the twisting conditions. 12:30 - 14:00 Lunch Break 42 Technical Programme Wednesday, September 21, 2016 • 11:00 - 12:30 W.2.D: Room 15 W.2.E: Room 110 W.2.F: Room 112 Advanced ModulationSC5 Formats I Transmitters II SC2 Switching and RoutingSC4 Chair: Giancarlo Gavioli (Nokia, IT) Chair: Leo Spiekman (Aeon Corp., USA) Chair: Oded Raz (Eindhoven University of Tech- nology, NL) W.2.D.1 • 11:00 W.2.E.1 • 11:00 Invited W.2.F.1 • 11:00 Invited 5 and 7 bit/symbol 4D Modulation Formats Based on Quantum-dot lasers monolithically grown on silicon High radix all-optical switches for software-defined data- 2A8PSK substrates centre networks Keisuke Kojima (Mitsubishi Electric Research Laboratories, USA); Huiyun Liu (University College London & Torrington Place, UK) Nick Parsons (Polatis, UK); Rich Jensen (Polatis, USA); Adam Tsuyoshi Yoshida (Mitsubishi Electric Corporation, JP); Toshiaki Monolithically integrating III-V lasers on Si is the most promising Hughes (Polatis, UK) Koike-Akino, David Millar, Kieran Parsons and Valeria Arlunno solution to overcome the issue of lack of efficient light sources on We review use cases for optical circuit switching (OCS) in (Mitsubishi Electric Research Laboratories (MERL), USA) Si. We demonstrated the first practical silicon-based telecommu- datacentre networks, together with results for a 384x384 port We propose 5 and 7 bit/symbol 4D modulation formats based nications-wavelength quantum-dot laser with high output power dark fibre OCS with median loss of 1.5dB. Challenges of scaling on 2A8PSK, which outperform previously known modulation and long lifetime. SDN-enabled OCS fabrics to greater than 50,000 endpoints are formats for each spectral efficiency. Combined with the recently discussed. reported 6 bit/symbol 2A8PSK, the 2A8PSK family covers 5-7 bits without significant hardware modifications. W.2.D.2 • 11:15 Digital Subcarrier Multiplexing 4-D Set-Partitioning QAM Signals Xiang Meng (Huazhong University of Science and Technology, PRC); Qunbi Zhuge (Ciena Corporation, CA); Meng Qiu and Thang Hoang (McGill University, CA); Mohammad Sowailem (McGill University, Egypt); Xingyu Zhou (UESTC, PRC); Fangyuan Zhang (McGill University, CA); Ming Tang, Changjian Ke, Deming Liu and Songnian Fu (Huazhong University of Science and Tech- nology, PRC); David Plant (McGill University, CA) We experimentally investigate 4-D set-partitioning formats in digital subcarrier multiplexing systems. The proposed 4-D set-partitioning of signals across two subcarriers outperforms the conventional approach implemented across two polarizations in terms of both nonlinearity and optical filtering tolerance. W.2.D.3 • 11:30 W.2.E.2 • 11:30 W.2.F.2 • 11:30 96-GBaud Coded 8-Dimensional 16QAM Transmission over Polymer-based Integrated Tuneable laser with On-Chip Large-Scale Optical Circuit Switch for Intra-Datacenter 5,252 km Using Iterative Soft-Output Decoding Wavelength Locker Networking Using Silicon-Photonic Multicast Switch and Masanori Nakamura, Fukutaro Hamaoka, Asuka Matsushita, David De Felipe, Magnus Happach, Moritz Kleinert, Crispin Tunable Filter Kengo Horikoshi, Hiroshi Yamazaki and Munehiko Nagatani Zawadzki, Walter Brinker, Wolfgang Rehbein, Martin Moehrle and Koh Ueda, Yojiro Mori and Hiroshi Hasegawa (Nagoya University, (NTT Corporation, JP); Akihide Sano (NTT Network Innovation Norbert Keil (Fraunhofer Heinrich-Hertz-Institute, DE); Werner JP); Ken-Ichi Sato (School of Engineering - Nagoya University, Laboratories, JP); Akira Hirano (NTT, JP); Yutaka Miyamoto (NTT Hofmann (Technische Universität Berlin, DE); Martin Schell (Fraun- JP); Keijiro Suzuki, Hiroyuki Matsuura, Ken Tanizawa, Satoshi Network Innovation Laboratories, JP) hofer Institute for Telecommunications, Heinrich-Hertz-Institut, DE) Suda, Kazuhiro Ikeda, Shu Namiki and Hitoshi Kawashima We propose novel coded 8-dimensional 16QAM demonstrating A polymer-based integrated tuneable laser with on-chip (National Institute of Advanced Industrial Science and Technology, 576-Gbps transmission over 5,252km. At the same spectral wavelength locker is presented. The device incorporates a free- JP); Shigeru Nakamura, Shigeyuki Yanagimachi and Akio Tajima efficiency, 8D-16QAM using iterative soft output decoding can space-based 100-GHz etalon, and monitor planar photodiodes (NEC Corporation, JP) expand the transmission reach by 1,212km compared to conven- coupled by means of 45° mirrors. Wavelength stabilization with a We propose a novel optical circuit switch architecture for in- tional PDM-8QAM. resolution of ±4 GHz has been demonstrated. tra-datacenter networking. The key components, optical multicast switches and tunable filters are fabricated using silicon photonics. Proof-of-concept transmission experiments are performed using newly developed silicon-photonic devices. W.2.D.4 • 11:45 W.2.E.3 • 11:45 W.2.F.3 • 11:45 Folded Orthogonal Frequency Division Multiplexing for Wavelength Stabilized Silicon/III-V Hybrid Laser System Performance Assessment of a Monolithically Super-Channel Sub-Banding Argishti Melikyan, Guilhem de Valicourt, Po Dong, Nicolas K Integrated WDM Cross-Connect Switch for Optical Data Bill Corcoran, Chen Zhu, Arthur Lowery and Binhuang Song Fontaine, Kwangwoong Kim, Chia-Ming Chang and Young-Kai Centre Networks (Monash University, AU) Chen (Nokia Bell Labs, USA) Nicola Calabretta (COBRA Research Institute, NL); Wang Miao, Orthogonal, periodic-sinc-shaped sub-carrier spectra allow We demonstrate wavelength stabilized hybrid silicon/III-V laser. Kristif Prifti and Kevin Williams (Eindhoven University of Techno multi-carrier bands with the precise, rectangular frequency The on-chip silicon diode temperature sensor integrated with the logy, NL) definition of Nyquist-WDM. Experimental demonstration of these laser cavity allows sub‑10pm wavelength stabilization in tempera- We assess the system performance of a photonic integrated ‘folded’ OFDM bands shows a 0.5-1.7-dB implementation penalty, ture fluctuation of 2 C around pre-set temperature. 4x4x4lamba WDM cross-connect switch with nanoseconds allowing 520-Gb/s super-channel transmission over 4160 km. wavelength, space, time switching operation. Experimental results show error-free dynamic switching of 10 Gb/s, 20 Gb/s, and 40 Gb/s data packets with <2dB penalty. W.2.D.5 • 12:00 W.2.E.4 • 12:00 W.2.F.4 • 12:00 Invited Improved Flexibility in Rate and Reach by Time-Frequency Transmission Characteristics of 32-Gbaud PDM IQ Coherent Optical Subcarrier Processing and Add/Drop Packed QPSK Monolithic Silicon Modulator Operating with 2-VPPD Drive Multiplexing Qian Hu, Fred Buchali, Laurent Schmalen, Wilfried Idler, Roman Voltage Carsten Schmidt-Langhorst, Thomas Richter and Robert Elschner Dischler and Henning Buelow (Nokia Bell Labs, DE) Norihiro Ishikura, Kazuhiro Goi, Haike Zhu, Mikhail Illarionov, Hiroki (Fraunhofer Heinrich Hertz Institute, DE); Tomoyuki Kato, Takahito We experimentally demonstrate a transmission system with Ishihara, Akira Oka, Takuya Oda, Koichiro Masuko, Teijiro Ori and Tanimura, Shigeki Watanabe and Takeshi Hoshida (Fujitsu adaptable rate and reach based on time-frequency-packing Kensuke Ogawa (Fujikura Ltd., JP); Yuki Yoshida (National Institute Laboratories Ltd., JP); Colja Schubert (Fraunhofer Heinrich Hertz technique. Packed by a digital filter, the DP-QPSK signal is of Information and Communications Technology, JP); Ken’ichi Ki- Institute, DE) transmitted at various baud rates in a sub-Nyquist channel with tayama (The Graduate School for the Creation of New Photonics Frequency conversion in optical fiber allows for coherent optical fixed bandwidth. Industries, JP); Tsung-Yang Liow, Xiaoguang Tu, Patrick Lo and processing of densely multiplexed subcarriers in spatially separat- Dim-Lee Kwong (Institute of Microelectronics, SG) ed nodes. Proof-of-concept experiments show the applicability to Monolithic silicon PDM IQ modulator having vertical PN-junction up to 32QAM subcarriers, broadband operation (400 GHz) and rib-waveguide phase shifters in a ceramic-based metal package selective processing of PDM subcarrier tributaries. operating with RF drive voltage as low as 2 VPPD is character- ized in 32-Gbaud optical-fibre transmission. Signal-to-noise ratio penalty is obtained as 5.5 dB. W.2.E.5 • 12:15 High-Speed Monolithically Integrated Silicon Photonic Transmitters in 0.25 μm BiCMOS Platform Despoina Petousi, Iria Garcia Lopez (IHP GmbH, DE); Stefan Lischke (IHP Frankfurt/Oder, DE); Dieter Knoll, Pedro Rito, Marcel Kroh and Georg Winzer (IHP GmbH, DE); Christian Mai (IHP Frankfurt/Oder, DE); Karsten Voigt (Technical University of Berlin, DE); Ahmet Cagri Ulusoy and Dietmar Kissinger (IHP GmbH, DE); Lars Zimmermann (IHP & Technical University of Berlin, DE); Klaus Petermann (Technical University of Berlin, DE) Monolithically integrated Si depletion-type transmitters in 0.25 μm photonic BiCMOS platform with different driving approach- es are discussed. A power efficient implementation featuring integrated 4-bit DAC functionality is presented, from which PAM-4 eye diagrams up to 40 Gb/s are demonstrated. 12:30 - 14:00 Lunch Break 43 Technical Programme Wednesday, September 21, 2016 • 14:00 - 15:30 W.3.A: Room 18+19 W.3.B: Room 17 W.3.C: Room 16 Elastic Optical NetworksSC6 I Fibres for ModeSC1 Division Multilexing Nonlinear OpticalSC3 Signal Processing Chair: Ioannis Tomkos (Athens Information Chair: Francesco Poletti (University of Chair: Leif Oxenløwe (Technical University of Technology, GR) Southampton, UK) Denmark, DK) W.3.A.1 • 14:00 Tutorial W.3.B.1 • 14:00 Invited W.3.C.1 • 14:00 Upgraded Roles and Benefits of Elastic Optical Networks in Beyond Linear and Nonlinear Properties of OAM in Fibers THz-Range Optical Frequency Shifter for Dual Polarization 100-Gb/s Era Siddharth Ramachandran (Boston University, USA) WDM Signals Using Frequency Conversion in Fibre Masahiko Jinno (Kagawa University, JP) Stable propagation of OAM in fibers has opened up a new Tomoyuki Kato and Shigeki Watanabe (Fujitsu Laboratories This tutorial reviews elastic optical networking technology and design space with applications ranging from telecommunications Ltd., JP); Takahito Tanimura (The University of Tokyo & Fujitsu presents its roles and benefits in a new era where major line rates to biomedical imaging. This talk will review progress in the field, Laboratories Ltd., JP); Thomas Richter, Robert Elschner, Carsten in metro/core optical networks are 100 Gb/s and beyond. elucidating the unique linear and nonlinear properties of OAM Schmidt-Langhorst and Colja Schubert (Fraunhofer Hein- fiber modes. rich-Hertz-Institut, DE); Takeshi Hoshida (Fujitsu Laboratories Ltd., JP) We propose an optical frequency shifter for dual-polarization signals using frequency conversion in fibre. We achieve THz- range frequency shift with the original signal suppression without an optical filter and demonstrate combining of two dual-polariza- tion 400-Gb/s superchannels with acceptable in-band crosstalk. W.3.B.2 • 14:30 W.3.C.2 • 14:30 Upgraded Low-Loss 25.3km Few-Mode Ring-Core Fibre for Mode-Di- QPSK Phase-Regeneration in a Silicon Waveguide Using vision Multiplexed Transmission Phase-Sensitive Processing Yongmin Jung and Qiongyue Kang (Optoelectronics Research Isaac Sackey and Erik Liebig (Technical University of Berlin, DE); Centre, University of Southampton, UK); Hongyan Zhou (State Thomas Richter (Fraunhofer Heinrich-Hertz-Institut, DE); Andrzej Key Laboratory of Optical Fiber and Cable Manufacture Technolo- Gajda (IHP GmbH, DE); Lars Zimmermann (IHP & Technical gy, PRC); Rui Zhang, Su Chen, Honghai Wang and Yucheng Yang University of Berlin, DE); Klaus Petermann (Technical University of (Yangtze Optical Fibre and Cable Joint Stock Limited Company, Berlin, DE); Colja Schubert (Fraunhofer Heinrich-Hertz-Institut, DE) PRC); Xianqing Jin (USTC, PRC); Frank Payne (University of We present an in-line 4-level phase-regenerator which utilizes Oxford, UK); Shaif-ul Alam and David J Richardson (University of phase-sensitive amplification in a silicon waveguide with re- Southampton, UK) verse-biased p-i-n junction. Phase noise reduction is investigated We report the design, fabrication and characterisation of a for a QPSK signal in a 1,040-km dispersion-managed link. few-mode ring-core fibre supporting 4 mode groups. The low loss (~0.3dB/km) and length (25.3km) are both records for a ring-core fibre. W.3.B.3 • 14:45 Group Delay Spread in Graded-Index 10-Spatial-Mode Fibers Carmen Castineiras (Prysmian Group & University Lille 1, FR); Denis Molin and Marianne Bigot (Prysmian Group, FR); Laurent Bigot (University of Lille - CNRS, FR); Yves Quiquempois (Univer- sité de lille, FR); Pierre Sillard (Prysmian, FR) We theoretically investigate the group delay spread (GDS) of 10-spatial-mode fibers.The strongly-coupled regime leading to the increase of GDS with the square root of distance is only achieved for high perturbations and below a certain effective index difference value. W.3.A.2 • 15:00 W.3.B.4 • 15:00 W.3.C.3 • 15:00 How deploying elastic and fixed 100 Gb/s transponders Fibers with High Numbers of Modes and Low DMGDs Characterization of a Wavelength Converter for 256-QAM can further optimize cost per Gb/s during ageing of WDM Pierre Sillard, Marianne Bigot and Denis Molin (Prysmian Group, Signals Based on an AlGaAs-On-Insulator Nano-waveguide networks FR); Koen de Jongh and Frank Achten (Prysmian Group, NL) Francesco Da Ros, Metodi Yankov, Edson Porto da Silva, Minhao Thierry Zami (Nokia, FR); Jelena Pesic and Petros Ramantanis Fibers with high numbers of spatial modes (≥15) and low Pu, Luisa Ottaviano and Hao Hu (Technical University of Denmark, (Nokia Bell Labs, FR) DMGDs (<90ps/km) are designed and fabricated. In such fibers, DK); Elizaveta Semenova (Department of Photonics Engineer- This study illustrates how jointly deploying relatively low cost the highest-order modes are not used to reduce the impacts of ing, Technical University of Denmark, DK); Soren Forchhammer 100 Gb/s optical transponders and elastic optical transponders cladding and DMGD sensitivity to process variability. (Technical University of Denmark, DK); Darko Zibar (DTU Fotonik, fitting the ageing of margins can further improve return on invest- department of Photonic Engineering, Technical University of ment for the operators of WDM networks Denmark, DK); Michael Galili, Kresten Yvind and Leif Oxenløwe (Technical University of Denmark, DK) High efficiency and broadband wavelength conversion in a 9-mm AlGaAs-On-Insulator waveguide is shown to provide high-quality (OSNR > 30 dB) idler generation over a 28-nm bandwidth enabling error-free conversion of 10-GBd 256-QAM with OSNR penalty below 2.5 dB. W.3.A.3 • 15:15 W.3.B.5 • 15:15 W.3.C.4 • 15:15 Low-cost CD-ROADMs Based Elastic Optical Networks Demonstration of a Thin-Ring Air Core Fiber Supporting 22 Experimental Demonstration of Phase-Sensitive Regenera- Employing Wavelength Defragmentation Stable Angular Momentum Modes tion of a 20-40 Gb/s QPSK Channel without Phase-Locked Yutaka Takita, Kazuyuki Tajima, Tomohiro Hashiguchi and Toru Patrick Gregg (Boston University, USA); Poul Kristensen (OFS Loop using Brillouin Amplification Katagiri (Fujitsu Limited, JP) Fitel, DK); Steven Golowich (MIT-Lincoln Laboratory, USA); Ahmed Almainman, Yinwen Cao, Morteza Ziyadi, Amirhossein We evaluate low-cost CD-ROADMs (L-CD-ROADMs) based Siddharth Ramachandran (Boston University, USA) Mohajerin-Ariaei, Peicheng Liao, Changjing Bao, Fatemeh Alisha- elastic optical networks where wavelength defragmentation is A thin-ring air-core fiber design suppressing higher radial-order hi, Ahmad Fallahpour, Bishara Shamee (University of Southern applied. Through simulations, we confirm that such networks modes enables supporting a record number (22) of stable California, USA); Joe Touch (USC/ISI, USA); Youichi Akasaka can save close to 50% of ROADM cost in the add/drop part with spin-orbit coupled angular momentum modes over 10m. Output and Tadashi Ikeuchi (Fujitsu Laboratories of America, Inc., USA); negligible impact on wavelength utilization efficiency. projection measurements of all non-degenerate modes reveal Steven Wilkinson (Raytheon, USA); Moshe Tur (Tel-Aviv University, >18dB purity relative to nearest neighbours. IL); Alan Willner (University of Southern California, USA) We experimentally demonstrate all-optical phase-sensitive regeneration of a 20-40Gb/s QPSK signal without a phase-locked loop by amplifying the fourth harmonic using Brillouin amplifica- tion. We observe up to 65% reduction in phase noise and 3.4 dB gain at BER of 10-4. 15:30 - 16:00 Coffee Break | Exhibition Hall | 16:00 - 17:30 W.4.P: Poster Session I 44 Technical Programme Wednesday, September 21, 2016 • 14:00 - 15:30 W.3.D: Room 15 W.3.E: Room 110 W.3.F: Room 112 Advanced ModulationSC5 Formats II TWDM PON SC7 Silicon PhotonicsSC2 and Integration Chair: Hiroshi Onaka (Fujitsu Limited, JP) Chair: Derek Nesset (BT plc, UK) Chair: Antonio Fincato (STMicroelectronics, IT) W.3.D.1 • 14:00 W.3.E.1 • 14:00 W.3.F.1 • 14:00 82.29-Tb/s (182×560-Gb/s) Transmission of 42GHz-Spaced Field-Trial of a Real-Time 100 Gb/s TWDM-PON Based on Optimization of Integrated Silicon Doped Heaters for Opti- WDM PDM-128-QAM OFDM Signals over 100-km SMF 10G-Class Optical Devices cal Microring Resonators Fan Li and Jianjun Yu (ZTE (TX) Inc., USA); Yuanquan Wang, Jun- Lilin Yi, Honglin Ji and Zhengxuan Li (Shanghai Jiao Tong Univer- Paolo Pintus, Costanza Manganelli, Fabrizio Gambini and Fabrizio wen Zhang and Xinying Li (Fudan University, PRC); Hung-Chang sity, PRC); Xiang Li, Cai Li (Wuhan Research Institute of Post & Di Pasquale (Scuola Superiore Sant’Anna, IT); Maryse Fournier Chien (ZTE (TX) Inc., USA) Telecommunication, PRC); Qi Yang (FiberHome, PRC); Lei Xue and Olivier Lemonnier (CEA LETI, FR); Christophe Kopp (CEA, Transmission of 42GHz-spaced 182×560-Gb/s PDM-128QAM- and Xiaodong Wang (Shanghai Jiao Tong University, PRC); Suyi LETI, MINATEC DOPT Grenoble, FR); Claudio Oton (Scuola OFDM over 2×50-km SMF with DFT-S PAPR suppression and Wang, Ying Yang and Junbo Xu (Fiberhome, PRC); Shaohua Yu Superiore Sant’Anna, IT) DD-LMS post-equalization is successfully demonstrated for the (Huazhong University of Science&Technology, PRC); Weisheng We present the design, the fabrication and the characterization first time to enable large-capacity systems on 400G wavelengths. Hu (Shanghai Jiao Tong University, PRC) of thermally tunable integrated silicon-doped heaters for optical We show the first field trial of 100G-PON with downstream/ switches. Their performance, with focus on Reconfigurable Opti- upstream data rates of 25/10Gb/s/λ based on 10G-class optical cal Add/Drop Multiplexer, has been investigated in term of power devices supporting 40-km reach and 33-dB loss budget. The sys- consumption and time response. tem stability is verified by 67-hour real-time BER measurement. W.3.D.2 • 14:15 W.3.E.2 • 14:15 W.3.F.2 • 14:15 Super-Nyquist 9-WDM 126-GBaud PDM-QPSK Transmis- Experimental Demonstration of Low Cost Wavelength Drift Ge Waveguide Photodetector on Wafer-Bonded Ge-on-In- sion over 7878km using Digital-Preprocessed Analog-Mul- Mitigation for TWDM Systems sulator Substrate Monolithically Integrated with Amor- tiplexed DAC for Long-Haul Applications Gael Simon and Fabienne Saliou (Orange, FR); Philippe Chanclou phous Si Waveguide Asuka Matsushita, Fukutaro Hamaoka, Masanori Nakamura, and Luiz Anet Neto (Orange Labs, FR); Didier Erasme (Telecom Jian Kang, Mitsuru Takenaka and Shinichi Takagi (University of Kengo Horikoshi, Hiroshi Yamazaki and Munehiko Nagatani ParisTech, FR) Tokyo, JP) (NTT Corporation, JP); Akihide Sano (NTT Network Innovation We experimentally proved that a harmful wavelength drift of We demonstrate the proof-of-concept of Ge/a-Si hybrid pho- Laboratories, JP); Akira Hirano (NTT, JP); Yutaka Miyamoto (NTT tunable DMLs under burst mode is induced by adiabatic and tonic integrated circuits on Ge-on-insulator (GeOI) substrate fabri- Network Innovation Laboratories, JP) thermal chirp. We demonstrate the possibility to compensate one cated by wafer bonding. We successfully demonstrate waveguide We successfully demonstrate 400Gbps/carrier data trans- phenomenon by the other. The wavelength drift can be reduced Ge PIN photodetector with low-dark-current operation on GeOI mission (504Gbps line-rate assuming 25.5% FEC) over 7878km by 50%. wafer monolithically integrated with a-Si passive waveguide. using 126-GBaud PDM-QPSK signal generated by a digital pre-processed analog multiplexed DAC. Spectral efficiency of 3.21bit/s/Hz is achieved with super-Nyquist 125-GHz WDM spacing and optical pre-filtering. W.3.D.3 • 14:30 W.3.E.3 • 14:30 Invited W.3.F.3 • 14:30 Comparison of Single Carrier 200G 4QAM, 8QAM and Burst-Mode Optical Amplifier Technologies for TWDM-PON Novel Nonreciprocal Devices with Integrated Electromag- 16QAM in a WDM Field Trial Demonstration over 612 km Masamichi Fujiwara (NTT Access Network Service Systems net for Silicon Photonics SSMF Laboratories, JP) Paolo Pintus (Scuola Superiore Sant’Anna, IT); Duanni Huang and Ginni Khanna (Technical University of Munich, DE); Talha Rahman We introduce our burst-mode optical amplifier technologies for Chong Zhang (University of California, Santa Barbara, USA); Yuya (Eindhoven University of Technology, Eindhoven, NL); Erik Man (Cori- TWDM-PONs that support E2 class power budget, allow service Shoji and Tetsuya Mizumoto (Tokio Institute of Technology, JP); ant R&D GmbH, DE); Emilio Riccardi (Telecom Italia Lab, IT); Annachi- providers to flexibly locate optically-amplified repeaters in long- John Bowers (University of California, USA) ara Pagano, Anna Chiado`Piat (Telecom Italia, IT); Bernhard Spinnler, reach systems, and also accommodate many more users through We present a novel approach to construct integrated isolators Stefano Calabro, Danish Rafique, Uwe Feiste (Coriant R&D GmbH, higher splitting ratios. and circulators based on magneto-optical materials. An inte- DE); Huug de Waardt (Eindhoven University of Technology, NL); Bernd grated electromagnet is designed and fabricated, eliminating the Krombholz (Coriant R&D GmbH, DE); Tomislav Drenksi (Socionext need for a permanent magnet. The fabricated devices exhibit high Europe GmbH, UK); Marc Bohn, Antonio Napoli (Coriant R&D GmbH, performance and can be easily integrated/packaged. DE); Norbert Hanik (Munich University of Technology, DE) We present results of a field trial carried on Telecom Italia EDFA-only legacy link with 0.3 dB/km average fiber attenuation. Single carrier 200G WDM DP-4QAM, DP-8QAM and DP-16QAM were successfully transmitted with system margin of 4.1dB, 4.3dB and 2.6dB respectively. W.3.D.4 • 14:45 W.3.F.4 • 14:45 Experimental Study of Subcarrier Multiplexing Benefit in 74 Hybrid 2D/3D Photonic Integration for Non-Planar Circuit nm Bandwidth Transmission up to 20,450 km Topologies Jin-Xing Cai, Matthew Mazurczyk (TE SubCom, USA); Oleg Sinkin Aleksandar Nesic, Matthias Blaicher and Tobias Hoose (Karlsruhe (Tyco Telecom, USA); Maxim Bolshtyansky (TE Subcom, USA); Institute of Technology (KIT), DE); Matthias Lauermann (Infinera Dmitri Foursa (Tyco Telecommunications, USA); Alexei Pilipetskii Corporation, USA); Yasar Kutuvantavida, Wolfgang Freude and (Tyco Electronics Subsea Communications, USA) Christian Koos (Karlsruhe Institute of Technology (KIT), DE) We experimentally demonstrate 0.8dB subcarrier-multiplexing We present a concept for realizing crossing-free photonic benefit for QPSK signals transmitted in 74nm bandwidth over integrated circuits (PIC) using 3D freeform waveguides. We prove 20,450km, and only 0.2dB benefit is achieved for 16QAM signals. the viability of the approach using a silicon photonic 4x4 switch- We observe subcarrier index performance dependence due to the and-select device. The method is applicable to a wide range of transmitter RF noise spectrum. PIC technologies. W.3.D.5 • 15:00 Invited W.3.E.4 • 15:00 W.3.F.5 • 15:00 Invited Solutions for 400 Gbit/s Inter Data Center WDM Transmis- Dynamically Reconfigurable TDM-DWDM PON Ring Archi- Monolithic Electronic-Photonic Co-Integration in Photonic sion tecture for Efficient Rural Deployment BiCMOS Annika Dochhan (ADVA Optical Networking SE, DE); Nicklas Eiselt Daniel Carey, Nicola Brandonisio, Stefano Porto, Alan Naughton, Lars Zimmermann (IHP & Technical University of Berlin, DE) (Technical University of Denmark, DK); Helmut Griesser (ADVA Peter Ossieur (Tyndall National Institute, IR); Nick Parsons (Polatis Monolithic co-integration of silicon photonics with high-perfor- Optical Networking SE, DE); Michael Eiselt (ADVA, DE); Juan Jose Ltd., UK); Giuseppe Talli and Paul Townsend (Tyndall National mance BiCMOS is a new technology for implementing efficient Vegas Olmos (Technical University of Denmark, DK); Idelfonso Institute, IR) sub-systems in high-speed optical communications. Present Tafur Monroy (Technical University of Denmark, Denmark & ITMO A novel chained amplifier node access architecture for rural status of the technology will be reviewed, pros and cons in com- University, RU); Jörg-Peter Elbers (ADVA AG Optical Networking, DE) areas has been demonstrated for the first time using FEC in burst parison to other integration technologies will be discussed. We review some currently discussed solutions for 400 Gbit/s mode operation at 10Gb/s implemented on FPGAs supporting 40 inter-data center WDM transmission for up to 100 km. We focus channels and 1024 users with a reach of 120k. on direct detected solutions, namely PAM4 and DMT, and present two WDM systems based on these formats. W.3.E.5 • 15:15 User/Service Group Separation in Optical Domain Using Overlayed Modulation Technique for 40 Gbit/s Single Wavelength TDM PON Robert Borkowski (Nokia, DE); Rene Bonk (Alcatel-Lucent, DE); Wolfgang Poehlmann (Nokia, DE); Thomas Pfeiffer (Alcatel-Lu- cent, DE) We experimentally demonstrate optical layer separation be- tween user/service groups in burst-mode upstream of 40 Gbit/s TDM PON using overlayed modulation technique. Loss budget exceeding 29 dB and C-band transmission up to 40 km with 12 km differential reach is achieved. 15:30 - 16:00 Coffee Break | Exhibition Hall | 16:00 - 17:30 W.4.P: Poster Session I 45 Poster Session I Wednesday, September 21, 2016 • 16:00 - 17:30 SC 1 - Fibres, Fibre Devices and Fibre Amplifiers W.4.P1.SC2.11 PDM-QPSK WDM Signal Amplification Using PPLN-Based Polarization-Inde- pendent In-Line Phase-Sensitive Amplifier Masashi Abe, Takushi Kazama, Takeshi Umeki and Koji Enbutsu (NTT Device Technol- W.4.P1.SC1.1 Experimental Observation of Mid-infrared Supercontinuum Generation in an ogy Laboratories, JP); Yutaka Miyamoto (NTT Network Innovation Laboratories, JP); As2Se3- AsSe2 Fiber Hirokazu Takenouchi (NTT Photonics Laboratories, JP) Tonglei Cheng, Kenshiro Nagasaka, Hoang Tuan Tong and Xiaojie Xue (Toyota Tech- We demonstrate the in-line phase-sensitive amplification of PDM-QPSK WDM sig- nological Institute, JP); Morio Matsumoto and Hiroshige Tezuka (Furukawa Denshi nals. The amplifier consists of PPLN waveguides and has a net gain of 12 dB. These Co., Ltd., JP); Takenobu Suzuki and Yasutake Ohishi (Toyota Technological Institute, signals are transmitted over 80 km by recovering the pilot tone. JP) We experimentally investigate supercontinuum generation spanning 2.0 to 15.1 μm in a 3 mm-long As2Se3-AsSe2 fiber with the mid-infrared femtosecond pulse pump W.4.P1.SC2.12 Broadband Frequency Comb Generation in Aluminum Nitride Microring source. Resonators Xianwen Liu, Changzheng Sun, Bing Xiong, Jian Wang, Lai Wang, Yanjun Han, Zhib- W.4.P1.SC1.2 Low-loss and Low-nonlinearity Few-mode Fibre for LP21 Mode Transmission iao Hao, Hongtao Li and Yi Luo (Tsinghua University, PRC); Jianchang Yan, Tongbo with Low DSP Complexity Wei, Yun Zhang and Junxi Wang (Institute of Semiconductors, Chinese Academy of Takayoshi Mori, Taiji Sakamoto, Masaki Wada, Azusa Urushibara, Takashi Yamamoto Sciences, PRC) and Kazuhide Nakajima (NTT Corporation, JP) Nearly octave frequency comb spanning from 1075 to 2075 nm is generated in A few-mode fibre with a low-loss (0.180 dB/km) and large-Aeff (366 um2) at 1550 epitaxial aluminum nitride microring resonator with intrinsic quality factor as high as nm in the LP21 mode is presented. We demonstrate a low-DSP-complexity transmis- ~1.6 million. Blue-shifted dispersive-wave emission is observed, which helps extend sion over 100 km few-mode fibre and reveal high nonlinear tolerance using the LP21 the frequency comb coverage. mode. W.4.P1.SC2.13 Broadband 8 × 8 Si-Wire PILOSS Switch with Double Mach-Zehnder Switch W.4.P1.SC1.3 Theoretical study of mode coupling via the gain medium in FM-EDFA Elements including mode beating effects Keijiro Suzuki, Ken Tanizawa, Satoshi Suda, Hiroyuki Matsuura, Kazuhiro Ikeda, Shu Jean-Baptiste Trinel, Guillaume Le Cocq, Olivier Vanvincq, Yves Quiquempois, Esben Namiki and Hitoshi Kawashima (National Institute of Advanced Industrial Science and Andresen (Université de Lille, FR); Laurent Bigot (University of Lille - CNRS, FR) Technology, JP) A field-propagating model for active optical fibers is applied to the particular case We report a broadband 8×8 Si-wire optical switch based on a double Mach- of Few-Mode EDFA. Mode coupling through the amplifying medium is analyzed and Zehnder element switch. An operating bandwidth of 20 nm for -20 dB crosstalk is results show significant differences compared to usual intensity models. obtained, which is 2.7-times broader than that with single Mach-Zehnder element switches. W.4.P1.SC1.4 Bi/Er Co-doped Fibers as an Active Medium for Optical Amplifiers for the W.4.P1.SC2.14 Route-and-Select Type Wavelength Cross Connect for Core-Shuffling of C-, L- and U- Telecommunication Bands 7-Core MCFs with Spatial and Planar Optical Circuit Sergei Firstov (Fiber Optics Research Center, RAS, RU); Vladimir F. Khopin (Institute Keita Yamaguchi (NTT Corporation & NTT Device Technology Labs, JP); Mitsumasa of Chemistry of High Purity Substances of RAS, RU); Konstantin Riumkin and Sergey Nakajima, Yuichiro Ikuma, Kazunori Seno and Osamu Moriwaki (NTT Corporation, JP); Alyshev (Fiber Optics Research Center, RAS, RU); Mikhail Melkumov (Fiber Optics Kenya Suzuki (NTT Device Technology Laboratories, NTT Corporation, JP); Mikitaka Research Center of the Russian Academy of Sciences, RU); Aleksey N. Guryanov Itoh (NTT Photonics Laboratories, JP); Mitsunori Fukutoku (NTT Innovation Labora- (Institute of Chemistry of High Purity Substances of RAS, RU); Evgeny M. Dianov tories, JP); Yutaka Miyamoto (NTT Network Innovation Laboratories, JP); Toshikazu (Fiber Optics Research Center of the Russian Academy of Sciences, RU) Hashimoto (NTT Corporation, JP) We report the first results on the fabrication of Bi/Er co-doped fibers with the gain We demonstrated a route-and-select type 7×7 core-shuffle wavelength cross bandwidth over 200 nm ranging from 1530 to 1770 nm. The main fiber characteris- connect switch based on a spatial and planar optical circuit. The spatial beam tics affecting the amplification are discussed. transformer enables us to integrate 14-in-1 WSSs in the same optical system as the conventional 1×N WSS. W.4.P1.SC1.5 Angular Momentum Dependence of the Twist-Induced Effect in Few-Mode Fibres W.4.P1.SC2.15 Flexible, Multi-channel, Ultra-dense Optical Interface for Silicon Photonics Paolo Martelli, Annalaura Fasiello, Oriana Soccali, Pierpaolo Boffi and Mario Martinelli Victor I. Kopp, Jongchul Park, Mitch Wlodawski, Jonathan Singer and Dan Neu- (Politecnico di Milano, IT) groschl (Chiral Photonics Inc., USA); Peter De Heyn, Brad Snyder and Joris Van The twist-induced effect on fibre modes has been recognized as a phase shift Campenhout (IMEC, BE); Philippe Absil (IMEC, BE) depending on the total angular momentum. The amount of this phase shift has been We demonstrate an all-glass, 61-channel, flexible, two-dimensional optical fiber measured through an interference experiment in a few-mode fibre, confirming the array with 37 inner channels matched to an array of vertical grating couplers of a theoretical predictions. multi-channel (16 Tx and 16 Rx) transceiver prototype occupying a chip area of only 0.16 mm2. W.4.P1.SC1.6 Improved Method for Measuring Inter-Core Crosstalk in Multi-Core Fibres Using a Near-Infrared Camera W.4.P1.SC2.16 On-chip Optical Sampling using an Integrated SOA-based Nonlinear Optical Shota Saitoh, Yoshimichi Amma, Yusuke Sasaki, Katsuhiro Takenaga and Kazuhiko Loop Mirror Aikawa (Fujikura Ltd., JP) Leimeng Zhuang, Chen Zhu, Bill Corcoran, Zihan Geng, Binhuang Song and Arthur We present an improved method that enables measurement of crosstalk as low as Lowery (Monash University, AU) approximately −50 dB using a near-infrared camera. Measured results of a 32-core We report the first demonstration of on-chip optical sampling using an integrated fibre are in good agreement with those by the conventional method using a power SOA-based nonlinear optical loop mirror. The device implements a compact design meter. featuring a size of 2 x 1.2 mm2 and a sampling window of about 30 ps. W.4.P1.SC1.7 Highly Nonlinear Few-Mode Fiber for Optical Parametric Amplification W.4.P1.SC2.17 Experimental Demonstration of On-Chip Orbital Angular Momentum Carrying Elham Nazemosadat, Abel Lorences-Riesgo, Magnus Karlsson, Peter A Andrekson Twisted Light Generation Using Dielectric Metasurfaces on Silicon Platform (Chalmers University of Technology, SE) Hongya Wang (Huazhong University of Science and Technology & Wuhan National A highly nonlinear dispersion-shifted few-mode fiber is designed. The dispersion Laboratory for Optoelectronics, PRC); Jun Liu, Jing Du and Jian Wang (Huazhong properties and high nonlinearity of this fiber allow simultaneous single-pump paramet- University of Science and Technology, PRC) ric amplification of four spatial modes (LP01, LP11, LP02, LP21), with high gain and We demonstrate a method of generating twisted lights OAM whose topological low cross-talk, over the C-band. number ranges from l = 1 to 4 at the wavelength of 980 nanometer using dielectric metasurfaces array on silicon-on-insulator platform. W.4.P1.SC2.18 Integrated Switchable Mode Exchange for Reconfigurable Mode-Multiplexing SC 2 - Waveguide and Optoelectronic Devices Optical Networks Chunlei Sun, Yu Yu, Guanyu Chen and Xinliang Zhang (Huazhong University of Science and Technology, PRC) We propose and demonstrate an on-chip switchable mode exchange utilizing a W.4.P1.SC2.8 Low Operating-Energy Directly Modulated Membrane Distributed-Reflector mode dependent Mach-Zehnder interferometer assisting by a phase shifter. By con- Lasers on Si trolling the phase difference, the data carried on different modes can be exchanged Takuro Fujii, Koji Takeda, Erina Kanno, Koichi Hasebe, Hidetaka Nishi, Ryo Nakao, with power penalty less than 1dB. Tsuyoshi Yamamoto, Takaaki Kakitsuka , Shinji Matsuo (NTT Corporation, JP) We achieve a low operating energy and high modulation speed in a directly modu- W.4.P1.SC2.19 Integrated-optic Demultiplexer for Variable Capacity Optical OFDM Signals lated membrane laser on Si. A relatively thick (350 nm) membrane structure enables Composed of Slab Star Coupler-type Optical DFT Circuit and Variable Optical us to reduce the series resistance, which reduces the operating energy to 97 fJ/bit. Attenuators Koichi Takiguchi (Ritsumeikan University, JP) W.4.P1.SC2.9 8-channel InP OFDM Transmitter PIC with Integrated Optical Fourier I report a novel waveguide-type OFDM filter that can adaptively demultiplex 10 to Transform 50 Gbaud symbol rate sub-carrier channels. It was fabricated with silica waveguide Braulio Gomez Saavedra, Ronald Kaiser, Johannes Beyer, Marko Rausch, Marko technology and the adoption of variable attenuators reduced loss variation when Gruner, Walter Fürst and Martin Schell (Fraunhofer Institute for Telecommunications, changing the filter characteristics. Heinrich-Hertz-Institut, DE) An InP-based 8-channel 1550 nm OFDM transmitter PICs is demonstrated for the first time. The PIC integrates a 1x8 splitter/combiner, eight TWE Mach-Zehnder IQ modulators, an 8-port AWG, 50-Ohms termination resistors, and CPW/CPS transmis- sion line connections/transitions. W.4.P1.SC2.10 Integrated 8-Channel Mode and Wavelength Demultiplexer for MDM and WDM Transmission over Few-Mode Fibers Daniele Melati, Andrea Alippi, Andrea Annoni, Nicola Peserico and Andrea Melloni (Politecnico di Milano, IT) We demonstrate a photonic integrated circuit for simultaneous demultiplexing of two fiber modes and four wavelength channels. Combined with integrated MDM mul- tiplexer the circuit is successfully exploited for the transmission of 10Gbit/s channels with cross-talk lower than -15 dB. 46 Poster Session I Wednesday, September 21, 2016 • 16:00 - 17:30 SC 3 - Digital and Optical Signal Processing SC 4 - Subsystems for Optical Networking and Datacoms W.4.P1.SC3.20 Experimental Demonstration of All-Optical FEC Coding Scheme with Convo- W.4.P1.SC4.32 Adaptive RF Signal Stability Distribution Over Remote Optical Fiber Transfer lutional Code using Single Signal Source Based on Photonic Phase Shifter Yohei Aikawa and Hiroyuki Uenohara (Tokyo Institute of Technology, JP) Shanguo Huang, Wensheng ZHai, Xinlu Gao, Mutong Xie, Mingyang Zhao and We experimentally demonstrate all-optical FEC coding scheme consisting of all-op- Wenjing Xu (Beijing University of Posts and Telecommunications, PRC); Wanyi Gu tical HNLF-based wavelength converters and XOR gates with (7,5)_8 convolutional (Key Laboratory of Optical Communication and Lightwave Technologies, Ministry of code. The proposed scheme offers 3.5 dB net coding gain at BER=10^{-9} with Education, Beijing U, PRC) DPSK-modulated RZ-format signals at 10 Gbps. We demonstrate adaptive RF signal distribution stability over 50 km optical fiber using phase pre-compensation technology. The experimental results implement 360° W.4.P1.SC3.21 Sidelobe Suppression using Cancellation Sub-Carriers for OFDM phase shift over 20 GHz to 30 GHz with Allan deviation approximate 8.35×10-17 at Superchannels average time of 1000 s. Yiwei Xie, Chen Zhu, Binhuang Song and Arthur Lowery (Monash University, AU) We mitigate the inter-channel-interference (ICI) in orthogonal frequency division W.4.P1.SC4.33 Techno-Economic Analysis of Carrier Sources in Slice-able Bandwidth Vari- multiplexing (OFDM) superchannel by adding cancellation sub-carriers (CCs). We able Transponders experimentally show that CC-OFDM outperforms conventional OFDM by 0.4-dB in a Muhammad Imran (Scuola Superiore Sant‘Anna, IT); Antonio D‘Errico (Ericsson, IT); dual-polarization 400-Gbps 3360-km OFDM superchannel. Andrew Lord (British Telecom, UK); Luca Potì (Consorzio Nazionale Interuniversitario per le Telecomunicazioni, IT) W.4.P1.SC3.22 Real-Time Flexible Heterogeneous UDWDM System for Coherent PON Different carrier source implementation strategies in sliceable bandwidth variable Ricardo Ferreira (Instituto de Telecomunicações, PRT); Ali Shahpari (University of transponders have been compared in terms of cost and power consumption. A Aveiro, PRT); Sofia Amado (University of Aveiro & Instituto de Telecomunicações, reduction factor up to 4 has been obtained through novel centralized carrier source Aveiro, PRT); Jacklyn D. Reis (CPqD, BR); Armando Pinto, Antonio Teixeira (DETI, schemes. University of Aveiro & Insitituto de Telecomunicações, PRT) We demonstrate the first reconfigurable real-time receiver DSP in a flexible hetero- W.4.P1.SC4.34 Experimental Validation of Scalability Improvement for Passive Optical Inter- geneous UDWDM system for coherent PON applying different modulation formats. connect by Implementing Digital Equalization The evaluation reports the ODN power budget for multiple UDWDM configurations Rui Lin (KTH Royal Institute of Technology & Huazhong University of Science and using QPSK, 8PSK and 8QAM signals. Technology, PRC); Xiaodan Pang (Swedish ICT AB, SE); Oskars Ozolins (Acreo Swedish ICT, SE); Zhenhua Feng (Huazhong University of Science and Technology, W.4.P1.SC3.23 Cluster Analysis of Received Constellations for Optical Performance PRC); Anders Djupsjöbacka (Acreo, SE); Urban Westergren and Richard Schatz (Kista Monitoring Photonic Research Centre (KPRC), Royal Institute of Technology (KTH), SE); Gunnar John van Weerdenburg, Roy van Uden, Eric Sillekens and Huug de Waardt (Eind- Jacobsen (Acreo AB, SE); Ming Tang, Songnian Fu and Deming Liu (Huazhong hoven University of Technology, NL); Ton Koonen (COBRA, Eindhoven University of University of Science and Technology, PRC); Sergei Popov, Jiajia Chen (KTH Royal Technology, NL); Chigo Okonkwo (Eindhoven University of Technology, NL) Institute of Technology, SE) Performance monitoring based on centroid clustering to investigate constellation We experimentally investigate scalability of a coupler-based passive optical generation offsets. The tool allows flexibility in constellation generation tolerances by interconnect (POI) employing cost-efficient modulation formats, pulse amplitude forwarding centroids to the demapper. The relation of fibre nonlinearities and singular modulation and discrete multi-tone. Results reveal that digital equalization significantly value decomposition of intra-cluster noise is experimentally demonstrated. boosts the POI scalability, particularly for the cases requiring higher transmission performance. W.4.P1.SC3.24 Embedded In-Band DQPSK Signaling within n-QAM Data Transmission Roman Dischler, Fred Buchali and Laurent Schmalen (Nokia Bell Labs, DE) W.4.P1.SC4.35 Drive-amplitude-independent Auto Bias Control Circuit for QAM Signals and We propose embedded sequences of DQPSK-symbols in a n-QAM data stream for Its Demonstration with an InP-based IQ Modulator independent signaling on transponder level. Experimentally we demonstrate a simpli- Hiroto Kawakami and Shoichiro Kuwahara (NTT Corporation, JP); Akira Hirano (NTT, fied processing chain with low additional processing effort obtaining a BER margin of JP) factor 10 vs. data-BER. A novel auto bias control technique for various types of IQ modulators is proposed. The technique can generate any order quadrature amplitude modulation signals with W.4.P1.SC3.25 Characterization and Pre-Distortion of Linear and Non-Linear Transmitter no dependence on drive amplitude. The measured penalty was found to be almost Impairments for PM-64QAM Applications negligible. Thomas Duthel, Peter Hermann, Johann Schießl, Chris Fludger, Andreas Bisplinghoff and Theodor Kupfer (Cisco Optical GmbH, DE) W.4.P1.SC4.36 Direct Measurement on Frequency Response of Common Mode Rejection A characterization approach for optical IQ transmitter‘s skew, frequency response Ratio in Coherent Receiver and non-linear properties is presented. Its effectiveness is proven by performance Keizo Inagaki (National Institute of Information and Communications Technology, measurements of digitally pre-distorted PM-64QAM at 384Gbit/s. Special attention is JP); Tetsuya Kawanishi (Waseda University & National Institute of Information and given to the optical loss induced by modulation. Communications Technology, JP); Atsushi Kanno and Naokatsu Yamamoto (National Institute of Information and Communications Technology, JP) W.4.P1.SC3.26 A Novel Fixed Throughput Nonlinear Cross-Polarization Compensation: We propose a direct measurement method of CMRR frequency response in Flexible k-Best GML coherent receivers. Measured CMRR frequency response is drastically improved over Patricia Layec (Nokia Bell Labs France, FR); Nicola Rossi (Nokia Bell Labs, FR); 2 to 40 GHz frequency range by tuning the amplitude and skew balance in a coherent Sebastien Bigo (Bell Labs, Alcatel-Lucent, FR) receiver under test. We propose a novel blind nonlinear cross-polarization compensation method based on Generalized Maximum Likelihood. It offers a fixed throughput implementa- W.4.P1.SC4.37 SDN-enabled Backpropagation Correction for OSNR Estimation and Optimi- tion easing the hardware logic integration thanks to a breadth-first search. Simulations zation in Under-Monitored EDFA-based Optical Links show a 1dB gain in nonlinear tolerance. Juliano Assine, Anderson Bravalheri and Heitor Carvalho (CPqD, BR); Miquel Garrich (Politecnico di Torino, BR); Yue Fei, Xue Wang (The University of Texas at Dallas, W.4.P1.SC3.27 A Trellis-Based Phase Correction for Mitigating Nonlinear Effects USA); Andrea Fumagalli (UTD, USA); Jacklyn D. Reis (CPqD, BR); Juliano Rodrigues Mahdi Zamani, Hossein Najafi and Jeebak Mitra, Chuandong Li and Zhuhong Zhang Fernandes de Oliveira (CPqD Foundation & University of Sao Paulo, BR) (Huawei Technologies Canada, CA) SDN is a key technology to address the challenges in quasi-static and over-pro- A hardware-efficient trellis-based algorithm is proposed for fiber nonlinearity mitiga- visioned undermonitored EDFA-based optical links. We propose and experimentally tion in coherent systems, especially for high order modulations. Experimental results, demonstrate a SDN-enabled backpropagation correction technique to efficiently in 200 Gb/s DP-16QAM co-propagated with 10-G channels, demonstrate significant estimate and increase OSNR while minimizing remote network operations. performance improvement over other existing methods of comparable complexity. W.4.P1.SC4.38 MxM WSS Based ROADM Architecture with Topology-Insensitive Routing W.4.P1.SC3.28 Ultra-Wideband Nonlinearity Compensation Performance in the Presence of Performance PMD Masaki Niwa, Yojiro Mori and Hiroshi Hasegawa (Nagoya University, JP); Ken-Ichi Gabriele Liga (University College London, UK); Cristian B. Czegledi (Chalmers Sato (School of Engineering - Nagoya University, JP) University of Technology, SE); Tianhua Xu (Optical Networks Group, University College We propose MxM WSS based ROADM architecture that employs main/junction London, UK); Erik Agrell (Chalmers University of Technology, SE); Robert I Killey and subsystem OXCs and OXC-assisted transponder-bank add/drop. Extensive computer Polina Bayvel (University College London, UK) simulations verify that the proposed architecture offers high routing performance We numerically investigate the performance of multi-channel digital backpropaga- regardless of the physical network topology cost-effectively. tion for 1 THz optical fibre transmission in the presence of polarisation-mode disper- sion. We show that the average SNR performance rapidly saturates as a function of W.4.P1.SC4.39 SEFDM Based Spectrum Compressed VLC System Using RLS Time-domain the compensation bandwidth. Channel Estimation and ID-FSD Hybrid Decoder Yiguang Wang and Yingjun Zhou (Fudan University, PRC); Tao Gui, Kangping Zhong, W.4.P1.SC3.29 Novel IM/DD Single-Sideband OFDM Generation Featuring Tolerance to Xian Zhou, Liang Wang, Alan Pak Tao Lau and Chao Lu (The Hong Kong Polytechnic Dispersion-Related Fading and Distortion University, HK); Nan Chi (Fudan University, PRC) Yi-Hsiang Wang and Chia-Chien Wei (National Sun Yat-Sen University, TW); Hidenori For the first time we experimentally demonstrate an 800Mb/s SEFDM based VLC Taga Takehiro Tsuritani (KDDI R&D Laboratories Inc., JP) system over 3m free-space transmission for 20% bandwidth saving. RLS time-do- Based on a cascaded DML/EAM, we proposed a novel IM/DD scheme to generate main equalizer is proposed for channel estimation, and an ID-FSD hybrid decoder is SSB-OFDM signals, featuring tolerance to dispersion-related fading and distortion. utilized for ICI elimination. Without compensation for dispersion and nonlinear distortion, 5-GHz SSB-OFDM signal can achieve 12.8 Gbps after 250 km. W.4.P1.SC4.40 Real Time 10Gb-Ethernet Transmission over 2D Indoor Passive Beam Steered Optical Wireless System based on High Port Arrayed Waveguide W.4.P1.SC3.30 Precoded Faster-than-Nyquist Coherent Optical Transmission Gratings Mrinmoy Jana, Ahmed Medra and Lutz Lampe (University of British Columbia, CA); Amir Masood Khalid, Maria Torres Vega, Ketamaw Mekonnen, Zizheng Cao and Jeebak Mitra (Huawei Technologies Canada, CA) Antonio Liotta (Eindhoven University of Technology, NL); Ton Koonen (COBRA, Eind- In this paper we propose a novel symbol-by-symbol memoryless soft demapping hoven University of Technology, NL) method for coded coherent optical systems that employ Faster-than-Nyquist (FTN) We demonstrate the real-time 10Gb-Ethernet data delivery to multiple users transmission for improved spectral efficiency and Tomlinson-Harashima precoding for simultaneously over an indoor optical wireless system based on 2D passive optical low-complexity equalization of FTN. beam-steering using high-port count arrayed waveguide gratings. The transmitted optical power is kept below eye safety limit W.4.P1.SC3.31 Electro-Optic Frequency Offset Estimator for Optical OFDM Jokhakar Jignesh, Bill Corcoran and Chen Zhu (Monash University, AU); Arthur Lowery (Monash Univ, AU) We present a new design for an electro-optic carrier frequency offset (CFO) estimator for optical OFDM systems, and experimentally demonstrate CFO estimation using off-the-shelf components, capable of tracking up to ±500 MHz offsets from a 28-Gbaud OFDM signal. 47 Poster Session I Wednesday, September 21, 2016 • 16:00 - 17:30 W.4.P1.SC4.41 Multi-Wavelength Multiplexer with Independent Mode Control Based on W.4.P1.SC5.51 552 Gbit/s, 46 Gbaud, 64 QAM Coherent Transmission over 160 km with Multi-Plane Light Conversion Simple LD-based Injection-locked Homodyne Detection Guillaume Labroille, Nicolas Barré, Pu Jian and Jean-François Morizur (CAILabs SAS, Keisuke Kasai, Masato Yoshida and Masataka Nakazawa (Tohoku University, JP) FR) We describe a single-carrier, polarisation-multiplexed 46 Gbaud 64 QAM coherent We report dual wavelength spatial multiplexers based on the technique of Multi- transmission. Using an LD-based injection-locked local oscillator for homodyne de- Plane Light Conversion, which have the capability of independently multiplexing tection, we transmitted 552-Gbit/s data over 160 km with a bit-error rate of 6×10^-4. signals at different wavelengths with high mode selectivity, enabling applications to The potential spectral efficiency reached 9.2 bit/s/Hz. FM-EDFA and PON over multi-mode fibers. W.4.P1.SC5.52 178 Gb/s Short-Range Optical Transmission Based on OFDM, Electrical W.4.P1.SC4.42 Capacity Improvement Using Bandwidth-Variable Transceiver in Meshed Up-Conversion and Signal Combining Optical Networks with Cascaded ROADMs Christoph Kottke (Fraunhofer Heinrich Hertz Institute, DE); Christian Schmidt Xingyu Zhou (University of Electronic Science and Technology of China, PRC); Qunbi (Technical University of Berlin & Fraunhofer Heinrich Hertz Institute, DE); Kai Habel Zhuge (Ciena Corporation, CA); Meng Qiu (McGill University, Montreal, CA); Xiang (Fraunhofer HHI, DE); Volker Jungnickel (Fraunhofer Heinrich Hertz Institute & Techni- Meng (Huazhong University of Science and Technology, PRC); Fangyuan Zhang cal University of Berlin, DE) (McGill University, CA); Baojian Wu (University of Electronic Science and Technology We demonstrate our improved wideband OFDM transmission system, using of China, PRC); David Plant (McGill University, CA) electrical up-conversion and signal combining. Transmission rates of 178 Gb/s over 2 We experimentally demonstrate the capacity improvement achieved by band- km of SSMF were achieved with an IM/DD system on a single wavelength and single width-variable transceivers (BVT) in fiber links with cascaded ROADMs. Compared polarization. with a fixed symbol rate transceiver with standard QAMs, the BVT increases capacity by up to 17%. W.4.P1.SC5.53 High Resolution Characterization of the Spectral Broadening Due to Inter-Channel Fiber Nonlinearities W.4.P1.SC4.43 Up to 108 Gb/s PAM 850 nm Multi and Single Mode VCSEL Transmission over Aazar Kashi, John C Cartledge and Ali Rezania (Queen‘s University, CA); Ali Bakhshali 100 m of Multi Mode Fiber (Queens University, CA); Maurice O‘Sullivan, Charles Laperle, Andrzej Borowiec and Grzegorz Stepniak (Warsaw University of Technology, PL); Lukasz Chorchos (Warsaw Kim Roberts (Ciena Corporation, CA) University of Technology & Institute of Telecommunications, PL); Mikel Agustin, Joerg The spectral broadening due to inter-channel fiber nonlinearities is quantified in Kropp, Nikolai Ledentsov, Vitaly Shchukin, Nikolai Ledentsov, Jr (VI Systems GmbH, terms of the spectral edge power for 256 Gb/s dual-polarization 16-QAM signals in a DE); Jarosław P. Turkiewicz (Warsaw University of Technology & Institute of Telecom- 9-channel system with 37.5 GHz channel spacing. munications, PL) Studies on ultra-high speed 850 nm VCSEL transmission are presented. Various W.4.P1.SC5.54 Evaluation of High-Speed EML-based IM/DD links with PAM Modulations and system configurations regarding fibre length, VCSEL type and uncoded and coded Low-Complexity Equalization PAM modulation schemes are investigated. Successful record 108 Gb/s PAM-4 Xiaodan Pang (Swedish ICT AB, SE); Oskars Ozolins (Acreo Swedish ICT, SE); transmission over 100 m MMF is shown. Simone Gaiarin (Technical University of Denmark, DK); Miguel Olmedo (Royal Institute of Technology, SE); Richard Schatz and Urban Westergren (Kista Photonic Research W.4.P1.SC4.44 PAM-n Solutions for Low-Cost Implementations of 100 Gbps/Lambda Trans- Centre (KPRC), Royal Institute of Technology (KTH), SE); Darko Zibar (DTU Fotonik, missions depertment of Photonic Engineering, Technical University of Denmark, DK); Sergei Cristian Prodaniuc, Nebojsa Stojanovic, Fotini Karinou and Qiang Zhang (Huawei Popov (Royal Institute of Technology, SE); Gunnar Jacobsen (Acreo AB, SE) Technologies Duesseldorf GmbH, DE); Thomas Dippon (Keysight Technologies We experimentally evaluated up to 96 Gb/s/λ PAM IM/DD transmissions with an Deutschland GmbH, DE); Roberto Llorente (Universidad Politecnica de Valencia, ES) EML and digital equalizations. Symbol-spaced FFE/DFEs with fewer than 10 taps are We experimentally demonstrate 112 Gbps PAM-4 and 126 Gbps PAM-8 BTB shown being sufficient for a high and stable performance over a 4 km SMF link. transmissions using bandlimited setups with less than 12 GHz 3-dB bandwidth. 4D-PAM-5 TCM is also implemented, showing power sensitivity gains over PAM-4 at W.4.P1.SC5.55 Experimental Demonstration of Physical-Layer Security in a Fiber-Optic Link rates of up to 88 Gbps. by Information Scrambling Junho Cho, Kyle C Guan, Sethumadhavan Chandrasekhar, Peter Winzer (Nokia Bell W.4.P1.SC4.45 Low Latency Optical Label Switched Add-Drop Node for Multi-Tb/s Data Labs, USA) Center Interconnect Metro Networks We experimentally demonstrate a physical-layer secure optical fiber communica- Wang Miao, John van Weerdenburg, Roy van Uden and Huug de Waardt (Eindhoven tion link that prohibits an eavesdropper from detecting any useful information. Our University of Technology, NL); Ton Koonen (COBRA, Eindhoven University of Technol- classical approach is based on a simple linear feedback shift register, thus scaling to ogy, NL); Chigo Okonkwo (Eindhoven University of Technology, NL); Nicola Calabretta multi-Terabits/s of secure bit rates. (COBRA Research Institute, NL) We demonstrate an optical label-switched add-drop node with Terabit/s channels W.4.P1.SC5.56 Achievable Information Rates Estimation for 100-nm Raman-Amplified Opti- and sub-microsecond switching for data center interconnect metro networks. Experi- cal Transmission System ments show excellent scalability with limited performance degradation up to 15 nodes Nikita A. Shevchenko (University College London, UK); Tianhua Xu (Optical Networks and 2.688 Tb/s capacity. Group, University College London, UK); Daniel Semrau, Gabriel Saavedra, Gabriele Liga, Milen Paskov, Lídia Galdino, Alex Alvarado, Robert I Killey and Polina Bayvel (University College London, UK) The achievable information rates of optical communication system using ultra-wide SC 5 - Point-to-Point Transmission Systems bandwidth 100-nm distributed Raman amplification have been investigated for each individual sub-channels, based on the first-order perturbative analysis of nonlinear distortions. W.4.P1.SC5.46 Cascadability Investigation of High Granular Optical Channel Defragmenta- W.4.P1.SC5.57 Seed Lightwave Distribution over 1600 km for 64QAM-based Coherent WDM tion Node for Flexible Optical Networks Optical Networks with Low DSP-complexity Satoshi Shimizu (National Institute of Information and Communications Technology, Jun Sakaguchi, Yoshinari Awaji (National Institute of Information and Communications JP); Gabriella Cincotti (University Roma Tre, IT); Naoya Wada (NICT, JP) Technology (NICT), JP); Naoya Wada (NICT, JP) Two different node configurations are testes: no-guard-interval (No-GI) and in- Seed lightwave distribution eliminates degradation of coherent signals by phase ter-band guard-interval (IB-GI) configuration. The bit-error-rate of No-GI exceeds 10^- noise and frequency offset. Seed lightwave was distributed over 1600 km, which 3 after 8-hop, whereas 16-hop was achieved in IB-GI configuration with BER~10^-3, amounts to factor five or ten improvement from previous results, while maintaining owing to the elimination of tight filtering. sufficient quality for DP-64QAM transmission. W.4.P1.SC5.47 Inter-Island Demonstration of an FSO High Speed Laser Ethernet Transceiver W.4.P1.SC5.58 Effect of Statistical Variations in the Response of Cascaded ROADMs on 100 for Telerobotic Space-Surface Control Gb/s DP QPSK System Performance Amita Shrestha, Julio César Ramírez Molina, Dirk Giggenbach and Jorge Pache- John C Cartledge and Clay Doggart (Queen‘s University, CA); Maurice O‘Sullivan, co-Labrador , Christopher Schmidt (German Aerospace Center (DLR), DE) Charles Laperle, Andrzej Borowiec and Kim Roberts (Ciena Corporation, CA) This paper presents the experimental results of 100Mbps Laser Ethernet Transceiv- Using a real-time transceiver, the performance implications of passband im- ers for high-speed communications in a 142 Km free-space optical inter-island link. pairments and bandwidth narrowing resulting from the cascading of ROADMs are Round-trip times below 1.6 ms and error free transmission at full throughput during assessed using a programmable optical filter and variable bandwidth optical filter to several time intervals were demonstrated. emulate the overall response. W.4.P1.SC5.48 Quantum-limited Measurements of Signals from Geostationary Earth Orbit W.4.P1.SC5.59 Real-time 70 Gbit/s, 128 QAM Quantum Noise Stream Cipher Transmission Dominique Elser, Kevin Günthner, Imran Khan, Birgit Stiller, Ömer Bayraktar and over 100 km with Secret Keys Delivered by Continuous Variable Quantum Christian Müller (Max Planck Institute for the Science of Light, DE); Karen Saucke, Key Distribution System Daniel Troendle, Frank F Heine, Stefan Seel, Peter Greulich and Herwig Zech (Tesat Masataka Nakazawa, Masato Yoshida, Toshihiko Hirooka and Keisuke Kasai (Tohoku Spacecom, DE); Bjorn Guetlich, Ines Richter and Rolf Meyer (DLR, DE); Christoph University, JP); Takuya Hirano (Gakushuin University, JP) Marquardt (Max Planck Institute for the Science of Light, DE); Gerd Leuchs (University We demonstrate a real-time quantum noise stream cipher transmission with a Erlangen-Nuremberg, DE) continuous variable quantum key distribution system to greatly increase encryption Quantum key distribution (QKD) has been implemented in metropolitan area net- security. 70 Gbit/s, 128 QAM encrypted data have been successfully transmitted over works around the world. Optical satellite communication is seen as suitable to provide 100 km. the missing long-haul interconnections. We validate this approach by quantum measurements of optical signals from space. W.4.P1.SC5.60 Experimental Investigation of the Impact of Distributed Link PDL on a Coher- ent Transmission System W.4.P1.SC5.49 Single-channel 5.12 Tbit/s (1.28 Tbaud) DQPSK Transmission over 300 km Hou-Man Chin (Orange Polska & University College London, PL); Douglas W Charlton Using Non-coherent Nyquist Pulses (Ciena Corperation, CA); Andrzej Borowiec, Charles Laperle, Michael Reimer and Daiki Suzuki, Koudai Harako, Toshihiko Hirooka and Masataka Nakazawa (Tohoku Maurice O‘Sullivan (Ciena Corporation, CA); Seb J Savory (University of Cambridge, University, JP) UK) We demonstrate a single-channel 5.12-Tbit/s, 300-km transmission using non-co- We experimentally investigate the impact of distributed PDL in a 35 Gbaud PM- herent Nyquist pulses with polarization-multiplexed DQPSK at 1.28 Tbaud. Despite QPSK optical coherent transmission system implemented by commercially available this ultrahigh baud rate, we achieved a record distance at 5.12 Tbit/s thanks to the transceivers over 800 km dispersion uncompensated SMF. 60,000 random instances high PMD tolerance of the Nyquist pulse. of distributed link PDL were realized for performance measurements. W.4.P1.SC5.50 56 Gb/s 20-km Transmission of PAM-4 Signal Employing an EML in C-band without in-line Chromatic Dispersion Compensation Fotini Karinou, Nebojsa Stojanovic and Cristian Prodaniuc (Huawei Technologies Duesseldorf GmbH, DE) We experimentally demonstrate 56 Gb/s PAM-4 transmission using a 1.55-μm EML over a 20-km SMF maximum reported distance without employing DCFs in the link, for low-cost metro and short-reach WDM applications. Performance is optimized and compared for various DSP schemes 48 Poster Session I Wednesday, September 21, 2016 • 16:00 - 17:30 SC 6 - Core, Metro and Data Center Networks W.4.P1.SC7.70 Experimental Demonstration of 25/30/40-Gb/s Flexible-PON Downstream Transmission by Using Pre-Compensated DMT with Adaptive Modulation/ Bandwidth and 10G EML/APD W.4.P1.SC6.61 Filterless Networks Based on Optical White Boxes and SDM Minghui Tao (Advanced Access Network Research Center, Huawei Technologies, Ajmal Muhammad (Royal Institute of Technology (KTH), Stockholm & Linköping Uni- Wuhan, PRC); Huaiyu Zeng (Futurewei Technologies, USA); Lei Zhou (Huawei Tech- versity, SE); Marija Furdek (KTH Royal Institute of Technology, SE); Georgios Zervas nologies & Advanced Access Network Research D, PRC); Shuchang Yao (Huawei (University of Bristol, UK); Lena Wosinska (KTH Royal Institute of Technology, SE) Technologies, PRC); Shengping Li (Huawei Technologies Co., Ltd., PRC); Xiang Liu We propose an agile and programmable multicore fiber (MCF)-based filterless (Futurewei Technologies, USA) network that exploits the flexibility offered by spatial domain multiplexing and We demonstrate the downstream transmission of a flexible-PON at 25/30/40-Gb/s programmable optical switches to eliminate the waste of spectrum due to unfiltered data rates by using low-cost 10G EML/APD and pre-compensated variable-band- transmission. width DMT with 8/16-QAM subcarrier formats, respectively achieving -24/-22/- 15.5dBm receiver sensitivities at BER=10-3 after 20-km SSMF transmission in the W.4.P1.SC6.62 Experimental Assessment of Seamless Interconnection of OPS and EPS C-band. Networks with IP Addressing and Routing Control Sugang Xu, Kenji Fujikawa, Hideaki Furukawa, Hiroaki Harai, Yoshinari Awaji and W.4.P1.SC7.71 Demonstration of NG-PON2 Coexisting with Other Systems on Same ODN by Naoya Wada (National Institute of Information and Communications Technology Using WDM filter with Low Power Penalty of under 1.0 dB (NICT), JP) Yuki Sakaue (NTT Corporation, JP); Katsuhisa Taguchi (NTT, JP); Kazutaka Hara (NTT We demonstrate the OPS network which is empowered with the fully distributed Access Network Service Systems Laboratories, JP); Toshiaki Shitaba and Tomohiro and automated control capabilities of IP addressing and routing. Seamless intercon- Taniguchi (NTT Corporation, JP); Susumu Nishihara and Kota Asaka (NTT Access nection of OPS and EPS networks is achieved with the IP-layer protocols HANA/ Network Service Systems Laboratories, JP); Ken-Ichi Suzuki, Akihiro Otaka (NTT HQLIP as the unified C-Plane mechanism. Corporation, JP) We demonstrate the coexistence of TWDM-PON, GE/10G-EPONs, and video W.4.P1.SC6.63 Optical Networking Utilizing Virtual Direct Links service system on the same ODN by using a WDM-filter based coexistence element. Yusaku Ito, Yojiro Mori and Hiroshi Hasegawa (Nagoya University, JP); Ken-Ichi Sato Thanks to a sufficient isolation at the filter, a power penalty of <1.0dB in all PONs is (School of Engineering - Nagoya University, JP) achieved. We propose efficient optical networking technology employing virtual direct links that offer coarse/fine hybrid granular routing. We compare the effectiveness of the W.4.P1.SC7.72 190-Gb/s CPRI-Equivalent Rate Fiber-Wireless Mobile Fronthaul for Simulta- proposal to different networking technologies that employ coarse granular routing. neous Transmission of LTE-A and F-OFDM Signals Tien Dat Pham, Atsushi Kanno and Naokatsu Yamamoto (National Institute of Infor- W.4.P1.SC6.64 Passive Optical Metro Network based on NG-PON2 with Sharing Burst-mode mation and Communications Technology, JP); Tetsuya Kawanishi (Waseda University Receiver between Continuous-mode and Burst-mode Transmitters to Sup- & National Institute of Information and Communications Technology, JP) port Cloud Edges We propose an efficient, flexible fiber-wireless mobile fronthaul for simultaneous Kyota Hattori and Masahiro Nakagawa (NTT Corporation, JP); Toshiya Matsuda (NTT, transmission of different RATs. We successfully transmit 2×20-MHz LTE-A and JP); Masaru Katayama (NTT Network Service Systems Labs, JP); Katsutoshi Koda 4×800-MHz F-OFDM signals with a CPRI-equivalent data rate of 190 Gb/s over a (NTT, JP) converged 20-km fiber and 1-m 90 GHz. We propose a future metro network architecture based on NG-PON2 to achieve high-reliability and cost-effectiveness for the VM migration of cloud edges. Experimen- W.4.P1.SC7.73 Experimental Optimization of DSP-Aggregated Front-hauling Transmission tal results showed the feasibility of reducing the number of receivers and unavailability for up to 4x96 LTE radio waveforms could be reduced by half. Stefano Straullu and Silvio Abrate (Istituto Superiore Mario Boella, IT); Roberto Gaudi- no and Mengesha Befekadu (Politecnico di Torino, IT) W.4.P1.SC6.65 Spectrum sharing for elastic transmission parameter adaptation In this paper we demonstrate the transmission of up to 384 LTE channels with the Nicola Sambo (Scuola Superiore Sant‘Anna, IT); Kostas Christodoulopoulos (Univer- DSP-based channel aggregation, for fronthauling applications, over a conventional sity of Patras, Greece); Piero Castoldi (Scuola Superiore Sant‘Anna, IT); Emmanouel PON infrastructure. An analysis on the impact of the optical link on the EVM is shown. Varvarigos (University of Patras & Computer Technology Institute, Greece) We propose spectrum sharing between different service classes: part of spectrum W.4.P1.SC7.74 10 Gbit/s Phase Time Diversity Directly Modulated DFB with Single-PD used by low-priority traffic can be reconfigured and used by high-priority traffic, Intradyne Receiver for Coherent WDM-PON enabling adaptation to more robust transmission. Even 70% of high-priority traffic is Ivan Cano, Juan Camilo Velásquez Micolta, Victor Polo and Josep Prat (Universitat recovered from soft-failures without rerouting. Politècnica de Catalunya, ES) A 10 Gbit/s directly modulated DFB laser with phase diversity in time is experimen- tally tested with polarization independent intradyne detection. Rx sensitivity of -34 W.4.P1.SC6.66 Methods of Designing Green Optical Networks with Parallel Integration of dBm at BER=10e-3 is achieved in a 40 GHz channel spaced WDM-PON. Optical Components Onur Turkcu, Abishek Gopalan, Biao Lu, Abhijit Chitambar, Pravin Mahajan and W.4.P1.SC7.75 Transmission Experiment of LTE Signals by IF-over-Fiber Using Commercial Parthiban Kandappan (Infinera, USA) Base Station and Deployed Optical Fibers We study the effects of network designs using Discrete and Integrated models into Byung Gon Kim (KAIST(Korea Advanced Institute of Science and Technology), KR); network energy consumption. We evaluate both models on three different network Kazuki Tanaka, Takashi Kobayashi, Abdelmoula Bekkali (KDDI R&D Laboratories architectures with optical and/or digital switching capabilities. We demonstrate the Inc., JP); Kosuke Nishimura (KDDI R&D Laboratories Inc. & Optical Access Network power efficiency of the Hybrid architecture. Laboratory, JP); Hoon Kim (KAIST, KR); Masatoshi Suzuki (KDDI R&D Laboratories, JP); Yun Chur Chung (KAIST, KR) W.4.P1.SC6.67 Techno-Economic Evaluation of Optical Transport Network in Metropolitan We experimentally verify the practicality of the IF-over-Fiber (IFoF) transmission Deployments scheme by using commercial base stations and deployed optical fibers. No significant Tamara Jiménez (University of Valladolid, ES); Victor Lopez (Telefonica, ES); Felipe degradation is observed under this realistic condition similar to commercial LTE Jiménez, Oscar González de Dios, Juan P. Fernández-Palacios (Telefónica I+D, ES) systems. Optical Transport Network (OTN) technology provides multiple benefits to the network operator in backbone networks. This paper presents a techno-economic W.4.P1.SC7.76 A Techno-Economic Outlook to Optical-Interface Requirements for comparison of optical solutions for metropolitan scenarios to assess when OTN must Midhauling of 5G Small Cells be deployed. Francesco Musumeci (Politecnico di Milano, IT); Massimo Tornatore (Politecnico di Milano & University of California, Davis, IT); Achille Pattavina (Politecnico di Milano, IT) We estimate the amount of optical interfaces to support fronthaul of Small Cells under aggressive 5G traffic forecasts, considering different functional splits (midhaul) and cell configurations. Cost of interfaces can be minimized by properly selecting SC 7 - Access, Local Area and Home Networks functional split and radio configuration. W.4.P1.SC7.77 Flexible 2/4-PAM-Modulation 25-Gb/s PON for Next Generation Access W.4.P1.SC7.68 10-Gbaud OOK / PAM4 Digital Mobile Fronthaul based on One-Bit / Two-bit Network Delta-Sigma Modulation Supporting Carrier Aggregation of 32 LTE-A Signals Jianhe Gao and Huafeng Lin (Huawei Technologies, PRC); Xiang Liu (Futurewei with up to 256 and 1024QAM Technologies, USA); Xuming Wu (Huawei Technologies, PRC); Lei Zhou (Huawei Jing Wang (Georgia Institute of Technology, USA); Zhenhua Yu (Texas Instruments, Technologies & Advanced Access Network Research D, PRC); Shuchang Yao (Hua- USA); Kai Ying, Junwen Zhang, Feng Lu, Mu Xu, Lin Cheng and Xiaoli Ma (Georgia wei Technologies, PRC) Institute of Technology, USA); Gee-Kung Chang (Georgia Tech, USA) A novel low-cost 2/4-PAM dual-mode 25-Gb/s PON is proposed based on 10-Gbaud OOK/PAM4 digital mobile fronthaul was experimentally demonstrated by commercial 10-Gb/s TOSA/ROSA. By introducing the rate-detector, dual-modes using one-bit/two-bit delta-sigma modulation supporting 32 LTE-A carrier aggregation with different DSP algorithms could adaptively work. This scheme could meet the for 3GPP release 13 with up to 256 and 1024QAM. Compared with CPRI, the mobile requirements of different ODNs. fronthaul capacity is increased by 4 times. W.4.P1.SC7.78 Improving the CoMP Performance through Wavelength Reconfiguration in W.4.P1.SC7.69 Analysis of Performance Degradations Induced by Multipath Interferences in Cloud Radio and Optical Access Networks RoF-based Mobile Fronthaul Network Implemented by Using Directly Modu- Jiawei Zhang, Ji Yuefeng, Songhao Jia, Hui Li, Xiaosong Yu, Yongli Zhao and Jie lated Lasers Zhang (Beijing University of Posts and Telecommunications, PRC) Byung Gon Kim (KAIST(Korea Advanced Institute of Science and Technology), KR); A minimum-cut graph based wavelength reconfiguration scheme (MCG-WR) is Hoon Kim (KAIST, KR); Kazuki Tanaka, Takashi Kobayashi, (KDDI R&D Laboratories, proposed to improve coordinated multipoint (CoMP) performance in a TWDM-PON JP); Kosuke Nishimura (KDDI R&D Laboratories Inc. & Optical Access Network Labo- based cloud radio access network. Simulation results show that MCG-WR can effec- ratory, JP); Masatoshi Suzuki (KDDI R&D Laboratories, JP); Yun C. Chung (KAIST, KR) tively reduce the inter-BBU CoMP traffic through dynamic wavelength reconfiguration. We investigate the effects of multipath interferences on the performance of a radio-over-fiber-based mobile fronthaul network using directly modulated lasers. Our theoretical model obtained without using the quasi-static approximation agrees well with the measured data. 49 Technical Programme Thursay, September 22, 2016 • 09:00 - 10:30 Th.1.A: Room 18+19 Th.1.B: Room 17 Th.1.C: Room 16 Nonlinear MitigationSC5 Multiplexing andSC2 Switching Devices Pulse AmplitudeSC4 Modulation II Chair: Rob Smets (SURFnet, NL) Chair: Takuo Tanemura (University of Tokyo, JP) Chair: Xin Yin (Ghent University - IMEC, BE) Th.1.A.1 • 09:00 Tutorial Th.1.B.1 • 09:00 Th.1.C.1 • 09:00 Mitigation of Nonlinear Propagation Impairments by Digital Wavelength Selective Switch for Commercial Multimode Experimental Demonstration of 56 Gbit/s PAM-4 over 15 Signal Processing Fiber Supporting 576 Spatial C hannel km and 84 Gbit/s PAM-4 over 1 km SSMF at 1525 nm using Takeshi Hoshida (Fujitsu Laboratories Ltd., JP) Haoshuo Chen, Nicolas K Fontaine, Roland Ryf, Bin Huang and a 25G VCSEL Various digital signal processing algorithms have been studied Amado Velázquez-Benítez (Nokia Bell Labs, USA); Cang Jin (Uni- Nicklas Eiselt (Technical University of Denmark, DK); Helmut Griesser in order to offset the nonlinear Shannon limit dominated by the versité Laval & COPL, CA); Burcu Ercan (UC Davis, USA); David (ADVA Optical Networking SE, DE); Jinlong Wei (ADVA Optical optical Kerr effect. This tutorial attempts to overview the operation Neilson (Bell Labs, USA) Networking SE); Annika Dochhan (ADVA Optical Networking SE, principles, implementation challenges and achievement, and We demonstrate a 1 x 16 wavelength selective switch with DE); Robert Hohenleitner (Vertilas GmbH, DE); Markus Ortsiefer future outlook on those techniques. commercial multimode fibers (OM3) supporting 36 spatial modes. (VERTILAS GmbH, c/o GATE Garching, DE); Michael Eiselt (ADVA, It provides a switch throughput of 576 spatial channels with a DE); Christian Neumeyr (VERTILAS, GmbH, DE); Juan Jose Vegas mode-dependent loss below 5.5 dB. Olmos (Technical University of Denmark, DK); Idelfonso Tafur Monroy (Technical University of Denmark, Denmark & ITMO University, RU) Record 28-GBd PAM-4 transmission over 15 km SSMF and 42-GBd PAM-4 over 1 km SSMF using a low-power 25G VCSEL are demonstrated at 1525 nm without optical dispersion compen- sation and only simple transceiver DSPs. Th.1.B.2 • 09:15 Th.1.C.2 • 09:15 Waveguide-Frontend with Integrated Polarization Diversity Single Lane 150-Gb/s, 100-Gb/s and 70-Gb/s 4-PAM Trans- Optics for Wavelength Selective Switch Array mission over 100-m, 300-m and 500-m MMF Using 25-G Hiroshi Kudo, Yuichiro Ikuma, Kota Shikama, Yohei Sakamaki and Class 850nm VCSEL Mitsumasa Nakajima (NTT Corporation, JP); Keita Yamaguchi (NTT Tianjian Zuo, Liang Zhang and Jie Zhou (Huawei, PRC); Qiang Corporation & NTT Device Technology Labs, JP); Kazunori Seno Zhang (Huawei Technologies Duesseldorf GmbH, DE); Enbo Zhou (NTT Corporation, JP); Kenya Suzuki (NTT Device Technology and Gordon Ning Liu (Huawei Technologies Co. Ltd., PRC) Laboratories, NTT Corporation, JP); Mikitaka Itoh (NTT Photonics We experimentally demonstrated a record transmission with Laboratories, JP); Toshikazu Hashimoto (NTT Corporation, JP) bit-rates of 150-Gb/s, 100-Gb/s and 70-Gb/s over 100-m, 300-m We propose a waveguide-frontend with integrated polarization and 500-m MMFs. More than 2-dB performance gain has been diversity optics for a wavelength selective switch (WSS) with a observed employing a 13-level duobinary 4-PAM format for spatial and planar optical circuit. We demonstrate a 2-in-1 1×20 bandwidth limited system. WSS and confirmed operation with a polarization dependent loss of <0.43 dB. Th.1.B.3 • 09:30 Th.1.C.3 • 09:30 Invited Compact Silicon Photonic Interleaver Using an Interfering High-Speed VCSELs for Datacom Loop Containing a Fabry-Perot Cavity Formed by Sagnac Anders Larsson and Johan Gustavsson (Chalmers University of Loop Mirrors Technology, SE); Petter Westbergh (Finisar, USA); Erik Haglund, Xinhong Jiang, Yuxing Yang, Boyu Liu, Yong Zhang, Ciyuan Qiu Emanuel Haglund and Ewa Simpanen (Chalmers University of and Yikai Su (Shanghai Jiao Tong University, PRC) Technology, SE) A compact (106.4 × 55.1 μm2) silicon photonic interleaver is VCSEL-MMF is the dominating technology for short-reach opti- proposed and experimentally demonstrated. The 3-dB and 20-dB cal interconnects in datacenters and high performance computing bandwidths of the passband are ~1.09 nm and ~1.585 nm, systems at current serial rates of up to 25-28 Gb/s. This is likely respectively. The central wavelength can be changed by tuning to continue at 50-56 Gb/s. The technology shows potential for only one waveguide. 100 Gb/s. Th.1.B.4 • 09:45 Ultra-compact and Highly Efficient Polarization Splitter and Rotator Based on a Silicon Bent Directional Coupler Yong Zhang, Yu He, Xinhong Jiang, Boyu Liu, Ciyuan Qiu and Yikai Su (Shanghai Jiao Tong University, PRC) An ultra-compact (coupling length ~ 8.77 micrometer) silicon polarization splitter and rotator is demonstrated based on a bent directional-coupler. The peak TM-TE coupling efficiency reaches 96.6%. The crosstalk values are < -10 dB over a wavelength range of 40 nm. Th.1.A.2 • 10:00 Th.1.B.5 • 10:00 Invited Th.1.C.4 • 10:00 Experimental Demonstration of Modulation-Dependent Ultrafast laser inscription of 3D waveguides for SDM 56 Gb/s PAM-4 Driver IC for Long-Wavelength VCSEL Nonlinear Interference in Optical Fibre Communication applications Transmitters Lídia Galdino, Gabriele Liga and Gabriel Saavedra (University Robert R. Thomson (Heriot Watt University, UK) Wouter Soenen (Ghent University & iMinds-imec, BE); Renato College London, UK); David Ives (University of Cambridge, UK); I will present the work that has been conducted on the applica- Vaernewyck (Ghent University, BE); Xin Yin (Ghent University - Robert Maher and Alex Alvarado (University College London, UK); tion of ultrafast laser inscription to the fabrication of three-dimen- IMEC, BE); Silvia Spiga (Walter Schottky Institut, Technical Univer- Seb J Savory (University of Cambridge, UK); Robert I Killey and sional components, such as 3D fan-outs and photonic lanterns, sity of Munich, DE); Markus-Christian Amann (Technical University Polina Bayvel (University College London, UK) for future applications in space division multiplexing (SDM). of Munich, DE); Geert Van Steenberge (Ghent University - IMEC, For the first time the modulation format dependence of BE); Elad Mentovich (Mellanox Technologies, IL); Paraskevas nonlinear interference in long-haul optical fibre transmission is Bakopoulos (National Technical University of Athens, GR); Johan experimentally demonstrated for polarisation-division multiplexed Bauwelinck (Ghent University - iMinds, BE) 4, 16, 64 and 256-QAM. We present the first 56 Gb/s PAM-4 driver IC, developed in 130 nm SiGe BiCMOS, for long-wavelength VCSEL transmitters. Efficiency of the integrated 4-tap FFE driving a state-of-the-art 1.5 um VCSEL is verified, showing back-to-back BER below 1E-6. Th.1.A.3 • 10:15 Th.1.C.5 • 10:15 Dispersion Map Optimization for Nonlinearity Mitigation in 100 Gbps PAM-4 Transmission over 100m OM4 and Wide- Two-Span Phase-Sensitive Amplifier Links band Fiber using 850nm VCSELs Egon Astra (Tallinn University of Technology, EST); Samuel L. I. Justin Lavrencik, Siddharth J Varughese, Varghese A. Thomas Olsson and Henrik Eliasson (Chalmers University of Technology, (Georgia Institute of Technology, USA); Gary Landry (Finisar Corp, SE); Taavi Laadung (Tallinn University of Technology, EST); Peter A USA); Yi Sun, Roman Shubochkin and Kasyapa Balemarthy, Andrekson (Chalmers University of Technology, SE) Balemarthy (OFS, USA); Jim Tatum (Finisar Corp, USA); Stephen The first investigation of dispersion map optimization in two- Ralph (Georgia Institute of Technology, USA) span PSA-amplified links is presented. We show numerically and We experimentally demonstrate 100 Gbps PAM-4 transmission experimentally, that the nonlinearity mitigation improves by 1.4dB over 105m of OM4 and wideband MMF fibers. The 107Gbps if different dispersion maps are applied in each span, compared line rates allow 100Gbps user rates with FEC. The link included to single-span optimized maps. unpackaged 850nm VCSELs designed for 25G operation and offline equalization and decoding. 10:30 - 11:00 Coffee Break | Foyer CCD | 11:00 - 12:30 Th.2.P: Poster Session II 12:30 - 14:00 Lunch Break 14:00 - 14:30 Post Deadline Paper Sessions 15:30 - 16:00 Awards and Closing Ceremony | Room 1 | 50 Technical Programme Thursay, September 22, 2016 • 09:00 - 10:30 Th.1.D: Room 15 Th.1.E: Room 112 Auxiliary Managementand Control Channel Elastic Optical Networks II TechnologiesSC7 for Mobile Fronthaul SC6 Chair: Kota Asaka (NTT Access Network Service Chair: Dimitra Simeonidou (University of Bristol, Systems Laboratories, JP) UK) Th.1.D.1 • 09:00 Th.1.E.1 • 09:00 Invited Experimental Investigation of an Optically-superimposed Can Metro Networks Be the Next Playground for (True) AMCC in 100 Gb/s Coherent WDM-PON for 5G Mobile Elastic Networks Fronthaul Patricia Layec, Arnaud Dupas, Dominique G. Verchere and Satoshi Yoshima, Takaaki Katsumata, Hiroshi Miura, Yuita Nogu- Sebastien Bigo (Nokia Bell-Labs, FR); chi, Akiko Nagasawa, Naoki Suzuki and Masaki Noda (Mitsubishi We review elastic optical networks experiments and associated Electric Corporation, JP) use cases. Metro networks are particularly well-suited to the We experimentally demonstrated a 100 Gb/s coherent introduction of some level of dynamics in the optical networks, WDM-PON for 5G mobile fronthaul controlled by an AMCC super- leveraging elastic building blocks such as transponders and imposed on the DP-QPSK signal. The required receiver sensitivity optical nodes. of -26dBm was achieved when the modulation index was set to between 5% and 40%. Th.1.D.2 • 09:15 Experimental Investigation of AMCC Superimposition Im- pact on CPRI Signal Transmission in DWDM-PON Network Goji Nakagawa and Kyosuke Sone (Fujitsu Ltd., JP); Shoichiro Oda and Setsuo Yoshida (Fujitsu Laboratories Ltd.); Yasuhiko Aoki and Motoyuki Takizawa (Fujitsu Ltd., JP); Jens C. Rasmussen (Fujitsu Laboratories Ltd., JP) We have investigated and clarified the impact of AMCC super- imposition on CPRI signal transmission, and confirmed that the impact of message channel was negligibly small for CPRI option 8 client signal. We demonstrated AMCC signal detection with DWDM-PON network. Th.1.D.3 • 09:30 Th.1.E.2 • 09:30 Low-frequency Pilot Tone Management for WDM-PON Demonstration of Bandwidth Maximization between Flexi/ toward Future Mobile Fronthaul employing 64B/66B Line Fixed Grid Optical Networks with Real-Time BVTs Coding Shuangyi Yan, Emilio Hugues-Salas, Ali Hammad, Yan Yan, Kazuaki Honda (NTT Corporation, JP); Takayuki Kobayashi (NTT, George M. Saridis, Sarvesh Sanjay Bidkar, Reza Nejabati and JP); Susumu Nishihara (NTT Access Network Service Systems Dimitra Simeonidou (University of Bristol, UK); Arnaud Dupas and Laboratories, JP); Tatsuya Shimada (NTT, JP); Jun Terada and Patricia Layec (Nokia Bell Labs, FR) Akihiro Otaka (NTT Corporation, JP) Real-Time SDN-based BVT enables baud-rate tunability to Low frequency embedded pilot tone can provide protocol-free combat the filtering effect of the legacy filters for interoperability management channels for WDM-PON-based mobile fronthaul between fixed-grid/flexigrid. Based on the passed filters and systems. Experiments show modulation index control enables link-distance, SDN controller configures BVTs to maximize the 128 kb/s pilot tones to be inserted into 64B/66B-line-coded CPRI link capacity. option 8 signals, which have a low frequency component. Th.1.D.4 • 09:45 Th.1.E.3 • 09:45 Experimental Real Time AMCC Implementation for Spectral-Efficiency Maximization with Subcarrier-Multi- Fronthaul in PtP WDM-PON plexed Hybrid-QAM Signals Adaptive to Distance and Hop Zakaria Tayq, Luiz Anet Neto and Philippe Chanclou (Orange Count Labs, FR); Christelle Aupetit-Berthelemot (XLIM - University of YYuma Isono, Masaki Niwa, Yojiro Mori and Hiroshi Hasegawa Limoges, FR) (Nagoya University, JP); Ken-Ichi Sato (School of Engineering - A real-time pilot tone implementation allowing fronthaul moni- Nagoya University, JP) toring and wavelength tunability in WDM-PON systems is exper- We propose a novel spectral efficiency maximization method imentally demonstrated. The obtained results show transmission adaptive to distance and hop count for subcarrier-multiplexed of a 128 kb/s control signal with minor impact on CPRI. hybrid-QAM signals. Simulation results show that the proposed scheme substantially improves spectral efficiency in all the net- works topologies tested. Th.1.D.5 • 10:00 Th.1.E.4 • 10:00 Experimental Demonstration of Accommodation of Energy Efficiency of General-Purpose Systems Employing TDD-based Mobile Fronthaul and Secondary Services in a Virtualization Concepts in Operator Networks TDM-PON Christoph Lange and Dirk Kosiankowski (Deutsche Telekom AG, Daisuke Hisano and Takayuki Kobayashi (NTT, JP); Hiroshi Ou DE); Michael Schlosser (Berlin Institute for Software Defined (NTT Corporation, JP); Tatsuya Shimada (NTT, JP); Jun Terada Networks, DE); Andreas Gladisch (Deutsche Telekom AG & and Akihiro Otaka (NTT Corporation, JP) Innovation Labs, DE) We experimentally demonstrate a novel bandwidth allocation The energy efficiency of purpose-built and virtualization-aided scheme using a TDD frame monitor. We confirm that the average general-purpose telecom equipment is compared based on pow- throughput of the secondary system is increased over ninefold er measurements, traffic observations and network modelling. The and a mobile fronthaul is transmitted with a less than 50 μs results show improved energy efficiency of software realizations latency. based on general-purpose systems originating from finer-granular capacity provisioning. Th.1.D.6 • 10:15 Th.1.E.5 • 10:15 Dynamic Resource Sharing for C-RANs with Joint Orches- Software Defined Contention in Wavelength Cross- tration of Radio and Transport Connects Muhammad Rehan Raza and Matteo Fiorani (KTH Royal Institute Thierry Zami (Nokia, FR); Colin Kelly (Nokia, CA) of Technology, SE); Ahmad Rostami (Ericsson Research, SE); We assess the paradoxical benefit of lightly degrading by Björn Skubic and Peter Öhlen (Ericsson AB, SE); Lena Wosinska software restriction the blocking ratio of an initially contention- and Paolo Monti (KTH Royal Institute of Technology, SE) less add/drop stage in a wavelength routing cross-connect, to We present a resource allocation strategy for centralized maximize its capacity and keep as much as possible efficient radio access network architectures able to adapt to the wireless transponders and internal amplification network capacity requirements. Both simulation and emulation results show that it is possible to reuse up to 33.3% of the transport resources. 10:30 - 11:00 Coffee Break | Foyer CCD | 11:00 - 12:30 Th.2.P: Poster Session II 12:30 - 14:00 Lunch Break 14:00 - 14:30 Post Deadline Papers Sessions 15:30 - 16:00 Awards and Closing Ceremony | Room 1 | 51 Poster Session II Thursday, September 22, 2016 • 11:00 - 12:30 SC 1 - Fibres, Fibre Devices and Fibre Amplifiers Th.2.P2.SC2.11 Experimental Study of Phase and Intensity Noise in a Monolithically Integrated DFB Laser IQ Modulator PIC at QPSK operation Sophie Lange, Ronald Kaiser, Marko Gruner, Martin Schell (Fraunhofer Institute for Th.2.P2.SC1.1 Demonstration of an Ultra-Flat Raman-Enhanced Fibre Optical Parametric Telecommunications, Heinrich-Hertz-Institut, DE) Amplifier (FOPA) with >110nm Gain-Bandwidth Phase noise in monolithic optical laser-modulator PICs influences QPSK perfor- Vladimir Gordienko and Marc Stephens (Aston University, UK); Shigehiro Takasaka mance depending on laser bias current and internal optical feedback. The phase (Furukawa Electric co., Ltd., JP); Atalla El-Taher, Ian Phillips and Wladek Forysiak noise was most significant at lower symbol rates and minimized at high symbol rates (Aston University, UK); Ryuichi Sugizaki (Furukawa Electric co., Ltd., JP); Nick Doran at selected bias points. (Aston University, UK) We demonstrate a Raman-enhanced FOPA achieving record unfiltered gain vari- Th.2.P2.SC2.12 Emission Beam Engineering of 1.3-μm High-power DFB Laser Using ation of only ±0.5dB over 111nm bandwidth and 9.6dB gain. We amplify a 60Gb/s Monolithically-integrated Mirror and Lens for Silicon Photonics QPSK signal error-free across the L-band with maximum Q2 penalty of 0.9±0.3dB. Koichiro Adachi, Takanori Suzuki, Kouji Nakahara, Akira Nakanishi, Kazuhiko Naoe and Shigehisa Tanaka (Oclaro Japan, Inc., JP) Th.2.P2.SC1.2 Millimeter-Resolution Long Range Optical Frequency Domain Reflectometry A beam-angle control of 1.3-μm high-power DFB laser without mode-profile for Health Monitoring of Access Network degradation was demonstrated using monolithically-integrated mirror and lens. By Bin Wang, Xinyu Fan, Guangyao Yang, Qingwen Liu and Zuyuan He (Shanghai Jiao tuning the mirror angle and lens position, wide-range angled beam (up to 20º) without Tong University, PRC) degradation in mode profile was successfully achieved. We greatly improve the performance of optical frequency domain reflectometry by using high-order sideband modulation and injection-locking technique. A spatial Th.2.P2.SC2.13 Optical Amplitude Modulator Linearized by Integration of Optical Interfero- resolution of 4.2 mm over 10 km measurement range is obtained, and polarization metric Waveguides beat length of 10.5 cm is measured. Yuya Yamaguchi, Atsushi Kanno, Tetsuya Kawanishi, Masayuki Izutsu and Hirochika Nakajima (Waseda University & National Institute of Information and Communications Th.2.P2.SC1.3 High-speed Dynamic Strain Measurement Based on Frequency-swept Pulsed Technology, JP) BOTDA We propose an optical amplitude modulator with tailored transfer function by Chihiro Kito, Hiroshi Takahashi and Kunihiro Toge, Tetsuya Manabe (NTT Corporation, JP) integration of Mach-Zehnder-interferometer-based waveguides. The fabricated mod- We propose a high-speed, dynamic strain measurement based on real-time ulator designed to enhance the linearity showed a unique transfer function in good Brillouin time-domain analysis of correlated gain measured with an oscilloscope. We agreement with the theoretical one. achieved the highest recorded speed of 97 kilo-points/s over 1 km fibre, which is close to the repetition limit. Th.2.P2.SC2.14 120 Gbit/s PAM-4 Signaling Using a Silicon-Organic Hybrid (SOH) Mach- Zehnder Modulator Th.2.P2.SC1.4 Experimental Evaluation of RF crosstalk in Multicore Fibers for Radio over Heiner Zwickel, Stefan Wolf, Yasar Kutuvantavida, Clemens Kieninger , Matthias fiber Applications Lauermann, Wolfgang Freude and Christian Koos (Karlsruhe Institute of Technology Jose Manuel Galve Higon, Jose Capmany and Ivana Gasulla (Universidad Politecnica (KIT), DE) de Valencia, ES); Tiago Alves (Instituto de Telecomunicações, PRT); Adolfo Cartaxo Four-level pulse amplitude modulation (PAM-4) signals are generated using a (IST-TUL, PRT); Salvador Sales (Universidad Politecnica de Valencia, ES) silicon-organic hybrid (SOH) push-pull Mach-Zehnder modulator. We demonstrate We present a simple theoretical formalism and experimental characterization of data rates (symbol rates) of 120 Gbit/s (60 GBd) with a 500 µm long device fabricated RF-crosstalk due to inter-core coupling in homogeneous Multicore Fibers. Measure- through a commercial silicon photonic foundry. ments confirm the behaviour predicted by the model. The results are relevant for the design of radio over fiber systems. Th.2.P2.SC2.15 Differential Microring Binary Phase-shift Keying Modulators Chia-Ming Chang, Guilhem de Valicourt , Sethumadhavan Chandrasekhar, Po Dong Th.2.P2.SC1.5 Dependence of Kerr Comb Linewidth and Coherent System Performance on (Nokia Bell Labs, USA) the Pump Linewidth We experimentally demonstrate a nested microring modulator in a Mach-Zehnder Peicheng Liao and Changjing Bao (University of Southern California, USA); Arne interferometer for BPSK at 10 Gbps. Differential drive of such a modulator facilitates Kordts, Karpov Maxim and Martin Pfeiffer (Ecole Polytechnique Federale de BSPK modulation and offers several advantages such as cancellation of imperfection Lausanne, CH); Lin Zhang (Tianjin University, PRC); Amirhossein Mohajerin-Ariaei, from single ring modulator. Yinwen Cao, Ahmed Almainman and Morteza Ziyadi (University of Southern California, USA); Youichi Akasaka (Fujitsu Laboratories of America, Inc., USA); Tomer Yeminy Th.2.P2.SC2.16 Femtosecond Laser Written Integrated Spatial Multiplexers for Few-Mode (Ben Gurion University, IRL); Moshe Tur (Tel-Aviv University, IRL); Tobias Kippenberg Multicore Fibre (Ecole Polytechnique Federale de Lausanne, CH); Alan Willner (University of Southern Nicolas Riesen (University of Adelaide, AU); Simon Gross (Macquarie University, AU); California, USA) John Love (The Australian National University, AU); Yusuke Sasaki (Fujikura Ltd., JP); We experimentally investigate the dependence of Kerr comb linewidth, generation Michael Withford (Macquarie University, AU) and coherent system performance on the pump linewidth. The linewidth of generated We demonstrate compact femtosecond laser written 3D spatial multiplexers for combs could be determined by the pump demonstrating the pump-limited system few-mode multicore fibre operating across the C+L bands. The integrated tapered performance of Kerr combs. mode couplers feature direct mode-selectivity, excellent mode extinction ratios (up to 25 dB) and low insertion loss (~2 dB). Th.2.P2.SC1.6 Optimizing the Curvature of Elliptical Cladding Elements to Reduce Leakage Loss in Antiresonant Hollow Core Fibres Th.2.P2.SC2.17 Ultra-efficient interleaved depletion modulators by using advanced fabrication Lieke van Putten, Eric Numkam Fokoua, Seyedmohammad Abokhamis mousavi, technology Walter Belardi and Francesco Poletti (University of Southampton, UK) Anna Lena Giesecke, Andreas Prinzen, Heiko Füser, Caroline Porschatis, Holger We study systematically the effect of the curvature of glass membranes on the Lerch, Jens Bolten, Stephan Suckow, Bartos Chmielak and Thorsten Wahlbrink (AMO confinement loss of an antiresonant negative curvature hollow core fibre. Optimum GmbH, DE) curvatures are found that can reduce the fibre loss by orders of magnitude. We fabricated highly efficient silicon photonic depletion modulators utilizing inter- digitated pn-junctions with critical dimensions <200 nm. With this concept, record Th.2.P2.SC1.7 A Crosstalk Analysis of Heterogeneous 30-Core Fibre low values <2VdB of (V_π Lα)_2V as key figure of merit for the efficiency of such Takeshi Fujisawa (Hokkaido University, JP); Yoshimichi Amma (Fujikura Ltd., PRC); modulators have been achieved. Shoichiro Matsuo and Kazuhiko Aikawa (Fujikura Ltd., JP); Kunimasa Saitoh and Masanori Koshiba (Hokkaido University, JP) Th.2.P2.SC2.18 50-GHz+ Thin-Film Polymer on Silicon Modulator for PAM4 100G-per-wave- Intercore crosstalk of heterogeneously arranged 30-core fibre having four kinds of length Long-Reach Data Center Interconnects cores is investigated. Measured crosstalk for all the combinations of cores are in good Andrea Chiuchiarelli (CPqD, BR); Sandro M. Rossi (CPqD Telecom & IT Solutions, agreement with calculated values by coupled-mode theory with single correlation BR); Valery Nobl Rozental (CPqD, Division of Optical Technologies, BR); Glauco length, assuming longitudinal random twist. Simões (CPqD, BR); Luis Carvalho, Julio Cesar Oliveira (BrPhotonics, BR); Juliano Rodrigues Fernandes de Oliveira (CPqD Foundation & University of Sao Paulo, BR); Jacklyn D. Reis (CPqD, BR) This paper demonstrates 50-GHz+ Mach-Zehnder modulator based on thin-film Polymer on Silicon platform for Data Center Interconnects. System level demonstra- SC 2 - Waveguide and Optoelectronic Devices tion is successfully carried out for 40x112 Gb/s, 56-GBd PAM4 optical channels in 100-GHz WDM grid over record 140-km link distance. Th.2.P2.SC2.8 Monolithically Integrated 40 Gbit/s Tunable Transmitter in an Experimental Th.2.P2.SC2.19 Physical Layer Compact Models for Ring Resonators based Dense WDM Generic Foundry Process for Large-Scale Integration Optical Interconnects Weiming Yao (Eindhoven University of Technology & COBRA Research Institute, NL); Sébastien Rumley, Meisam Bahadori, Dessislava Nikolova and Keren Bergman Meint K Smit (Technical University Eindhoven, NL); Michael J. Wale (Oclaro, UK) (Columbia University, USA) We present a tunable transmitter photonic integrated circuit fabricated on an Two compact models relating the coupling and attenuation coefficient of ring experimental generic III-V foundry platform, consisting of a DBR-laser with 10 nm resonators to their physical dimensions are introduced. We leverage these models to continuous tuning range, monolithically integrated with a traveling-wave Mach- delimit the capabilities of ring resonators for dense WDM optical interconnects. Zehnder modulator capable of 40 Gbit/s operation. Th.2.P2.SC2.20 Back-Reflection Free Grating Couplers on Silicon-on-Insulator Th.2.P2.SC2.9 Simultaneous Two-Wavelength Hybrid III/V-Si Laser Based on Single-Section Jeong Hwan Song and Xavier Rottenberg (IMEC, BE) Quantum Dot Gain We propose a design of novel grating couplers having low back-reflections on Michael Eggleston, Guilhem de Valicourt, Jeffrey Lee and Kwangwoong Kim (Nokia silicon-on-insulator (SOI) where grating trenches are asymmetrically etched. 3D-FDTD Bell Labs, USA); Ting-Chen Hu (Nokia Bell Labs, USA); Vitalii Sichkovskyi and Johann simulations show that the average back-reflection of 1dB bandwidth in the proposed Peter Reithmaier (University of Kassel, DE); Young-Kai Chen (Nokia Bell Labs, USA) grating coupler is -41dB. We demonstrate a novel selectable multi-wavelength hybrid III-V/Si laser using in-homogeneously broadened quantum dot gain material. Simultaneous stable lasing on two wavelengths is achieved while maintaining low RIN one order of magnitude better than previously demonstrated with mode-locked lasers. Th.2.P2.SC2.10 Ultra-broadband Integrated Four-Channel Mode-Division-Multiplexing Based on Tapered Mode-Evolution Couplers Jing Wang (Huawei Technologies Co., Ltd., PRC); Yi Xuan (Purdue University, USA); Minghao Qi (Purdue University, PRC); Lei Liu, Gordon Ning Liu (Huawei Technologies Co. Ltd., PRC) We reported an ultra-broadband integrated four-channel mode-division multiplexing (MDM) scheme based on tapered mode-evolution couplers. This MDM link exhibits a very large −1 dB bandwidth of >180 nm, which is considerably larger than most of the previously reported MDM links. 52 Poster Session II Thursday, September 22, 2016 • 11:00 - 12:30 SC 3 - Digital and Optical Signal Processing Th.2.P2.SC3.31 Comparison of Multi-Channel Nonlinear Equalization using Inverse Volterra Series versus Digital Backpropagation in 400 Gb/s Coherent Superchannel Vassiliki Vgenopoulou (Athens Information Technology, GR); M. Sezer Erkilinc and Th.2.P2.SC3.21 Nonlinear Blind Equalization for 16-QAM Coherent Optical OFDM using Robert I Killey (University College London, UK); Yves Jaouën (Telecom ParisTech, FR); Support Vector Machines Ioannis Roudas (Corning Inc., USA); Ioannis Tomkos (Athens Information Technology, Elias Giacoumidis (University of Sydney, CUDOS, IPOS, AU); Mhatli Sofien (ENIT, GR) TUN); Son Le (Aston University, UK); Ivan A Aldaya (University of Campinas, BR); We investigate the performance of a Volterra-based nonlinear equalizer and the Mary McCarthy and Andrew Ellis (Aston University, UK); Benjamin Eggleton (University digital backpropagation (DBP) method in multi-channel nonlinear equalization after of Sydney, AU) 20×80 km transmission distance. The Volterra equalizer, which operates with single- A novel blind nonlinear equalizer (BNLE) based on support vector machines is step-per-span, performs similarly compared to DBP with 40 steps-per-span experimentally demonstrated for ~41-Gb/s 16-QAM CO-OFDM at 2000 km. For 2 dBm launched optical power, BNLE reduces the fiber nonlinearity penalty by ~1 dB compared to Volterra-based NLE. Th.2.P2.SC3.32 Experimental Investigation of GF(3 2) Nonbinary LDPC-coded Non-uniform 9-QAM Modulation Format Th.2.P2.SC3.22 Machine Learning for Optical Performance Monitoring from Directly Detected Zhen Qu, Changyu Lin, Tao Liu and Ivan B. Djordjevic (University of Arizona, USA) PDM-QAM Signals A specially designed GF(3^2) nonbinary LDPC-coded non-uniform 9-quadrature Jesper Wass, Jakob Thrane, Molly Piels, Júlio C. M. Diniz and Rasmus Jones (Tech- amplitude modulation (QAM) is proposed. The experimental and numerical results nical University of Denmark, DK); Darko Zibar (DTU Fotonik, Depertment of Photonic show that the proposed scheme outperforms nonbinary GF(2^3) LDPC-coded Engineering, Technical University of Denmark, DK) uniform 8-QAM by ~0.8-dB. Supervised machine learning methods are applied and demonstrated experimental- ly for inband OSNR estimation and modulation format classification in optical commu- Th.2.P2.SC3.33 Selective wavelength conversion of multi-channel 16-QAM signal in a nication systems. The proposed methods accurately evaluate coherent signals up to graphene-silicon microring resonator 64QAM using only intensity information. Yun Long, Xiao Hu, Mengxi Ji, Li Shen and Andong Wang (Huazhong University of Science and Technology, PRC); Yi Wang (Wuhan National Laboratory for Opto- Th.2.P2.SC3.23 Experimental Investigation of Compression with Fixed-length Code Quantiza- electronics & Huazhong University of Science and Technology, PRC); Jian Wang tion for Convergent Access-Mobile Networks (Huazhong University of Science and Technology, PRC) Luiz Anet Neto, Philippe Chanclou, Zakaria Tayq and Bidossessi Charlyse Zabada By exploiting graphene-enhanced FWM in a graphene-silicon microring, we pro- (Orange Labs, FR); Fabienne Saliou and Gael Simon (Orange, FR) pose and experimentally demonstrate selective wavelength conversion of multi-chan- We experimentally assess compression with scalar and vector quantization for nel 16-QAM signal. Efficient wavelength conversion and low crosstalk are observed fixed-mobile convergent networks. We show that four-dimensional vector quantization when the channel spacing is 100 GHz and 50 GHz, respectively. allows 73% compression compliant with 3GPP EVM recommendations for transmis- sions over 25 km SSMF with 1:16 split ratio. Th.2.P2.SC3.24 Timing Jitter Impact on QAM Modulation of Frequency Combs Obtained by SC 4 - Subsystems for Optical Networking and Datacoms Cross Phase Modulation of Mode-locked Lasers Mark Pelusi (University of Sydney, AU); Karen Solis-Trapala (EFFECT Photonics, NL); Takashi Inoue (National Institute of Advanced Industrial Science and Technology, JP); Th.2.P2.SC4.34 Optical DAC for Generation of PAM4 Using Parallel Electro-Absorption Hung Nguyen Tan (Danang University of Science & Technology, VN); Shu Namiki Modulators (National Institute of Advanced Industrial Science and Technology, JP) Wan-Jou Huang and Chia-Chien Wei (National Sun Yat-Sen University, TW); Jyehong Lower noise frequency combs obtained from mode-locked semiconductor and Chen (National Chiao Tung University, TW) mode-locked fiber lasers by cross-phase modulation of output pulses in nonlinear Employing a proposed optical 2-bit DAC based on parallel EAMs, we experimen- fiber are compared. The importance of low timing jitter for enabling comb-line modu- tally demonstrated 50- and 64-Gbps optical 4-PAM signals. Compared to using an lation with 96-Gb/s-DP-16QAM and 64QAM signals is shown. electrical DAC, the optical DAC has better performance and higher tolerance to the operation conditions of modulators. Th.2.P2.SC3.25 Polarization-Mode Dispersion Aware Digital Backpropagation Cristian B. Czegledi (Chalmers University of Technology, SE); Gabriele Liga and Th.2.P2.SC4.35 Hexagonal Reconfigurable Lattice Mesh for Programmable Photonic Domanic Lavery (University College London, UK); Magnus Karlsson (Chalmers Processors University of Technology & Photonics Laboratory, SE); Erik Agrell (Chalmers University Daniel Pérez (Universidad Politécnica de Valencia, ES); Ivana Gasulla and Jose of Technology, SE); Seb J Savory (University of Cambridge, UK); Polina Bayvel (Uni- Capmany (Universidad Politecnica de Valencia, ES); Richard Soref (University of versity College London, UK) Massachusetts Boston, USA) We study a modified DBP algorithm that accounts for PMD. Based on the accu- We propose a hexagonal tuneable-coupler-based mesh design, for the implemen- mulated PMD at the receiver, the algorithm distributively compensates for PMD in the tation of reconfigurable optical cores in programmable processors. This hexagonal reverse propagation and outperforms the conventional approach by up to 2.1 dB. mesh outperforms the previously proposed square mesh topology in on-chip inte- gration metrics and performance. We provide application examples and robustness Th.2.P2.SC3.26 On the Design of Capacity-Approaching Unit-Memory Spatially Coupled simulations. LDPC Codes for Optical Communications Laurent Schmalen, Detlef Suikat, Vahid Aref and Detlef Rösener (Nokia Bell Labs, DE) Th.2.P2.SC4.36 Single-Ended In-Service Hybrid Monitoring of Fibre-Extended Copper Lines We consider unit-memory spatially coupled LDPC codes for optical communi- Gustavo Amaral, Andrea Baldivieso and Joaquim Dias Garcia (Pontifical Catholic cations. We analyze the region of wave-like convergence using an FPGA-based University of Rio de Janeiro, BR); Patryk Urban (Ericsson AB, SE); Jean Pierre von der windowed decoding emulator. We show that the post-FEC errors occur in long bursts Weid (Pontifical Catholic University of Rio de Janeiro, BR) and highlight some design guidelines. We report on the simultaneous monitoring of both fibre and copper links in a fibre-extended copper mobile fronthaul network. The monitoring signal, which is Th.2.P2.SC3.27 Hardware-efficient Precise and Flexible Soft-demapping for Multi-Dimension- allocated to an optical subcarrier channel, is used to determine both the fibre‘s and al Complementary APSK Signals copper‘s characteristics. Tsuyoshi Yoshida and Keisuke Matsuda (Mitsubishi Electric Corporation, JP); Keisuke Kojima (Mitsubishi Electric Research Laboratories, USA); Hiroshi Miura and Keisuke Th.2.P2.SC4.37 A Self-Optimizing 4-Channel 30 Gbaud/s PAM-4 Packaged Silicon Photonics Dohi (Mitsubishi Electric Corporation, JP); Milutin Pajovic and Toshiaki Koike-Akino, Subsystem with Binary Driving Signals David Millar and Kieran Parsons (Mitsubishi Electric Research Laboratories, USA); Nathan Abrams, David M Calhoun, Christine Chen and Keren Bergman (Columbia Takashi Sugihara (Mitsubishi Electric Corporation, JP) University, USA) We propose the combination of log-likelihood ratio (LLR) table and min-sum We demonstrate four channel PAM-4 modulation in a silicon-photonic platform algorithm-based LLR updates for simple, precise, and flexible soft-demapping of driven by push-pull binary electrical signals. The subsystem self-optimizes through a multi-dimensional complementary APSK signals. Transmission experiment verifies the gradient descent algorithm across the full range of starting voltages. demapping loss is limited to 0.15 dB in Q-factor. Th.2.P2.SC4.38 Overall Frequency Response Measurement of DSP-based Optical Transmitter Th.2.P2.SC3.28 Sub-Symbol-Rate Sampling of Super-Nyquist Signals Using Built-in Monitor Photodiode Cheng Xu, Guanjun Gao and Jie Zhang (Beijing University of Posts and Telecommu- Yangyang Fan, Zhenning Tao, Liang Dou, Ying Zhao, Hao Chen (Fujitsu Research and nications, PRC); Sai Chen (Beijing University of Posts and Telecommunications & Bell Development Center Company Limited, PRC); Saito Taku and Komaki Kousuke (Fujitsu Labs, Alcatel-Lucent, USA); Ming Luo (FiberHome, PRC); Rong Hu (State Key Lab. of Ltd., JP); Takeshi Hoshida and Jens C. Rasmussen (Fujitsu Laboratories Ltd., JP) Optical Comm. Technologies and Networks, PRC) To pre-equalize the bandwidth limitation at the transmitter side, the overall response We demonstrate 12-Gbaud WDM PDM-QPSK transmission with 10GHz channel of the transmitter is required. An accurate response measurement assisted by the spacing and only 9.6-GSa/s ADC sampling rate. By using 4PB shaping with MLSE, photodiode built in Mach-Zehnder modulator is proposed and experimentally demon- the sampling rate can be reduced to 0.8-times symbol-rate without OSNR penalty, strated. compared with that of 2-times symbol-rate. Th.2.P2.SC4.39 Demonstration of a 71.8 Gbps 4-PAM 850 nm VCSEL-based Link with a Th.2.P2.SC3.29 Efficient SDM-MIMO Stokes-Space Equalization Pre-emphasizing Passive Filter Francisco Javier Vaquero Caballero (Technical University of Denmark, DE); Abdullah Tamás Lengyel and Krzysztof Szczerba (Chalmers University of Technology, SE); Zanaty (University of Kiel, DE); Fabio Pittalá, Gernot Goeger and Yabin Ye (Huawei Magnus Karlsson (Chalmers University of Technology & Photonics Laboratory, SE); Technologies Duesseldorf GmbH, DE); Idelfonso Tafur Monroy (Technical University of Anders Larsson and Peter A Andrekson (Chalmers University of Technology, SE) Denmark, Denmark & ITMO University, RU); Werner Rosenkranz (University of Kiel, DE) We present 71.8 Gbps 4-PAM back-to-back transmission in an 850 nm VC- We propose a novel frequency-domain 6x6 MIMO Stokes-space equalizer and SEL-based link using a passive pre-emphasis filter and FEC with no post-equaliza- compare its performance to a 6x6 MIMO LMS architecture. This method is suited to tion. Bit error rates below 10-8 are demonstrated with 72 Gbps uncoded data. overcome DSP complexity and laser linewidth issues in SDM transmission systems. Th.2.P2.SC4.40 Service-triggered failure identification/localization through monitoring of Th.2.P2.SC3.30 Short-Reach Distance Extension through CAPS Coding and DSP-free Direct multiple parameters Detection Receiver Marc Ruiz (Universitat Politècnica de Catalunya, ES); Francesco Fresi (CNIT, IT); Alba Francesco Fresi and Gianluca Meloni (CNIT, IT); Marco Secondini (Scuola Superiore Vela (Universitat Politècnica de Catalunya (UPC), ES); Gianluca Meloni (CNIT, IT); Sant‘Anna, IT); Fabio Cavaliere (Ericsson Telecomunicazioni, IT); Luca Potì (Consorzio Nicola Sambo (Scuola Superiore Sant‘Anna, IT); Filippo Cugini (CNIT, IT); Luca Potì Nazionale Interuniversitario per le Telecomunicazioni, IT); Enrico Forestieri (Scuola (Consorzio Nazionale Interuniversitario per le Telecomunicazioni, IT); Luis Velasco Superiore Sant‘Anna, IT) (Universitat Politècnica de Catalunya (UPC), ES); Piero Castoldi (Scuola Superiore Order-3 CAPS coding for short-reach direct-detection systems is experimentally Sant‘Anna, IT) demonstrated. Chromatic dispersion tolerance is compared to that of OOK and PAM- Failures in the optical layer might impact the quality of supported services. We 4 modulations, with respect to which transmission distance can be increased by a experimentally characterize several failure causes and propose an effective machine factor of 4 and 1.5, respectively. learning-based algorithm to localize and identify the most probable cause of failure impacting a given service. 53 Poster Session II Thursday, September 22, 2016 • 11:00 - 12:30 Th.2.P2.SC4.41 Cascadability Performance of a High-speed Electro-absorption Optical Th.2.P2.SC5.50 Investigation of Potential MPI Effects on Supervisory Channel Transmission Switch for DP-16QAM and DP-QPSK Optical Signals Below Cable Cut-off in G.654 Fibres Hideaki Furukawa (NICT, JP); Jose Manuel Delgado Mendinueta (National Institute of John D Downie, Jason Hurley and Hector DePedro, Steven Garner, Jeremy Blaker, Information and Communications Technology, JP); Toru Segawa (NTT Corporation Aramais Zakharian, Sergey Ten and Greg Mills (Corning Incorporated, USA) & NTT Device Technology Laboratories, JP); Ryo Takahashi (NTT Device Technology We examine supervisory channel transmission at wavelengths below cable cut-off Laboratories, JP); Satoshi Shinada (National Institute of Information and Communica- in G.654 fibres via modelling and cabled fibre tests. We find negligible MPI and no tions Technology, JP); Naoya Wada (NICT, JP) penalty for 2.5 Gb/s transmission in a worst-case configuration up to 40 nm below We experimentally investigate the cascadability of electro-absorption optical switch- cut-off. es for optical packet switched networks. Dual-polarization QPSK and 16QAM optical signals can cascade more than 50 and 10 EA optical switches, respectively, which is Th.2.P2.SC5.51 Experimental Investigation of Quasi-Periodic Power Spectrum in Raman-As- 1.6 times greater compared to SOA switches. sisted Phase Sensitive Amplifier for 10/20/50-Gbaud QPSK and 10-Gbaud 16QAM Signals Th.2.P2.SC4.42 Direct Modulation of a Hybrid III-V/Si DFB Laser with MRR Filtering for 22.5- Yinwen Cao, Fatemeh Alishahi (University of Southern Calliforni, USA); Youichi Akasa- Gb/s Error-Free Dispersion-Uncompensated Transmission over 2.5-km SSMF ka (Fujitsu Laboratories of America, Inc., USA); Morteza Ziyadi, Ahmed Almainman, Valentina Cristofori, Francesco Da Ros and Yunhong Ding (Technical University of Amirhossein Mohajerin-Ariaei, Changjing Bao and Peicheng Liao, Ahmad Fallahpour, Denmark, DK); Alexandre Shen (Alcatel-Thales III-V Lab, FR); Antonin Gallet (III-V lab, Bishara Shamee (University of Southern California, USA); Tadashi Ikeuchi (Fujitsu Lab- a joint lab of Nokia, Thales and CEA, FR); Dalila Make (Alcatel Thales III-V Lab, FR); oratories of America, Inc., USA); Shigehiro Takasaka and Ryuichi Sugizaki (Furukawa Guang-Hua Duan (III-V Lab, FR); Leif Oxenløwe (Technical University of Denmark, DK); Electric co., Ltd., JP); Joe Touch (USC/ISI, USA); Moshe Tur (Tel-Aviv University, ISR); Christophe Peucheret (University of Rennes 1, FR) Alan Willner (University of Southern California, USA) Error-free and penalty-free transmission over 2.5 km SSMF of a 22.5 Gb/s data Raman-assisted PSA without phase-stabilization-loop is experimentally evaluated signal from a directly modulated hybrid III-V/Si DFB laser is achieved by enhancing the by placing signals at different locations in a quasi-periodic PSA power spectrum. With dispersion tolerance using a silicon micro-ring resonator. phase adjustment, an 18dB peak-dip gain-extinction-ratio difference is observed. Improved performance is demonstrated using 10/20/50-Gbaud QPSK and 10-Gbaud Th.2.P2.SC4.43 Characterization of a Packaged Network on Chip based on Multi-Microrings 16QAM signals. Stefano Faralli, Isabella Cerutti, Fabrizio Gambini and Paolo Pintus (Scuola Superiore Sant‘Anna, IT); Giovan Battista Preve (CNIT, IT); Marco Chiesa (Scuola Superiore Th.2.P2.SC5.52 5-band (O, E, S, C, and L) WDM Transmission with Wavelength Adaptive Sant‘Anna, IT); Rubén Ortuño (Universidad Politécnica de Valencia & Nanophotonics Modulation Format Allocation Technology Center, ES); Nicola Andriolli (Scuola Superiore Sant‘Anna, IT) Seiji Okamoto, Kengo Horikoshi, Fukutaro Hamaoka, Kyo Minoguchi and Akira Hirano A multi microring network on chip with 6 ports has been fabricated in SOI, pack- (NTT Corporation, JP) aged and characterized. The BER penalty for two simultaneous 10Gb/s transmissions We propose wavelength adaptive modulation format allocation method for of up to 5 hops is below 1 dB at BER of 10-9. extremely wide WDM system. We successfully demonstrated 5-band WDM transmis- sion for the first time, and showed potential capacity achieves 106.77 Tbit/s within Th.2.P2.SC4.44 Single-Lane 112Gbps Transmission over 300m OM4 Multimode Fiber Based 23.5 THz or 173.83 nm using proposed method. on A Single-Transverse-Mode 850nm VCSEL Bo Wu (Huawei Technologies Co. Ltd, PRC); Xian Zhou (The Hong Kong Polytechnic Th.2.P2.SC5.53 A Digital Coherent Optical Code Division Multiplexing Network with 16-Tb/s University, PRC); Yanan Ma, Jun Luo, Shaofeng Qiu (Huawei Technologies Co., Ltd, (2560×6.25-Gb/s) Capacity PRC); Kangping Zhong (The Hong Kong Polytechnic University, HK); Feng Zhiyong Xie Wang, Yuanda Huang, Yanzhao Lu, Yi Yu and Liangchuan Li (Huawei Technolo- (Huawei Technologies Co., PRC); Chao Lu (The Hong Kong Polytechnic University, gies Co., Ltd., PRC) HK); Vitaly Shchukin and Joerg Kropp, Nikolay Ledentosov (VI Systems GmbH, DE) We experimentally demonstrate a digital coherent optical code division multiplexing Single-lane 120Gbps-BtB, 118Gbps-100m, 117Gbps-200m and 112Gbps-300m network with total capacity of 16-Tb/s (80×32×6.25-Gb/s) in C-band featuring 6.25- discrete multi-tone transmission based on a single-transverse-mode 850nm band Gb/s per node for 2560 supported nodes over 300-km standard-single-mode-fiber. VCSEL is investigated respectively over standard OM4 multimode fiber. This proves our previous conclusion of single-lane capacity beyond 100G by more optical cou- Th.2.P2.SC5.54 150-Gb/s DMT over 80-km SMF transmission based on Spectrally Efficient pling power SSBI cancellation using guard-band Twin-SSB Technique Liang Zhang and Tianjian Zuo (Huawei, PRC); Qiang Zhang (Huawei Technologies Th.2.P2.SC4.45 Precise Sub-carrier Frequency Monitor and Control Method for Superchannel Duesseldorf GmbH, DE); Jie Zhou, Enbo Zhou, Gordon Ning Liu (Huawei Technolo- Transmission in Cascaded ROADM Network gies Co. Ltd., PRC) Guoxiu Huang, Shoichiro Oda (Fujitsu Laboratories Ltd., JP); Ying Zhao (Fujitsu Re- We propose a spectrally efficient SSBI cancellation scheme based on guard-band search and Development Center, PRC); Huihui Li (Fujitsu R&D Centre Co., Ltd., PRC); twin-SSB technique. 112-Gb/s DMT transmission over 80-km SMF is experimentally Tomohiro Yamauchi (Fujitsu Laboratories Ltd., JP); Setsuo Yoshida and Yasuhiko Aoki demonstrated with an ROSNR of 30.7 dB and the highest achieved capacity is up to (Fujitsu Ltd., JP); Zhenning Tao (Fujitsu R&D Center Ltd., PRC); Jens C. Rasmussen 150 Gb/s. (Fujitsu Laboratories Ltd., JP) We proposed precise sub-carrier frequency monitor and control method to Th.2.P2.SC5.55 Advanced Receiver Design enables PDM-16QAM DWDM Transmission over eliminate laser frequency uncertainness in super-channel transmission. Based on 2660 km of SSMF with Only EDFA digital signal processing without additional hardware, the relative frequency accuracy Xiaozhou Wang (Universität der Bundeswehr München & Coriant GmbH, DE); Stefano reached 10 times higher than ITLA specification. Calabro and Bernhard Spinnler (Coriant R&D GmbH, DE); Ginni Khanna (Technical University of Munich, DE); Berthold Lankl (University of Federal Armed Forces Munich, DE) Th.2.P2.SC4.46 End-to-end Optical 25Gb/s Link Demonstrator with Embedded Waveguides, We demonstrate experimental DWDM PDM-16QAM transmission at 200 Gb/s over 90°Out-of-Plane Connector and On-board Optical Transceivers 2660 km of SSMF, using EDFA-only amplification and advanced DSP techniques, Marika Immonen (TTM Technologies, FN); Ruiyong Zhang (FCI Deutschland GmbH, including powerful digital pre-distortion, iterative carrier recovery and decoding using DE); Marie Press, Hong Tang and Wanlu Lei (Ericsson AB, SE); Jinhua Wu and Hui 50% OH soft-decision FEC. Juan Yan (TTM Technologies, PRC); Long Xiu Zhu (TTM Technologies, FN); Murat Serbay (FCI Deutschland GmbH, DE) Th.2.P2.SC5.56 Experimental Nonlinear Frequency Division Multiplexed Transmission using We present optical/electrical demonstrator with 96-optical channels totalling Eigenvalues with Symmetric Real Part 2.4Tb/s aggregate capacity tested with 300Gb/s on-board transceivers, embedded Alexander Geisler and Christian Schaeffer (Helmut-Schmidt-University, DE) waveguides, and connectors with 90° reflectors in a standard PCB. Results show We demonstrate the nonlinear transmission of a PSK modulated discrete spectrum BER 1E-12at 25Gb/s, <0.1dB/cm transmission loss and 2.5dB connector loss. consisting of up to 3 eigenvalues, 2 of them having non-zero symmetric real parts. A low error rate using NFT detection at 4Gbps is shown. Th.2.P2.SC4.47 Monolithic Photonic-Electronic Linear Direct Detection Receiver for 56Gbps OOK Th.2.P2.SC5.57 Correlation Between Modulated and Probe Signals for Superchannel In- Marcel Kroh, Ahmed Awny (IHP Microelectronics, DE); Georg Winzer (IHP, DE); Ra- ter-Subcarrier Nonlinear Phase Perturbations jasekhar Nagulapalli (Inphi, UK); Stefan Lischke (IHP Frankfurt/Oder, DE); Dieter Knoll Ali Rezania, John C Cartledge and Aazar Kashi, Ali Bakhshali, Ahmed Abd El-Rahman and Anna Peczek (IHP GmbH, DE); Daniel Micusik (Rohde & Schwarz, DE); Ahmet (Queen‘s University, CA) Cagri Ulusoy and Dietmar Kissinger (IHP, DE); Lars Zimmermann (IHP & Technical For a 1 Tb/s dual-polarization 16-QAM Nyquist-superchannel, the degree of University of Berlin, DE); Klaus Petermann (Technical University of Berlin, DE) correlation for the inter-subcarrier nonlinearity induced phase perturbation is assessed A monolithic photonic-electronic direct detection single pol linear receiver chip is between a modulated center subcarrier and a CW probe center subcarrier. presented. Electro-optical bandwidth and BER measurements reveal state-of-the-art performance of the integrated receiver. Th.2.P2.SC5.58 Power Consumption of a Minimal-DSP Coherent Link with a Polarization Multiplexed Pilot-Tone Th.2.P2.SC4.48 Experimental Demonstration of Full-Duplex Data Transmission Link using Lars Lundberg, Christoffer Fougstedt, Per Larsson-Edefors and Peter A Andrekson Twisted Lights Multiplexing over 1.1-km Orbital Angular Momentum (OAM) (Chalmers University of Technology, SE); Magnus Karlsson (Chalmers University of Fiber Technology & Photonics Laboratory, SE) Shi Chen and Jun Liu (Huazhong University of Science and Technology, PRC); Yifan We experimentally study the trade-off between performance and DSP power Zhao (Huazhong University of Science and Technology & Wuhan National Laboratory consumption. While minimal DSP allows transmission of 16QAM at 5GBaud, the for Optoelectronics, PRC); Long Zhu, Andong Wang, Jing Du, Shuhui Li and Jian symbol rate can be increased if an extra equalizer is added, leading to energy savings Wang (Huazhong University of Science and Technology, PRC) in optical components. We propose and demonstrate a full-duplex data transmission link using twisted light multiplexing over 1.1-km OAM fiber. The measured full-duplex OSNR penalties at Th.2.P2.SC5.59 Cross Polarization Modulation (XPolM) Compensation for Submarine Up- BER of 2×10-3 for uplink and downlink are about 2.3 dB. grade Links using DP-8QAM Milutin Pajovic, David Millar, Kieran Parsons (Mitsubishi Electric Research Labora- tories, USA); Keisuke Matsuda and Hiroshi Miura (Mitsubishi Electric Corporation, JP); Keisuke Kojima Toshiaki Koike-Akino (Mitsubishi Electric Research Laboratories, SC 5 - Point-to-Point Transmission Systems USA); Tsuyoshi Yoshida (Mitsubishi Electric Corporation, JP) We propose a method of XPolM compensation suitable for submarine upgrade systems, and experimentally validate performance for a 70 × 192 Gb/s DP-8QAM Th.2.P2.SC5.49 Experimental Studies on Characteristics of Polarization Parameters over system. The method improves the Q-factor by 0.16dB and outperforms the conven- Atmospheric Turbulence tional NPCC by 0.12dB. Jiankun Zhang, Ruijie Li and Anhong Dang (Peking University, PRC) We report an investigation on turbulence-induced changes for overall polarization Th.2.P2.SC5.60 Stochastic Nonlinear Interference in Dispersion Managed Coherent Optical parameters of light beams, with different wavelength and under different Rytov index- Links es. Experimental results show strong correlations between state of polarization and Nicola Rossi (Nokia Bell Labs, FR); Amirhossein Ghazisaeidi (Université Laval, CA); turbulent strength, which is consistent with theoretical predictions. Petros Ramantanis (Nokia Bell Labs, FR) We numerically investigate the stochastic nature of nonlinear interference in disper- sion managed links. We show deviation of signal statistics from Gaussian assumption and significant performance variability due to interaction between nonlinearity and polarization mode dispersion. 54 Poster Session II Thursday, September 22, 2016 • 11:00 - 12:30 Th.2.P2.SC5.61 Improving 100-Gb/s Transmission Performance in a 1250-km Legacy Disper- SC 7 - Access, Local Area and Home Networks sion-Managed Link with Co-Propagating 10-Gb/s OOK Channels via Modified Phase-Conjugated Twin Waves Xuefeng Tang, Zhuhong Zhang and Zhiping Jiang (Huawei Technologies (Canada), Th.2.P2.SC7.72 Unified Evolution-Ready 25 Gbps NG-PON Architecture CA); Xiang Liu (Futurewei Technologies, USA); Chuandong Li (Huawei Technologies Vincent Houtsma (Nokia Bell Labs, USA); Dora van Veen (Nokia Bell Labs, USA); (Canada), CA) Ed Harstead (Alcatel-Lucent, BE) We experimentally demonstrate the improved nonlinear transmission performance First experimental proof of a unique evolution-ready 25G TDM-PON architecture of a 100-Gb/s channel using modified phase-conjugated twin waves in a 1250-km featuring dual-rate 10 and 25 Gbps upstream. The architecture supports a novel legacy dispersion-managed SSMF link and 50-GHz-spaced co-propagating 10-Gb/s black-box approach taking into account future optical and electronic component cost OOK channels, achieving 0.7dB improved performance over a common 100-Gb/s evolutions. DP-QPSK channel. Th.2.P2.SC7.73 Multi-Core Based 94-GHz Radio and Power over Fiber Transmission Using 100-GHz Analog Photoreceiver Th.2.P2.SC5.62 Optimum Capacity Utilization in Space-Division Multiplexed Transmission Toshimasa Umezawa, Atsushi Kanno, Tien Dat Pham, Kouichi Akahane, Yoshinari Systems with Multimode Fibers Awaji, Naokatsu Yamamoto and Tetsuya Kawanishi (National Institute of Information Georg Rademacher and Friederike Schmidt, Klaus Petermann (Technical University of and Communications Technology (NICT), JP) Berlin, DE) We propose a multi-core-based radio and power over fiber transmission using a 100 For maximum capacity utilization, all spatial channels in space-division multiplexed GHz photoreceiver, and demonstrate 1 m photonic wireless transmission at 10 Gbps transmission systems are desired to perform equally. We show that an optimized per- (OFDM, 16QAM, 3 GHz) through a photonic power supply via cores in a multi-core fiber. mode power is capable of increasing the overall system OSNR. Th.2.P2.SC7.74 Ultrahigh-Fidelity Mobile Fronthaul Using Analog Angle Modulation Th.2.P2.SC5.63 Mitigation of Fading Caused by Atmospheric Turbulence with FMF Coupling Di Che (The University of Melbourne & National ICT Australia, AU); Feng Yuan and and Maximum Ratio Combining Used in 320-m Free-Space Optical Transmis- William Shieh (University of Melbourne, AU) sion of 10 Gb/s BPSK We propose angle modulation to remarkably enhance the SNR of channel-aggre- Manabu Arikawa, Takashi Ishikawa, Kohei Hosokawa, Seigo Takahashi, Yoshimasa gation-based analog fronthaul link. Experiments show >27-dB SNR improvement Ono and Toshiharu Ito (NEC Corporation, JP) using CPRI-equivalent bandwidth and >5 dB advantage of nonlinearity tolerance, We experimentally demonstrated the sum of the six modes of FMF improved cou- compared with amplitude modulation. pling efficiency by 6.5 dB for the optical beam impaired by 320-m open-air free-space Th.2.P2.SC7.75 TWDM-PON ONUs Optical Frequency Drift versus Tuning transmission, and fading was suppressed by digital maximum ratio combining for 10 Gael Simon and Fabienne Saliou (Orange, FR); Philippe Chanclou (Orange Labs, FR); Gb/s BPSK. Bertrand Le Guyader (Orange, FR); Laurent Guillo (France Telecom R&D, FR); Luiz Anet Neto (Orange Labs, FR); Didier Erasme (Telecom ParisTech, FR) Th.2.P2.SC5.64 Achievable Information Rate of Nonlinear Inverse Synthesis Based 16QAM A vendor‘s TWDM-PON system and a commercial laser permit to demonstrate that OFDM Transmission reaching optical budget requirements for all NG-P ON2 capable channels signifies Son Le and Ian Phillips (Aston University, UK); Jaroslaw Prilepsky , Morteza Kamalian, failing upstream spectral excursion requirements, and reciprocally. Kopae (Aston University & Aston Institute of Photonic Technologies, UK); Andrew Th.2.P2.SC7.76 Multi-Dimensional Resources Integration for Service Provisioning in 5G Ellis and Paul Harper (Aston University, UK); Sergei K. Turitsyn (Aston University & Cloud Radio over Fiber Network Photonics Research Group, UK) Hui Yang, Wei Bai, Yuanlong Tan, Ao Yu, Jie Zhang (Beijing University of Posts and We experimentally investigate, for the first time, the achievable information rate of Telecommunications, PRC); Young Lee (Huawei Technologies Co., Ltd, USA); Yuefeng the nonlinear inverse synthesis system with 16QAM OFDM format employing hard Ji (Beijing University of Posts and Telecommunications, P.R. China) and soft FEC, showing that 3 bits/symbol can be achieved over a distance of 1632 We propose a multi-dimensional resources integration (MDRI) architecture for km. services provisioning with resources integrated provisioning (RIP) scheme in software defined cloud radio over fiber network of 5G. The feasibility and efficiency are verified on OpenFlow-based enhanced SDN testbed. SC 6 - Core, Metro and Data Center Networks Th.2.P2.SC7.77 Feasibility Study on In-Band Unidirectional ONU Control of the 10G-class WDM Overlaid Digital Baseband UHD Video Distribution System Toshiaki Shitaba, Tomohiro Taniguchi and Hidekazu Shimizu (NTT Corporation, JP); Th.2.P2.SC6.65 Demonstration of a Hybrid SDN/GMPLS Control Plane for Optical Virtual Toshihito Fujiwara (NTT & NTT Access Network Service Systems Laboratories, JP); Private Networks with Restoration Capabilities Hisao Yoshinaga and Tomoki Sugawa (NTT Corporation, JP) Domenico Siracusa, Federico Pederzolli , Matteo Gerola and Andrea Zanardi (Cre- This paper describes a downlink digital baseband video distribution system using ate-Net, IT); Domenico La Fauci and Gabriele Maria Galimberti (Cisco Photonics, IT) WDM-overlay technology. An experiment confirms the feasibility of in-band carousel Creating Optical Virtual Private Networks (OVPNs) over existing deployments is ONU control, a key technology of the system. becoming an operator concern. This paper describes the first hybrid SDN/GMPLS implementation addressing this problem and demonstrates, through an emulated Th.2.P2.SC7.78 Direct Detection OFDM PON using Ge-on-Si Photodetector Employing Volter- testbed, that the system is responsive and provides OVPN-specific restoration. ra Filtering for Nonlinear Compensation Yung Hsu, Jun-jie Liu (National Chiao Tung University, TW); Xinru Wu (The Chinese Th.2.P2.SC6.66 Crosstalk-aware Virtual Optical Network Embedding (VONE) in Spatial Divi- University of Hong Kong, HK); Hsin-Yu Wu (National Chiao Tung University, TW); sion Multiplexing Enabled Elastic Optical Networks with Multi-core Fibers Chien-Hung Yeh (Industrial Technology Research Institute, TW); Hon Tsang (The Ruijie Zhu and Yongli Zhao, Hui Yang, Yuanlong Tan, Xiaosong Yu, Guanjun Gao and Chinese University of Hong Kong, HK); Jyehong Chen and Chi-Wai Chow (National Jie Zhang (Beijing University of Posts and Telecommunications, PRC); Nannan Wang Chiao Tung University, TW) and Jason P. Jue (University of Texas at Dallas, USA) We propose and demonstrate a Ge-on-Si photodetector-based direct-detection A crosstalk-aware VONE (CA-VONE) algorithm is proposed for spatial division orthogonal-frequency-division-multiplexing passive-optical-network (OFDM-PON) em- multiplexing enabled elastic optical networks with multi-core fibers. Simulation results ploying Volterra-filtering for nonlinear compensation. Capacity is enhanced by 49.55% show that CA-VONE can achieve better performance than the previous algorithms in to data-rate of 53.8Gbit/s after 20-km standard-single-mode-fiber (SSMF). terms of blocking probability and resource utilization. Th.2.P2.SC7.79 LTE-A Multiband and Ethernet over Large-core Diameter GI POF for Wired Th.2.P2.SC6.67 Experimental Demonstration of a Programmable S-BVT with PDM Capability and Wireless In-home Networks for Flexible Optical Metro Networks Federico Forni (Eindhoven University of Technology & Genexis B. V., NL); Yan Shi Laia Nadal Reixats and Michela Svaluto Moreolo, Josep M. Fabrega, Francisco Javier (Genexis, NL); Henrie van den Boom, Eduward Tangdiongga (Eindhoven University of Vílchez (Centre Tecnològic de Telecomunicacions de Catalunya, ES) Technology, NL); Ton Koonen (COBRA, Eindhoven University of Technology, NL) We experimentally demonstrate a programmable sliceable-BVT with PDM capability We demonstrate the successful co-transmission of 7 standard-compliant 64-QAM and adaptive FEC selection based on DD-OFDM, achieving 40G-100G transmission LTE-A bands and 2Gb/s 4-PAM over 35m of 1mm core diameter GI-POF and rates. PDM slice-ability is also assessed within the ADRENALINE network nodes 3.5m LOS and NLOS wireless links. This demonstrates the suitability of POF for the enabling up to 50\% spectral saving. next-generation home-appliance wireless-wired services. Th.2.P2.SC6.68 Transport API: A Solution for SDN in Carriers Networks Th.2.P2.SC7.80 Optical Beating Interference Reduction by Using Optical Pulse Division Victor Lopez (Telefonica, ES); Ricard Vilalta (CTTC, ES); Víctor Uceda (Universidad Multiplexing in IM/DD based OFDMA-PON Uplink Autónoma de Madrid, ES); Arturo Mayoral (CTTC, ES); Ramon Casellas (Centre Sun-Young Jung, Chang-Hun Kim, Sang-Min Jung and Sang-Kook Han (Yonsei Tecnologic de Telecomunicacions de Catalunya (CTTC), ES); Ricardo Martinez and University, KR) Raul Muñoz (CTTC, ES); Juan P. Fernández-Palacios (Telefónica I+D, ES) Optical beating interference (OBI) hinders signal detection in IM/DD based multiple The ONF Transport API is an interface to enable control of Transport networks, in- access with single nominal wavelength. Optical pulse division multiplexing based OBI cluding services such as topology, or connectivity setup. We present the first demon- reduction is proposed and experimentally demonstrated in OFDMA-PON uplink by stration of a connectivity service over a DWDM network using the ONF Transport API. considering spectrum broadening and near-orthogonality. Th.2.P2.SC6.69 Nonlinear-impairments- and crosstalk-aware resource allocation schemes for multicore-fiber-based flexgrid networks Th.2.P2.SC7.81 Real-Time Demonstration of an Optically Powered Radio Head for Low-Pow- Madushanka Nishan Dharmaweera and Li Yan (Chalmers University of Technology, er Small Cells with 94 dB End-to-End Budget SE); Magnus Karlsson (Chalmers University of Technology & Photonics Laboratory, Bernhard Schrenk, Thomas Zemen (AIT Austrian Institute of Technology GmbH, AUT) SE); Erik Agrell (Chalmers University of Technology, SE) End-to-end analogue down- and uplink radio transmission with real-time signal In this study, we propose a novel spectrum and core allocation scheme that processing is experimentally demonstrated using a technologically lean and ener- incorporates both intra-core physical layer impairments and inter-core crosstalk. We gy-conscious remote radio head. Powering through the fronthaul at an optical feed of demonstrate that accounting for the latter increases spectral efficiency by at least 290 mW enables a centralised power supply. 50% when crosstalk is significant. Th.2.P2.SC7.82 Multilevel Pulse Width Modulation Fibre Optic Transmission for Next Genera- tion Mobile Fronthaul Th.2.P2.SC6.70 On Deploying Encryption Solutions to Provide Secure Transport-as-a-Service Paola Parolari and Alberto Gatto (Politecnico di Milano, IT); Lorenzo Combi (DEIB (TaaS) in Core and Metro Networks Politecnico di Milano, IT); Pierpaolo Boffi, Mario Martinelli and Umberto Spagnolini Kyle C Guan and Joseph Kakande (Bell Labs, Nokia, USA); Junho Cho (Nokia Bell (Politecnico di Milano, IT) Labs, USA) Multilevel pulse width modulation for optical C-RAN fronthaul is proved and We study different architectural options of deploying OTN encryption solutions for compared with standard pulse width modulation for aggregated LTE channels. the core or metro transport networks, by evaluating the equipment cost, bandwidth Transmission over 7.5-km SSMF in a WDM PON fronthaul network is experimentally utilization, and complexity of key management under different traffic patterns. demonstrated for 16 LTE-64QAM aggregated channels. Th.2.P2.SC6.71 Results of Empirical Searches for k-Connected Minimum-Mean-Hop Network Th.2.P2.SC7.83 Energy-Efficient Cycle Length Compressing Scheme for TDM based Passive Topologies Optical Network Joseph Kakande and Steve Korotky (Nokia Bell Labs, USA) Yunxin Lv, Ning Jiang and Chenpeng Xue, Kun Qiu (University of Electronic Science We identify members of the sets of non-degenerate k-connected Mini- and Technology of China, PRC) mum-Mean-Hop topologies for a given number of nodes and links using empirical An energy-efficient scheme based on cycle length compressing is proposed and searches and substantiate the accuracy of an approximation for the minimum average analysed. By periodically compressing polling cycle length, longer sleeping time as hops for 2-connected graphs. well as substantial energy saving are obtained at ONU. 55 Author List Author Session No. Author Session No. A Aupetit-Berthelemot, Christelle Tu.1.F.3 / Th.1.D.4 Abbasi, Amin M.2.E.1 Autenrieth, Achim Tu.1.B.2 / Tu.1.B.3 Abd El-Rahman, Ahmed Th.2.P2.SC5.9 Avramopoulos, Hercules Tu.3.A.1 Abe, Jun-ichi Tu.2.B.4 Awaji, Yoshinari M.1.F.3 / Tu.1.D.2 / W.4.P1.SC5.12 / Abe, Masashi W.4.P1.SC2.4 W.4.P1.SC6.2 / Th.2.P2.SC7.2 Abokhamis mousavi, Seyedmohammad Th.2.P2.SC2.6 Awny, Ahmed Th.2.P2.SC4.14 Abrams, Nathan Th.2.P2.SC4.4 Awwad, Elie Tu.1.E.1 / Tu.3.B.5 Abrate, Silvio W.4.P1.SC7.6 Azana, Jose CLEO 3.4 Absil, Philippe W.4.P1.SC2.8 Azcárate, Gregorio M.1.E.5 Achouche, Mohand Tu.1.C.4 Aznar, José W.1.F.4 Achten, Frank Tu.2.D.3 / W.3.B.4 Adachi, Koichiro Th.2.P2.SC2.5 B Adamiecki, Andrew M.1.C.2 / M.1.C.5 / Tu.3.A.5 Babin, Sergey CLEO 5.5 Agraz, Fernando W.1.F.4 Bahadori, Meisam Th.2.P2.SC2.12 Agrell, Erik Tu.1.D.2 / W.4.P1.SC3.9 / Th.2.P2.SC3.5 / Bai, Wei Th.2.P2.SC7.5 Th.2.P2.SC6.5 Bakhshali, Ali Tu.2.A.3 / W.4.P1.SC5.8 / Th.2.P2.SC5.9 Aguado, Alejandro Tu.1.B.2 / Tu.1.B.5 / W.1.F.2 Bakopoulos, Paraskevas Th.1.C.4 Agustin, Mikel W.4.P1.SC4.12 Baldivieso, Andrea Th.2.P2.SC4.3 Aikawa, Kazuhiko W.2.B.2 / W.4.P1.SC1.6 / Th.2.P2.SC2.7 Balemarthy, Kasyapa Th.1.C.5 Aikawa, Yohei W.4.P1.SC3.1 Bao, Changjing W.3.C.4 / Th.2.P2.SC5.3 / Th.2.P2.SC2.5 Aimone, Alessandro Tu.3.A.1 Barbet, Sophie M.2.E.5 Akahane, Kouichi Th.2.P2.SC7.2 Barletta, Luca W.1.D.1 Akasaka, Youichi W.3.C.4 / Th.2.P2.SC2.5 / Th.2.P2.SC5.3 Barré, Nicolas W.4.P1.SC4.10 Akiyama, Yuichi M.1.B.3 Barry, Liam WS5.9 / Tu.3.C.1 Alam, Shaif-ul WS4.3 / W.2.B.4 / W.3.B.2 Barthelemy, Alain CLEO 1.3 Aldaya, Ivan Th.2.P2.SC3.1 Batshon, Hussam Tu.1.D.3 Alic, Nikola Tu.3.B.4 Bauwelinck, Johan M.2.E.1 / Tu.3.A.1 / Tu.3.F.4 /Th.1.C.4 Alippi, Andrea W.4.P1.SC2.3 Bayraktar, Ömer W.4.P1.SC5.3 Alishahi, Fatemeh W.3.C.4 / Th.2.P2.SC5.3 Bayvel, Polina M.1.D.4 / M.1.E.2 / M.2.B.1 / M.2.D.6 / W.2.C.1 / Alloatti, Luca W.1.A.2 W.2.C.5 / W.4.P1.SC3.9 / W.4.P1.SC5.11 / Th.1.A.2 / Almainman, Ahmed W.3.C.4 / Th.2.P2.SC2.5 / Th.2.P2.SC5.3 Th.2.P2.SC3.5 Alreesh, Saleem W.1.C.4 Befekadu, Mengesha W.4.P1.SC7.6 Altenhain, Lars M.1.C.4 Begleris, Ioannis Tu.2.D.4 Alvarado, Alex M.1.B.1 / M.1.D.4 / W.2.C.1 / W.2.C.5 / Behrens, Carsten WS6.7 W.4.P1.SC5.11 / Th.1.A.2 Bekkali, Abdelmoula W.4.P1.SC7.8 Alvarado-Zacarias, Juan Tu.2.D.1 / Tu.2.D.3 / Tu.2.F.5 Belardi, Walter Th.2.P2.SC2.6 Alves, Tiago Th.2.P2.SC2.4 Ben Ezra, Shalva Tu.3.C.3 Alyshev, Sergey W.4.P1.SC1.4 Bendahmane, Abdelkrim CLEO 1.3 / CLEO 4.3 / CLEO 4.5 Amado, Sofia W.4.P1.SC3.3 Bercy, Anthony CLEO 1.4 Amann, Markus-Christian Th.1.C.4 Berg, Loren Tu.3.B.1 Amaral, Gustavo Th.2.P2.SC4.3 Berger, Michael M.2.F.1 Amma, Yoshimichi W.4.P1.SC1.6 / Th.2.P2.SC2.7 Bergman, Keren M.2.F.2 / Th.2.P2.SC2.12 / Tu.2.B.3 / Th.2.P2.SC4.4 Amy-Klein, Anne CLEO 1.4 Bertignono, Luca W.1.D.3 Andrekson, Peter Tu.1.E.3 / W.1.B.2 / W.4.P1.SC1.7 / Beyer, Johannes W.4.P1.SC2.2 Th.1.A.3 / Th.2.P2.SC4.6 / Th.2.P2.SC5.10 Bhat, B M.1.C.5 Andresen, Esben W.4.P1.SC1.3 Bianchi, Alberto Tu.2.C.4 Andriolli, Nicola Tu.2.E.1 / Th.2.P2.SC4.10 Bidkar, Sarvesh Tu.1.B.5 / Th.1.E.2 Anet Neto, Luiz Tu.1.F.3 / W.3.E.2 / Th.1.D.4 / Th.2.P2.SC3.3 / Bielik, Anna M.1.C.4 Th.2.P2.SC7.4 Bigo, Sebastien M.2.B.2 / M.2.C.1 / W.1.F.6 / W.4.P1.SC3.7 / Th.1.E.1 Anezcua-Correa, Rodrigo Tu.2.D.1 / Tu.2.D.3 / Tu.2.F.5 Bigot, Laurent W.3.B.3 / W.4.P1.SC1.3 Angelini, Philippe M.2.C.1 / Tu.1.C.4 Bigot, Marianne W.3.B.3 / W.3.B.4 Ania-Castanon, Juan Diego CLEO 5.3 Bigot-Astruc, Marianne Tu.2.D.1 / Tu.2.D.3 Annoni, Andrea W.4.P1.SC2.3 Billet, Cyril CLEO 5.2 Anthur, Aravind Tu.3.C.1 Bimberg, Dieter CLEO 3.3 Antonio-Lopez, Jose Tu.2.D.1 / Tu.2.D.3 / Tu.2.F.5 Birk, Martin Tu.2.B.1 Antony, Cleitus Tu.3.F.2 Birk, Yitzhak Tu.3.C.3 Aoki, Yasuhiko M.1.B.2 / Tu.2.B.1 / Tu.2.C.1 / Th.1.D.2 / Bisplinghoff, Andreas W.4.P1.SC3.6 Th.2.P2.SC4.12 Blache, Fabrice M.2.C.1 / Tu.1.C.4 Aozasa, Shinichi M.2.A.4 Blaicher, Matthias W.3.F.4 Apostolopoulos, Dimitrios WS 2.1 / Tu.3.A.1 Blaker, Jeremy Th.2.P2.SC5.2 Arakawa, Yasuhiko WS5.6 Böcherer, Georg M.1.D.2 / M.1.D.3 / W.1.C.1 Aref, Vahid Tu.3.E.1 / Tu.3.E.2 / Th.2.P2.SC3.6 Boertjes, David WS2.8 Argyris, Nikolaos Tu.3.A.1 Boffi, Pierpaolo W.4.P1.SC1.5 / Th.2.P2.SC7.11 Arikawa, Manabu Th.2.P2.SC5.15 Bogoni, Antonella Tu.2.E.1 Arlunno, Valeria W.2.C.2 / W.2.D.1 Bohn, Marc W.3.D.3 Artiglia, Massimo M.1.E.5 Bolshtyansky, Maxim Tu.1.D.3 / W.3.D.4 Asaka, Kota W.4.P1.SC7.4 Bolten, Jens Th.2.P2.SC2.10 Assine, Juliano W.4.P1.SC4.6 Bonk, Rene W.3.E.5 Astra, Egon Th.1.A.3 Borges, Nuno Tu.1.B.3 Asyngier, Tadeusz M.2.C.4 Borkowski, Robert W.3.E.5 Ataie, Vahid Tu.3.B.4 Borowiec, Andrzej Tu.2.C.3 / Tu.3.B.1 / W.4.P1.SC5.8 / Auer, Erich M.0.3 W.4.P1.SC5.13 / W.4.P1.SC5.15 56 Author List Author Session No. Author Session No. Bosco, Gabriella W.1.D.3 Chen, Christine Th.2.P2.SC4.4 Boscolo, Sonia CLEO 2.2 Chen, Guanyu W.4.P1.SC2.11 Bosman, Erwin Tu.3.A.1 Chen, Hao Th.2.P2.SC4.5 Bottoni, Fabio M.1.E.5 Chen, Haoshuo Tu.2.D.3 / Tu.3.A.5 / W.2.B.5 / Th.1.B.1 Bowers, John WS5.2 / W.3.F.3 Chen, Jiajia W.4.P1.SC4.3 Bramerie, Laurent Tu.2.E.6 Chen, Jyehong Th.2.P2.SC4.1 / Th.2.P2.SC7.7 Brandonisio, Nicola W.3.E.4 Chen, Long W.1.E.4 Brasch, Victor Tu.3.E.3 / CLEO 4.2 Chen, Sai Th.2.P2.SC3.8 Braun, Ralf-Peter M.1.D.2 Chen, Shi Th.2.P2.SC4.15 Bravalheri, Anderson W.4.P1.SC4.6 Chen, Su W.3.B.2 Brecht, Benjamin CLEO 2.6 Chen, Xi Tu.3.A.5 Brenot, Romain M.2.E.2 / M.2.E.3 / M.2.E.5 Chen, Xiaoliang Tu.3.D.2 Brés, Camille WS4 Chen, Yong Tu.2.F.3 Breuer, Dirk Tu.1.F.1 Chen, Young-Kai WS5.5 / M.2.D.3 / M.2.E.2 / W.2.E.3 / Th.2.P2.SC2.2 Brinker, Walter W.2.E.2 Cheng, Lin W.1.E.2 / W.4.P1.SC7.1 Brunner, Daniel CLEO 2.1 Cheng, Tonglei W.4.P1.SC1.1 Buchali, Fred M.1.C.4 / W.1.C.1 / W.1.C.3 / M.1.D.2 / M.1.D.3 / Chi, Nan M.2.D.5 / W.4.P1.SC4.8 W.2.D.5 / W.4.P1.SC3.5 Chiado`Piat, Anna W.3.D.3 Buelow, Henning Tu.3.E.1 / Tu.3.E.2 / W.2.D.5 Chien, Hungchang M.2.D.5 Bueno, Julian CLEO 2.1 Chien, Hung-Chang M.1.C.1 / W.3.D.1 Burrows, Ellsworth M.2.A.1 / M.1.C.5 / W.1.D.2 Chiesa, Marco Th.2.P2.SC4.10 Chin, Hou-Man W.4.P1.SC5.15 C Chiodo, Nicolas CLEO 1.4 Cai, Jin-Xing Tu.1.D.3 / W.3.D.4 Chitambar, Abhijit W.4.P1.SC6.6 Caillaud, Christophe Tu.1.C.4 Chiuchiarelli, Andrea M.1.B.4 / Th.2.P2.SC2.11 Calabretta, Nicola M.2.F.4 / W.1.E.3 / W.2.F.3 / W.4.P1.SC4.14 Chmielak, Bartos Th.2.P2.SC2.10 Calabro, Stefano W.3.D.3 / Th.2.P2.SC5.7 Cho, Junho M.1.C.2 / M.1.C.5 / W.1.D.2 / W.4.P1.SC5.10 / Calhoun, David Th.2.P2.SC4.4 Th.2.P2.SC6.6 Camisard, Emilie CLEO 1.4 Chorchos, Lukasz W.4.P1.SC4.12 Cano, Ivan M.1.E.5 / W.4.P1.SC7.7 Choutagunta, Karthik WS1.1 Cantono, Mattia Tu.2.B.5 / Tu.3.D.4 Chow, Chi-Wai Th.2.P2.SC7.7 Cao, Xiaoyuan Tu.3.D.3 Christodoulopoulos, Kostas W.4.P1.SC6.5 Cao, Yinwen W.3.C.4 / Th.2.P2.SC2.5 / Th.2.P2.SC5.3 Chtioui, Mourad Tu.2.E.4 Cao, Zizheng Tu.2.E.2 / W.1.E.3 / W.4.P1.SC4.9 Chu, Guang Yong M.1.E.5 Capmany, Jose Th.2.P2.SC2.4 / Th.2.P2.SC4.2 Chung, Yun C. W.4.P1.SC7.2 Carena, Andrea WS2.4 / W.1.D.3 Chung, Yun Chur W.4.P1.SC7.8 Carey, Daniel W.3.E.4 Churkin, Dmitry CLEO 5.4 Carroll, John M.2.D.6 Ciaramella, Ernesto M.1.E.5 Cartaxo, Adolfo Th.2.P2.SC2.4 Cincotti, Gabriella W.4.P1.SC5.1 Cartledge, John WS6.12 /M.2.C.2 / Tu.2.A.3 / W.4.P1.SC5.8 / Codemard, Christophe M.1.A.1 W.4.P1.SC5.13 / Th.2.P2.SC5.9 Combi, Lorenzo Th.2.P2.SC7.11 Carvalho, Heitor W.4.P1.SC4.6 Connally, Patrick M.1.C.5 Carvalho, Luis M.1.C.2 / Th.2.P2.SC2.11 Contreras, Luis M. Tu.1.B.4 Casellas, Ramon Tu.1.B.2 / W.1.F.1 / Th.2.P2.SC6.4 Corcoran, Bill W.2.D.4 / W.4.P1.SC2.9 / W.4.P1.SC3.12 Cassese, Tommasso Tu.2.C.4 Corredera, Pedro CLEO 5.3 Castineiras, Carmen W.3.B.3 Cossu, Giulio M.1.E.5 Castoldi, Piero Tu.1.B.4 / W.4.P1.SC6.5 / Th.2.P2.SC4.7 Couderc, Vincent CLEO 1.3 Castro Casales, Alberto M.2.F.3 / Tu.3.D.2 Cristofori, Valentina Th.2.P2.SC4.9 Cavaliere, Fabio Th.2.P2.SC3.10 Cugini, Filippo Tu.1.B.4 / Th.2.P2.SC4.7 Ceoldo, Davide CLEO 4.5 Curri, Vittorio Tu.2.B.5 / Tu.3.D.4 Cerutti, Isabella Th.2.P2.SC4.10 Czegledi, Cristian W.4.P1.SC3.9 / Th.2.P2.SC3.5 Chagnon, Mathieu Tu.3.B.3 Chaibi, Mohamed Essghair Tu.2.E.6 D Chan, Wai-Yip Tu.2.A.3 Da Ros, Francesco M.1.D.1 / W.1.D.1 / W.3.C.3 / Th.2.P2.SC4.9 Chanclou, Philippe WS3.6 / Tu.1.F.3 / W.3.E.2 / Th.1.D.4 / Dalla Santa, Marco Tu.3.F.2 Th.2.P2.SC3.3 / Th.2.P2.SC7.4 Dang, Anhong Th.2.P2.SC5.1 Chand, Naresh W.1.E.1 Dangui, Vinayak Tu.3.B.4 Chandrasekhar, Sethumadhavan M.2.E.2 / Tu.3.A.5 / W.1.C.2 / Dar, Ronen WS6.1 / W.1.C.2 / W.1.D.2 / W.1.D.5 W.1.D.2 / W.4.P1.SC5.10 /Th.2.P2.SC2.8 Davidson, Carl Tu.1.D.3 Chang, Chia-Ming M.2.E.2 / W.2.E.3 / Th.2.P2.SC2.8 De Angelis, Gabriele Tu.2.C.4 Chang, Gee-Kung W.4.P1.SC7.1 De Felipe, David W.2.E.2 Chang, Gk W.1.E.2 De Heyn, Peter W.4.P1.SC2.8 Chang, Sun Hyok Tu.2.D.3 de Jongh, Koen W.3.B.4 Charbonnier, Philippe Tu.1.C.4 de Valicourt, Guilhem M.2.E.2 / W.2.E.3 / Th.2.P2.SC2.2 / Chardonnet, Chriistian CLEO 1.4 Th.2.P2.SC2.8 Charlet, Gabriel Tu.1.E.5 de Waardt, Huug Tu.2.D.1 / W.3.D.3 / W.4.P1.SC3.4 / W.4.P1.SC4.14 Charlet, Gabriel Tu.1.E.1 / Tu.3.B.5 Debregeas-Sillard, Helen M.1.E.5 Charlton, Douglas Tu.2.C.3 / W.4.P1.SC5.15 Delbue, Roger M.1.C.5 Che, Di Tu.1.C.1 / Th.2.P2.SC7.3 Delezoide, Camille WS 2.1 Cheben, Pavel CLEO 3.1 Delgado Mendinueta, Jose Manuel Tu.1.D.2 / Th.2.P2.SC4.8 Chekhovskoy, Igor CLEO 1.2 Denz, Cornelia CLEO 3.5 Chembo, Yanne CLEO 4.1 DePedro, Hector Th.2.P2.SC5.2 57 Author List Author Session No. Author Session No. D‘Errico, Antonio W.4.P1.SC4.2 Faralli, Stefano Th.2.P2.SC4.10 Dharmaweera, Madushanka Th.2.P2.SC6.5 Fasiello, Annalaura W.4.P1.SC1.5 Di Pasquale, Fabrizio W.3.F.1 Fatome, Julien CLEO 4.3 / CLEO 4.5 Dianov, Evgeny W.4.P1.SC1.4 Feder, Kenneth W.1.B.3 Dias Garcia, Joaquim Th.2.P2.SC4.3 Fedoruk, Mikhail CLEO 1.2 Dias, Frederic CLEO 5.2 Fehenberger, Tobias M.1.D.4 / W.1.D.1 / W.1.D.4 / M.1.D.5 / W.2.C.5 Ding, Yunhong Th.2.P2.SC4.9 Fei, Yue W.4.P1.SC4.6 Diniz, Júlio Th.2.P2.SC3.2 Feiste, Uwe W.3.D.3 Dippon, Thomas M.2.C.3 / W.4.P1.SC4.13 Feng, Zhenhua W.4.P1.SC4.3 Dischler, Roman W.2.D.5 / W.4.P1.SC3.5 Fernandez de Jauregui Ruiz, Ivan Tu.3.B.5 Dittmann, Lars M.2.F.1 Fernández-Palacios, Juan Tu.1.B.3 / W.4.P1.SC6.7 / Th.2.P2.SC6.4 Djordjevic, Ivan Th.2.P2.SC3.12 Fernández-Palacios, Juan Pedro Tu.1.B.1 Djupsjöbacka, Anders W.4.P1.SC4.3 Ferran, J. W.1.F.5 Dochhan, Annika WS3.5 / Tu.3.C.4 / W.3.D.5 / Th.1.C.1 Ferreira, Filipe Tu.1.E.4 / Tu.2.D.2 Doerr, Christopher WS5.12 Ferreira, Ricardo W.4.P1.SC3.3 Doggart, Clay W.4.P1.SC5.13 Finot, Christophe CLEO 2.2 / CLEO 4.3 Dohi, Keisuke W.2.C.3 / Th.2.P2.SC3.7 Fiol, Gerrit Tu.3.A.1 Dong, Po M.2.E.2 / Tu.3.A.5 / W.2.E.3 / Th.2.P2.SC2.8 Fiorani, Matteo M.2.F.2 / Th.1.D.6 Doran, Nick Th.2.P2.SC2.1 Firstov, Sergei W.4.P1.SC1.4 Dou, Liang M.1.B.2 / Tu.2.C.1 / Th.2.P2.SC4.5 Fischer, Ingo CLEO 2.1 Downie, John Th.2.P2.SC5.2 Fischer, Johannes W.1.C.4 Draper, Stark W.2.C.2 Fludger, Chris Tu.2.A.2 / W.4.P1.SC3.6 Drenksi, Tomislav W.3.D.3 Fontaine, Nick WS1.6 Dris, Stefanos Tu.3.A.1 Fontaine, Nicolas M.1.C.5 / Tu.2.D.3 / W.2.B.5 / W.2.E.3 / Th.1.B.1 Du, Jing W.4.P1.SC2.10 / Th.2.P2.SC4.15 Forchhammer, Soren M.1.D.1 / W.1.C.5 / W.1.D.1 / W.3.C.3 Duan, Guang-Hua WS5.1 / WS 5.1 / M.2.E.1 / M.2.E.3 / Th.2.P2.SC4.9 Forestieri, Enrico Th.2.P2.SC3.10 Ducros, Nicolas WS4.6 Forghieri, Fabrizio W.1.D.3 Dudley, John CLEO 5.2 Forni, Federico Th.2.P2.SC7.8 Dümler, Ulrich M.1.C.4 Forns, Xavier W.1.F.5 Dupas, Arnaud W.1.F.6 / Th.1.E.1 / Th.1.E.2 Forysiak, Wladek Th.2.P2.SC2.1 Dupiol, Richard CLEO 1.3 Fougstedt, Christoffer Th.2.P2.SC5.10 Dupuy, Jean-Yves M.2.B.2 / M.1.C.2 / M.1.C.5 / M.2.C.1 / Tu.1.C.4 Fournier, Maryse W.3.F.1 Duthel, Thomas W.4.P1.SC3.6 Foursa, Dmitri Tu.1.D.3 / W.3.D.4 Duval, Bernadette Tu.1.C.4 Fresi, Francesco Th.2.P2.SC3.10 / Th.2.P2.SC4.7 Dvoretskiy, Dmitriy CLEO 4.4 Freude, Wolfgang Tu.3.A.3 / Tu.3.E.3 / W.3.F.4 / Th.2.P2.SC2.7 Friis, Søren Tu.2.D.4 E FU, Fisher Tu.1.B.3 Effenberger, Frank WS3.7 / W.1.E.1 / W.2.A.1 Fu, Songnian W.2.D.2 / W.4.P1.SC4.3 Eggleston, Michael Th.2.P2.SC2.2 Fujii, Takuro Tu.3.A.2/ W.4.P1.SC2.1 Eggleton, Benjamin Th.2.P2.SC3.1 Fujikata, Junichi Tu.3.A.4 Eich, Pascal CLEO 2.5 Fujikawa, Kenji W.4.P1.SC6.2 Eigner, Christof CLEO 2.6 Fujisawa, Shinsuke Tu.2.B.4 Eiselt, Michael M.2.D.1 / Tu.3.C.4 / W.3.D.5 / Th.1.C.1 Fujisawa, Takeshi Th.2.P2.SC2.7 Eiselt, Nicklas M.2.B.5 / M.2.D.1 / Tu.3.C.4 / W.3.D.5 / Th.1.C.1 Fujiwara, Masamichi M.1.E.4 / W.3.E.3 Elbers, Jörg-Peter WS5.11 / Tu.3.C.4 / W.3.D.5 Fujiwara, Naoki Tu.2.E.5 Eliasson, Henrik Th.1.A.3 Fujiwara, Toshihito Th.2.P2.SC7.6 Ellermeyer, Tobias M.1.C.4 Fukui, Takayoshi M.2.B.4 Ellis, Andrew WS6.9 / Tu.1.E.4 / Tu.2.D.2 / Tu.3.B.2 / Fukumoto, Ryohei W.2.B.2 Tu.3.C.1 / Th.2.P2.SC3.1 / Th.2.P2.SC5.16 Fukutoku, Mitsunori M.2.D.4 / Tu.1.C.3 / W.4.P1.SC2.7 Elschner, Robert W.2.F.4 / W.3.C.1 Fumagalli, Andrea W.4.P1.SC4.6 Elser, Dominique W.4.P1.SC5.3 Furdek, Marija W.4.P1.SC6.1 El-Taher, Atalla Th.2.P2.SC2.1 Fürst, Walter W.4.P1.SC2.2 Emmerich, Robert W.1.C.4 Furukawa, Hideaki W.4.P1.SC6.2 / Th.2.P2.SC4.8 Enbutsu, Koji W.4.P1.SC2.4 Füser, Heiko Th.2.P2.SC2.10 Engenhardt, Klaus M.2.C.4 Erasme, Didier W.3.E.2 / Th.2.P2.SC7.4 G Ercan, Burcu Tu.2.D.3 / Th.1.B.1 Gaiarin, Simone M.2.C.4 / W.4.P1.SC5.9 Eriksson, Tobias M.1.D.3 / M.1.D.5 / Tu.1.E.3 / W.1.D.4 Gaimard, Quentin Tu.3.C.1 Erkilinc, M. Sezer M.1.E.2 / M.2.B.1 / M.2.D.6 / Th.2.P2.SC3.11 Gajda, Andrzej W.3.C.2 Erven, Christopher W.1.F.2 Galdino, Lídia M.2.B.1 / W.4.P1.SC5.11 / Th.1.A.2 Eschner, Juergen CLEO 2.5 Galili, Michael M.1.D.1 / M.2.F.1 / Tu.2.F.4 / W.1.D.1 / W.3.C.3 Essiambre, Rene WS6.2 / W.2.B.5 Galimberti, Gabriele Th.2.P2.SC6.1 Estaran, Jose Manuel M.2.B.2 / M.2.C.1 Gallazzi, Francesca CLEO 5.3 Gallet, Antonin M.2.E.3 / Th.2.P2.SC4.9 F Galve Higon, Jose Manuel Th.2.P2.SC2.4 Fabert, Marc CLEO 1.3 Gambini, Fabrizio W.3.F.1 / Th.2.P2.SC4.10 Fabrega, Josep W.1.F.3 / Th.2.P2.SC6.3 Gao, Guanjun Th.2.P2.SC3.8 / Th.2.P2.SC6.2 Fabregas, Guiu Tu.1.B.3 Gao, Jeffrey M.0.2 Fagertun, Anna M.2.F.1 Gao, Jianhe W.4.P1.SC7.10 Fallahpour, Ahmad Th.2.P2.SC5.3 / W.3.C.4 Gao, Xinlu W.4.P1.SC4.1 Fan, Xinyu Th.2.P2.SC2.2 Gao, Yuliang M.2.C.2 Fan, Yangyang Th.2.P2.SC4.5 Gapontsev, Valentin CLEO 3.2 58 Author List Author Session No. Author Session No. Garcia Lopez, Iria W.2.E.5 Hansson, Tobias CLEO 4.5 Garner, Steven Th.2.P2.SC5.2 Hao, Zhibiao W.4.P1.SC2.5 Garrich, Miquel W.4.P1.SC4.6 Happach, Magnus W.2.E.2 Gasulla, Ivana Th.2.P2.SC2.4 / Th.2.P2.SC4.2 Hara, Kazutaka W.4.P1.SC7.4 Gatto, Alberto Th.2.P2.SC7.11 Harai, Hiroaki W.4.P1.SC6.2 Gaudino, Roberto Tu.2.B.5 / Tu.3.D.4 / W.4.P1.SC7.6 Harako, Koudai W.4.P1.SC5.4 Gavioli, Giancarlo WS6.2 Harper, Paul Tu.3.B.2 / CLEO 5.3 / Th.2.P2.SC5.16 Geiselmann, Michael WS4.5 / CLEO 4.2 Harstead, Ed Tu.3.F.5 / Th.2.P2.SC7.1 Geisler, Alexander Th.2.P2.SC5.8 Hartmann, Wladislaw Tu.3.A.3 Geisler, Tommy W.1.B.2 Hasebe, Koichi W.4.P1.SC2.1 Geng, Zihan W.4.P1.SC2.9 Hasegawa, Hiroshi W.2.F.2 / W.4.P1.SC4.7 / W.4.P1.SC6.3 / Th.1.E.3 Genty, Goëry CLEO 5.2 Hashiguchi, Tomohiro W.3.A.3 Gerola, Matteo W.1.F.5 / Th.2.P2.SC6.1 Hashimoto, Toshikazu Tu.3.C.2 / W.4.P1.SC2.7 / Th.1.B.2 Gerstel, Ori Tu.1.B.3 Hattori, Kyota W.4.P1.SC6.4 Geyer, Jonas M.2.B.3 Hayashi, Tetsuya W.2.B.5 Ghasemi, Saeed M.1.E.5 He, Yu Th.1.B.4 Ghazisaeidi, Amirhossein Tu.3.B.5 / Th.2.P2.SC5.12 He, Zuyuan Th.2.P2.SC2.2 Ghelfi, Paolo Tu.2.E.1 Heine, Frank W.4.P1.SC5.3 Giacoumidis, Elias Th.2.P2.SC3.1 Herink, Georg CLEO 5.1 Giesecke, Anna Lena Th.2.P2.SC2.10 Hermann, Harald CLEO 2.6 Giggenbach, Dirk W.4.P1.SC5.2 Hermann, Peter W.4.P1.SC3.6 Girard, Nils M.2.E.3 Herzog, Bastian CLEO 3.3 Givehchi, Mehrdad M.2.B.3 Hilgendorf, Rolf Tu.3.C.3 Gladisch, Andreas Th.1.E.4 Hirai, Riu M.2.B.4 Gnauck, Alan M.2.A.1 / Tu.3.A.5 / W.1.D.2 Hirano, Akira Tu.3.D.1 / W.2.D.3 / W.3.D.2 / W.4.P1.SC4.4 / Goeger, Gernot Th.2.P2.SC3.9 Th.2.P2.SC5.4 Goi, Kazuhiro W.2.E.4 Hirano, Takuya W.4.P1.SC5.14 Goix, Michel Tu.1.C.4 Hirooka, Toshihiko M.1.C.3 / W.4.P1.SC5.4 / W.4.P1.SC5.14 Golowich, Steven W.3.B.5 Hisano, Daisuke Th.1.D.5 Gomes, Nathan WS3.8 Hoang, Thang W.2.D.2 Gomez Saavedra, Braulio W.4.P1.SC2.2 Hofmann, Werner W.2.E.2 Gonda, Tomohiro W.2.B.1 Hohenleitner, Robert Tu.3.C.4 / Th.1.C.1 Gonnet, Cedric Tu.2.D.3 Honda, Kazuaki Th.1.D.3 González de Dios, Oscar Tu.1.B.4 / W.4.P1.SC6.7 Honecker, Jörg Tu.2.E.3 Gopalan, Abishek W.4.P1.SC6.6 Hong, Sung Tu.1.F.3 Gordienko, Vladimir Th.2.P2.SC2.1 Hoose, Tobias W.3.F.4 Gorodetsky, Michael CLEO 4.2 Horak, Peter Tu.2.D.4 Gravey, Annie Tu.3.D.3 Horikoshi, Kengo Tu.1.C.3 / W.2.D.3 / W.3.D.2 / Th.2.P2.SC5.4 Gravey, Philippe Tu.3.D.3 Hoshida, Takeshi M.1.B.2 / M.1.B.3 / Tu.2.C.1 / Tu.2.C.2 / Gregg, Patrick W.3.B.5 W.2.F.4 / W.3.C.1 / Th.1.A.1 / Th.2.P2.SC4.5 Greulich, Peter W.4.P1.SC5.3 Hosokawa, Kohei Th.2.P2.SC5.15 Griesser, Helmut M.2.B.5 / M.2.D.1 / Tu.3.C.4 / W.3.D.5 / Th.1.C.1 Houtsma, Vincent Tu.3.F.5 / W.2.A.2 / Th.2.P2.SC7.1 Grobe, Klaus Tu.1.F.1 Hsu, Yung Th.2.P2.SC7.7 Gross, Simon Th.2.P2.SC2.9 Hu, Hao W.1.E.5 / W.3.C.3 Gruner, Marko Tu.3.A.1 / W.4.P1.SC2.2 / Th.2.P2.SC2.4 Hu, Qian M.1.C.4 / W.2.D.5 Grüner-Nielsen, Lars W.1.B.2 Hu, Rong Th.2.P2.SC3.8 Grzybowski, Kamil Tu.1.F.3 Hu, Ting-Chen Th.2.P2.SC2.2 Gu, Wanyi W.4.P1.SC4.1 Hu, Weisheng W.3.E.1 Guan, Kyle W.4.P1.SC5.10 / Th.2.P2.SC6.6 Hu, Xiao Th.2.P2.SC3.13 Guetlich, Bjorn W.4.P1.SC5.3 Hu, Xiaofeng Tu.3.F.3 Gui, Tao W.4.P1.SC4.8 Huang, Bin Tu.2.D.3 / Th.1.B.1 Guillo, Laurent Th.2.P2.SC7.4 Huang, Duanni W.3.F.3 Gunkel, Matthias WS2.9 Huang, Guoxiu Th.2.P2.SC4.12 Günthner, Kevin W.4.P1.SC5.3 Huang, Shanguo W.4.P1.SC4.1 Guo, Hairun CLEO 4.2 Huang, Wan-Jou Th.2.P2.SC4.1 Guryanov, Aleksey W.4.P1.SC1.4 Huang, Yishen Tu.2.B.3 Gustavsson, Johan Th.1.C.3 Huang, Yuanda Th.2.P2.SC5.5 Gutiérrez, Fernando Tu.3.C.1 Hughes, Adam W.2.F.1 Gutterman, Craig Tu.2.B.3 Hugues-Salas, Emilio Tu.1.B.5 / W.1.F.2 / Th.1.E.2 Hurley, Jason Th.2.P2.SC5.2 H Habel, Kai W.4.P1.SC5.7 I Haglund, Emanuel Th.1.C.3 Idler, Wilfried M.1.C.4 / M.1.D.2 /M.1.D.3 / Tu.3.E.2 / W.1.C.1 / W.2.D.5 Haglund, Erik Th.1.C.3 Igarashi, Koji M.2.A.3 / W.2.C.4 Haigh, Paul Anthony W.1.F.2 Iida, Daisuke W.1.B.1 Hamaoka, Fukutaro Tu.1.C.3 / Tu.3.C.2 / W.3.D.2 / W.2.D.3 / Ikeda, Kazuhiro W.2.F.2 / W.4.P1.SC2.6 Th.2.P2.SC5.4 Ikeuchi, Tadashi W.3.C.4 / Th.2.P2.SC5.3 Hammad, Ali Th.1.E.2 Ikuma, Yuichiro W.4.P1.SC2.7 / Th.1.B.2 Han, Jaehoon Tu.3.A.4 Illarionov, Mikhail W.2.E.4 Han, Sang-Kook Th.2.P2.SC7.9 Imajuku, Wataru Tu.3.D.1 Han, Yanjun W.4.P1.SC2.5 Imamura, Katsunori W.2.B.1 Hanik, Norbert W.1.D.4 / W.3.D.3 Imbrock, Jörg CLEO 3.5 59 Author List Author Session No. Author Session No. Immonen, Marika Th.2.P2.SC4.13 Th.2.P2.SC7.2 Imran, Muhammad W.4.P1.SC4.2 Kanno, Erina W.4.P1.SC2.1 Inagaki, Keizo W.4.P1.SC4.5 Kaptan, Yücel CLEO 3.3 Inoue, Takashi Th.2.P2.SC3.4 Karasik, Valery CLEO 4.4 Inui, Tetsuro Tu.3.D.1 Karinou, Fotini M.2.C.3 / W.4.P1.SC4.13 / W.4.P1.SC5.5 Iovanna, Paola Tu.1.B.4 Karlsson, Magnus Tu.1.E.3 / W.1.B.2 / W.1.D.4 / W.4.P1.SC1.7 / Ip, Ezra WS1.2 Th.2.P2.SC3.5 / Th.2.P2.SC4.6 / Th.2.P2.SC5.10 / Iqbal, Md Asif CLEO 5.3 Th.2.P2.SC6.5 Ishihara, Hiroki W.2.E.4 Kasai, Keisuke M.1.C.3 / W.4.P1.SC5.6 / W.4.P1.SC5.14 Ishii, Hiroyuki Tu.2.E.5 Kashi, Aazar W.4.P1.SC5.8 / Th.2.P2.SC5.9 Ishii, Kenji W.2.C.3 Kashio, Norihide Tu.3.A.2 Ishikawa, Mitsuteru Tu.3.A.2 Katagiri, Toru Tu.2.B.1 / W.3.A.3 Ishikawa, Takashi Th.2.P2.SC5.15 Katayama, Masaru W.4.P1.SC6.4 Ishikura, Norihiro W.2.E.4 Kato, Tomoyuki Tu.2.C.2 / W.2.F.4 / W.3.C.1 Isono, Yuma Th.1.E.3 Katsumata, Takaaki Th.1.D.1 Ito, Fumihiko W.1.B.1 Kawaguchi, Yu M.2.A.2 / W.2.B.1 Ito, Toshiharu Th.2.P2.SC5.15 Kawahara, Hiroki M.2.D.4 Ito, Yusaku W.4.P1.SC6.3 Kawai, Shingo M.2.D.4 Itoh, Mikitaka Tu.2.E.5 / W.4.P1.SC2.7 / Th.1.B.2 Kawakami, Hiroto W.4.P1.SC4.4 Ives, David M.1.B.1 / Th.1.A.2 Kawanishi, Tetsuya W.4.P1.SC4.5 / W.4.P1.SC7.5 / Th.2.P2.SC2.6 / Izutsu, Masayuki Th.2.P2.SC2.6 Th.2.P2.SC7.2 Kawashima, Hitoshi W.2.F.2 / W.4.P1.SC2.6 J Kazama, Takushi W.4.P1.SC2.4 Jackson, Chris W.1.F.4 Ke, Changjian W.2.D.2 Jacobfeuerborn, Bruno M.0.1 Keil, Norbert W.2.E.2 Jacobsen, Gunnar M.2.C.4 / W.4.P1.SC4.3 / W.4.P1.SC5.9 Kelly, Brian WS4.2 / M.2.D.6 Jalali, Bahram CLEO 5.1 Kelly, Colin Th.1.E.5 Jana, Mrinmoy W.4.P1.SC3.11 Kemal, Juned Tu.3.E.3 Jankowski, Andrzej Tu.2.E.4 Kennard, Jake W.1.F.2 Jaouën, Yves Th.2.P2.SC3.11 Kervella, Gael Tu.2.E.4 Jensen, Rich W.2.F.1 Keyvaninia, Shahram M.2.E.1 Jepsen, Peter Uhd W.1.E.5 Khalid, Amir Masood W.1.E.3 / W.4.P1.SC4.9 Ji, Honglin W.3.E.1 Khan, Imran W.4.P1.SC5.3 Ji, Mengxi Th.2.P2.SC3.13 Khani, Besher Tu.2.E.3 Ji, Yuefeng Th.2.P2.SC7.5 Khanna, Ginni W.3.D.3 / Th.2.P2.SC5.7 Jia, Shi W.1.E.5 Khebbache, Selma W.1.F.6 Jia, Songhao W.4.P1.SC7.11 Khodakarami, Hamid Tu.1.C.1 Jian, Pu W.4.P1.SC4.10 Khopin, Vladimir W.4.P1.SC1.4 Jiang, Ning Th.2.P2.SC7.12 Kibler, Bertrand CLEO 4.3 / CLEO 4.5 Jiang, Xinhong Th.1.B.3 / Th.1.B.4 Kieninger, Clemens Tu.3.A.3 / Th.2.P2.SC2.7 Jiang, Zhiping Th.2.P2.SC5.13 Kikuchi, Nobuhiko M.2.B.4 Jignesh, Jokhakar W.4.P1.SC3.12 Kikuchi, Nobuhiro Tu.3.A.2 Jiménez, Felipe W.4.P1.SC6.7 Killey, Robert WS6.2 / M.1.E.2 / M.2.B.1 / M.2.D.6 / W.4.P1.SC3.9 / Jiménez, Tamara W.4.P1.SC6.7 W.4.P1.SC5.11 / Th.1.A.2 / Th.2.P2.SC3.11 Jin, Cang M.2.A.5 / Tu.2.D.3 / Th.1.B.1 Kim, Byung Gon W.4.P1.SC7.2 / W.4.P1.SC7.8 Jin, Xianqing W.3.B.2 Kim, Chang-Hun Th.2.P2.SC7.9 Jinno, Masahiko W.3.A.1 Kim, Hoon W.4.P1.SC7.2 / W.4.P1.SC7.8 Jones, Rasmus Th.2.P2.SC3.2 Kim, Kwangwoong Tu.3.A.5 / W.2.E.3 / Th.2.P2.SC2.2 Jopson, Robert M.2.A.1 Kim, Sang-Yuep M.1.E.4 Jorge, Filipe M.2.B.2 / Tu.1.C.4 / M.2.C.1 / M.1.C.2 / M.1.C.5 Kippenberg, Tobias Tu.3.E.3 / CLEO 4.2 / Th.2.P2.SC2.5 Jue, Jason Th.2.P2.SC6.2 Kissinger, Dietmar W.2.E.5 / Th.2.P2.SC4.14 Jung, Sang-Min Th.2.P2.SC7.9 Kitayama, Ken‘ichi W.2.E.4 Jung, Sun-Young Th.2.P2.SC7.9 Kito, Chihiro Th.2.P2.SC2.3 Jung, Yongmin WS1.5 / Tu.2.D.4 / W.2.B.4 / W.3.B.2 Klaus, Werner M.1.F.3 / Tu.1.D.2 Jungnickel, Volker WS3.1 / W.4.P1.SC5.7 Kleinert, Moritz W.2.E.2 Kleis, Sebastian Tu.3.E.4 K Klonidis, Dimitrios M.1.F.1 / M.1.F.4 / Tu.1.B.1 / Tu.3.D.5 Kablukov, Sergey CLEO 5.5 Klötzer, Robert Tu.3.A.1 Kadohata, Akihiro Tu.3.D.1 Knoll, Dieter W.2.E.5 / Th.2.P2.SC4.14 Kaiser, Ronald Th.2.P2.SC2.4 / Th.2.P2.SC4.2 Kobayashi, Takashi W.4.P1.SC7.2 / W.4.P1.SC7.8 Kakande, Joseph Th.2.P2.SC6.6 / Th.2.P2.SC6.7 Kobayashi, Takayuki Th.1.D.3 / Th.1.D.5 Kakitsuka, Takaaki W.4.P1.SC2.1 Koda, Katsutoshi W.4.P1.SC6.4 Kakkar, Aditya M.2.C.4 Kohtoku, Masaki Tu.3.A.2 Kamalian, Morteza Tu.3.B.2 / CLEO 2.4 / Th.2.P2.SC5.16 Koike-Akino, Toshiaki W.2.C.1 / W.2.C.2 / W.2.D.1 / Th.2.P2.SC3.7 / Kamchevska, Valerija M.2.F.1 Th.2.P2.SC5.11 Kanazawa, Shigeru Tu.2.E.5 / Tu.3.A.2 / Tu.3.C.2 Kojima, Keisuke W.2.C.1 / W.2.C.2 / W.2.D.1 / Th.2.P2.SC3.7 / Kandappan, Parthiban W.4.P1.SC6.6 Th.2.P2.SC5.11 Kaneda, Noriaki M.2.D.3 Kolarczik, Mirco CLEO 3.3 Kang, Jian W.3.F.2 Koma, Ryo M.1.E.4 Kang, Qiongyue Tu.2.D.4 / W.3.B.2 Konczykowska, Agnieszka M.1.C.2 / M.1.C.5 / M.2.B.2 / M.2.C.1 Kani, Jun-ichi M.1.E.4 Kono, Naoto W.1.B.1 Kanno, Atsushi W.4.P1.SC4.5 / W.4.P1.SC7.5 / Th.2.P2.SC2.6 / Koonen, Ton Tu.2.C.5 / Tu.2.D.1 / Tu.2.E.2 / Tu.3.F.4 / W.1.E.3 / 60 Author List Author Session No. Author Session No. W.4.P1.SC3.4 / W.4.P1.SC4.9 / W.4.P1.SC4.14 / Levaufre, Guillaume M.2.E.3 Th.2.P2.SC7.8 Li, Borui Tu.3.A.5 / W.1.D.2 Koos, Christian Tu.3.A.3 / Tu.3.E.3 / W.3.F.4 / Th.2.P2.SC2.7 Li, Cai W.3.E.1 Kopp, Christophe W.3.F.1 Li, Chuandong W.4.P1.SC3.8 / Th.2.P2.SC5.13 Kopp, Victor W.4.P1.SC2.8 Li, Fan W.3.D.1 Kordts, Arne Tu.3.E.3 / Th.2.P2.SC2.5 Li, Guifang Tu.2.F.5 Korotky, Steve Th.2.P2.SC6.7 Li, Hongtao W.4.P1.SC2.5 Koshiba, Masanori Th.2.P2.SC2.7 Li, Hui W.4.P1.SC7.11 Kosiankowski, Dirk Th.1.E.4 Li, Huihui M.1.B.2 / Th.2.P2.SC4.12 Kottke, Christoph W.4.P1.SC5.7 Li, Jie M.2.C.4 Kouloumentas, Christos WS2.5 Li, Liangchuan Th.2.P2.SC5.5 Kousuke, Komaki Th.2.P2.SC4.5 Li, Ruijie Th.2.P2.SC5.1 Krapick, Stephan CLEO 2.6 Li, Shengping W.4.P1.SC7.3 Krauss, Sandro Tu.1.F.1 Li, Shuhui Th.2.P2.SC4.15 Kremp, Tristan W.1.B.3 Li, Wei Tu.2.F.2 Kristensen, Poul W.3.B.5 Li, Xiang W.3.E.1 Kroesen, Sebastian CLEO 3.5 Li, Xinying M.2.D.5 / W.1.E.4 / W.3.D.1 Kroh, Marcel W.2.E.5 / Th.2.P2.SC4.14 Li, Yan Tu.2.F.2 Krombholz, Bernd W.3.D.3 Li, Zhe M.2.B.1 Kropp, Joerg W.4.P1.SC4.12 / Th.2.P2.SC4.11 Li, Zhengxuan W.3.E.1 Krupa, Katarzyna CLEO 1.3 Liao, Peicheng Th.2.P2.SC2.5 / Th.2.P2.SC5.3 Kruse, Regina CLEO 2.6 Liao, Peicheng W.3.C.4 Krylov, Alexander CLEO 4.4 Liebig, Erik W.3.C.2 Kubo, Kazuo W.2.C.3 Liga, Gabriele WS6.13 / M.1.D.4 / Th.1.A.2 / W.4.P1.SC3.9 / Kuchta, Daniel Tu.1.A.2 W.4.P1.SC5.11 / Th.2.P2.SC3.5 Kudo, Hiroshi Th.1.B.2 Lihachev, Grigoriy CLEO 4.2 Kuo, Bill Ping Piu Tu.3.B.4 Lillieholm, Mads Tu.2.F.4 Kupfer, Theo Tu.2.A.2 Lin, Changyu Th.2.P2.SC3.12 Kupfer, Theodor W.4.P1.SC3.6 Lin, Huafeng W.4.P1.SC7.10 Kurtz, Felix CLEO 5.1 Lin, Rui W.4.P1.SC4.3 Kurz, Christoph CLEO 2.5 Lingnau, Benjamin CLEO 3.3 Kuschnerov, Maxim WS2.3 Liotta, Antonio W.4.P1.SC4.9 Kutuvantavida, Yasar Tu.3.A.3 / W.3.F.4 / Th.2.P2.SC2.7 Liow, Tsung-Yang W.2.E.4 Kuwahara, Shoichiro W.4.P1.SC4.4 Lischke, Stefan W.2.E.5 / Th.2.P2.SC4.14 Kwong, Dim-Lee W.2.E.4 Liu, Boyu Th.1.B.3 / Th.1.B.4 Liu, CheYu M.2.F.3 L Liu, Deming W.2.D.2 / W.4.P1.SC4.3 La Fauci, Domenico Th.2.P2.SC6.1 Liu, Gordon M.2.D.2 / Tu.3.F.1 / WS 3.1 / Th.1.C.2 / Th.2.P2.SC2.3 / Laadung, Taavi Th.1.A.3 Th.2.P2.SC5.6 Labroille, Guillaume W.4.P1.SC4.10 Liu, Huiyun W.2.E.1 Lach, Eugen M.1.D.2 Liu, Jun W.4.P1.SC2.10 / Th.2.P2.SC4.15 Lampe, Lutz W.4.P1.SC3.11 Liu, Jun-jie Th.2.P2.SC7.7 Lamponi, Marco Tu.2.E.4 Liu, Junqiu CLEO 4.2 Landi, Giada W.1.F.4 Liu, Lei Th.2.P2.SC2.3 Landry, Gary Th.1.C.5 Liu, Qingwen Th.2.P2.SC2.2 Lange, Christoph Th.1.E.4 Liu, Tao Th.2.P2.SC3.12 Lange, Sophie Th.2.P2.SC2.4 Liu, Xiang WS3.2 / W.1.E.1 / W.4.P1.SC7.3 / W.4.P1.SC7.10 / Langenhagen, Henning M.1.C.4 Th.2.P2.SC5.13 Lankl, Berthold Th.2.P2.SC5.7 Liu, Xianwen W.4.P1.SC2.5 Laperle, Charles W.4.P1.SC5.8 / W.4.P1.SC5.13 / W.4.P1.SC5.15 Liu, Xiaoli M.2.F.3 LaRochelle, Sophie M.2.A.5 Liu, Yifan M.1.F.2 Larsson, Anders Th.1.C.3 / Th.2.P2.SC4.6 Liu, Zhixin M.2.D.6 Larsson-Edefors, Per Th.2.P2.SC5.10 Llorente, Roberto W.4.P1.SC4.13 Lau, Alan Pak Tao W.4.P1.SC4.8 Lo, Patrick W.2.E.4 Lauermann, Matthias Tu.3.A.3 / W.3.F.4 / Th.2.P2.SC2.7 Lobo, Sebastien Tu.2.E.6 Lavery, Domanic M.1.D.4 / M.1.E.2 / W.2.C.1 / Th.2.P2.SC3.5 Long, Yun Th.2.P2.SC3.13 Lavrencik, Justin Th.1.C.5 Lopez, Olivier CLEO 1.4 Layec, Patricia W.1.F.6 / W.4.P1.SC3.7 / Th.1.E.2 / Th.1.E.1 Lopez, Victor Tu.1.B.1 / Tu.1.B.2 / Tu.1.B.3 / Tu.1.B.4 / W.4.P1.SC6.7 / Le Cocq, Guillaume W.4.P1.SC1.3 Th.2.P2.SC6.4 Le Guyader, Bertrand Th.2.P2.SC7.4 Lord, Andrew W.1.F.2 / W.4.P1.SC4.2 Le, Son CLEO 2.4 / Tu.3.B.2 / Th.2.P2.SC3.1 / Th.2.P2.SC5.16 Lorences-Riesgo, Abel Tu.1.E.3 / W.4.P1.SC1.7 Ledentosov, Nikolay Th.2.P2.SC4.11 Lourdiane, Mounia Tu.2.B.3 Ledentsov, Nikolai W.4.P1.SC4.12 Love, John Th.2.P2.SC2.9 Lee, Jeffrey M.2.D.3 / Th.2.P2.SC2.2 Lowery, Arthur W.2.D.4 / W.4.P1.SC2.9 / W.4.P1.SC3.2/ Lee, Young Th.2.P2.SC7.5 W.4.P1.SC3.12 Lei, Wanlu Th.2.P2.SC4.13 Lu, Biao W.4.P1.SC6.6 Lelarge, Francois M.2.E.1 / M.2.E.3 / Tu.3.C.1 Lu, Chao WS3.4 / W.4.P1.SC4.8 / Th.2.P2.SC4.11 Lemonnier, Olivier W.3.F.1 Lu, Feng W.4.P1.SC7.1 Lengyel, Tamás Th.2.P2.SC4.6 LU, Guo-Wei Tu.1.E.2 Leon-Saval, Sergio Tu.2.F.5 Lu, Xiaofeng Tu.1.C.2 Lerch, Holger Th.2.P2.SC2.10 Lu, Yanzhao Th.2.P2.SC5.5 Leuchs, Gerd W.4.P1.SC5.3 Lüdge, Kathy CLEO 3.3 61 Author List Author Session No. Author Session No. Luís, Ruben M.1.F.3 / Tu.1.D.2 Millot, Guy CLEO 1.3 / CLEO 4.3 / CLEO 4.5 Lundberg, Lars Th.2.P2.SC5.10 Mills, Greg Th.2.P2.SC5.2 Luo, Jun Th.2.P2.SC4.11 Minoguchi, Kyo Th.2.P2.SC5.4 Luo, Kai-Hong CLEO 2.6 Mirasso, Claudio CLEO 2.1 Luo, Ming Th.2.P2.SC3.8 Mirov, Mike CLEO 3.2 Luo, Yi W.4.P1.SC2.5 Mirov, Sergey CLEO 3.2 Lv, Yunxin Th.2.P2.SC7.12 Mitra, Jeebak W.4.P1.SC3.8 / W.4.P1.SC3.11 Miura, Hiroshi M.1.E.1 / Th.1.D.1 / Th.2.P2.SC3.7 / Th.2.P2.SC5.11 M Miyabe, Masatake Tu.2.B.1 Ma, Xiaoli W.4.P1.SC7.1 Miyamoto, Yutaka Tu.2.E.5 / Tu.3.C.2 / W.2.B.2 / W.3.D.2 / Ma, Yanan Th.2.P2.SC4.11 W.2.D.3 / W.4.P1.SC2.4 / W.4.P1.SC2.7 Mac Suibhne, Naoise WS4.7 / Tu.1.E.4 / Tu.2.D.2 Miyazawa, Takaya M.1.F.3 Maeda, Koichi M.2.A.2 Mizumoto, Tetsuya W.3.F.3 Mahajan, Pravin W.4.P1.SC6.6 Mo, Q Tu.2.F.2 Maher, Robert M.1.D.4 / M.2.B.1 / W.2.C.1 / Th.1.A.2 Modotto, Daniele CLEO 4.5 Maho, Anaelle M.2.E.2 / M.2.E.5 Moehrle, Martin W.2.E.2 Mai, Christian W.2.E.5 Mohajerin-Ariaei, Amirhossein W.3.C.4 / Th.2.P2.SC5.3 / Th.2.P2.SC2.5 Make, Dalila M.2.E.3 / Th.2.P2.SC4.9 Molin, Denis Tu.2.D.3 / Tu.2.D.1 / W.3.B.3 / W.3.B.4 Malhouitre, Stéphane M.2.E.3 Möller, Michael M.1.C.4 Mallécot, Franck Tu.1.C.4 Monberg, Eric W.1.B.3 Man, Erik W.3.D.3 Monno, Roberto W.1.F.4 Manabe, Tetsuya W.1.B.1 / Th.2.P2.SC2.3 Montero, Rafael W.1.F.4 Manganelli, Costanza W.3.F.1 Monti, Paolo Tu.1.B.4 / Th.1.D.6 Maor, Itay Tu.1.B.3 Morandotti, Roberto CLEO 5.2 Mardoyan, Haik M.2.B.2 / M.2.C.1 Mori, Hideki M.1.E.4 Marhuenda, Jaume Tu.1.B.2 / Tu.1.B.5 / W.1.F.2 Mori, Kunihiko Tu.1.C.3 Marin, Pablo Tu.3.E.3 Mori, Takayoshi M.2.A.4 / W.2.B.3/ W.4.P1.SC1.2 Marquardt, Christoph W.4.P1.SC5.3 Mori, Yojiro W.4.P1.SC4.7 / W.4.P1.SC6.3 / W.2.F.2 / Th.1.E.3 Martelli, Paolo W.4.P1.SC1.5 Morikawa, Hiroyuki Tu.2.C.2 Martin, Eamonn Tu.3.C.1 Morioka, Toshio W.1.E.5 / W.2.B.2 Martinelli, Mario W.4.P1.SC1.5 / Th.2.P2.SC7.11 Morita, Itsuro Tu.1.B.2 / W.2.C.4 Martinez, Ricardo Tu.1.B.2 / W.1.F.1 / W.1.F.3 / Th.2.P2.SC6.4 Moriwaki, Osamu W.4.P1.SC2.7 Mastropaolo, Antonia M.1.F.4 Morizur, Jean-François W.4.P1.SC4.10 Masuda, Akira M.2.D.4 Morthier, Geert M.2.E.1 Masuko, Koichiro W.2.E.4 Morvan, Michel Tu.3.D.3 Matsuda, Keisuke Th.2.P2.SC3.7 / Th.2.P2.SC5.11 Moskalev, Igor CLEO 3.2 Matsuda, Toshiya W.4.P1.SC6.4 Muhammad, Ajmal W.4.P1.SC6.1 Matsui, Yasuhiro M.2.C.2 Mukaikubo, Masaru M.2.E.4 Matsumoto, Morio W.4.P1.SC1.1 Müller, Christian W.4.P1.SC5.3 Matsumoto, Wataru W.2.C.1 / W.2.C.2 / W.2.C.3 Müller, Philipp CLEO 2.5 Matsuo, Shinji Tu.1.A.1 / W.4.P1.SC2.1 Muñoz, Raul Tu.1.B.2 / W.1.F.1 / W.1.F.3 / Th.2.P2.SC6.4 Matsuo, Shoichiro Th.2.P2.SC2.7 Musumeci, Francesco Tu.1.F.1 / W.4.P1.SC7.9 Matsushita, Asuka W.3.D.2 / W.2.D.3 Myslivets, Evgeny Tu.3.B.4 Matsuura, Hiroyuki W.2.F.2 / W.4.P1.SC2.6 Mawatari, Hiroyasu Tu.3.A.2 N Maxim, Karpov Tu.3.E.3 / CLEO 4.2 / Th.2.P2.SC2.5 Nadal Reixats, Laia W.1.F.3 / Th.2.P2.SC6.3 Mayoral, Arturo Tu.1.B.2 / W.1.F.1 / Th.2.P2.SC6.4 Nagarajan, Gaya WS2.10 Mazur, Mikael Tu.1.E.3 / W.1.B.2 / W.1.D.4 Nagasaka, Kenshiro W.4.P1.SC1.1 Mazurczyk, Matthew Tu.1.D.3 / W.3.D.4 Nagasawa, Akiko Th.1.D.1 McCarthy, Mary Th.2.P2.SC3.1 Nagashima, Takuji W.2.B.5 Medra, Ahmed W.4.P1.SC3.11 Nagatani, Munehiko Tu.3.C.2 / W.2.D.3 / W.3.D.2 Megeed, Sharief W.1.E.1 Nagulapalli, Rajasekhar Th.2.P2.SC4.14 Mehta, Priyanth Tu.3.B.1 Najafi, Hossein W.4.P1.SC3.8 Mekhazni, Karim M.2.E.5 / Tu.1.C.4 Nakagawa, Goji Th.1.D.2 Mekonnen, Ketamaw W.1.E.3 / W.4.P1.SC4.9 Nakagawa, Masahiro W.4.P1.SC6.4 Melati, Daniele W.4.P1.SC2.3 Nakahara, Kouji Th.2.P2.SC2.5 Melikyan, Argishti W.2.E.3 Nakajima, Hirochika Th.2.P2.SC2.6 Melkumov, Mikhail W.4.P1.SC1.4 Nakajima, Kazuhide M.2.A.4 / W.2.B.3 / W.4.P1.SC1.2 Melloni, Andrea W.4.P1.SC2.3 Nakajima, Mitsumasa W.4.P1.SC2.7 / Th.1.B.2 Meloni, Gianluca Th.2.P2.SC3.10 / Th.2.P2.SC4.7 Nakamura, Masanori W.2.D.3 / W.3.D.2 Meltsin, Maxim Tu.3.C.3 Nakamura, Shigeru W.2.F.2 Meng, Xiang W.2.D.2 / W.4.P1.SC4.11 Nakamura, Takahiro Tu.3.A.4 Mentovich, Elad WS5.10 / Th.1.C.4 Nakanishi, Akira Th.2.P2.SC2.5 Merghem, Kamel Tu.3.C.1 Nakano, Yoshiaki M.2.E.4 Merolla, Jean-Marc CLEO 5.2 Nakao, Ryo W.4.P1.SC2.1 Messaddeq, Younes M.2.A.5 Nakashima, Hisao M.1.B.3 Mestre, Miquel A. M.2.B.2 / M.2.C.1 Nakazawa, Masataka M.1.C.3 / W.4.P1.SC5.4 / W.4.P1.SC5.6 / Meyer, Rolf W.4.P1.SC5.3 W.4.P1.SC5.14 Miao, Wang M.2.F.4 / W.2.F.3 / W.4.P1.SC4.14 Namiki, Shu W.2.F.2 / W.4.P1.SC2.6 / Th.2.P2.SC3.4 Micusik, Daniel Th.2.P2.SC4.14 Naoe, Kazuhiko Th.2.P2.SC2.5 Millar, David WS6.2 / W.2.C.1 / W.2.C.2 / W.2.D.1 / Th.2.P2. Napoli, Antonio W.3.D.3 SC3.7 / Th.2.P2.SC5.11 Närhi, Mikko CLEO 5.2 62 Author List Author Session No. Author Session No. Naughton, Alan W.3.E.4 Pagès, Albert W.1.F.4 Nazarathy, Moshe Tu.3.C.3 Pajovic, Milutin W.2.C.1 / Th.2.P2.SC3.7 / Th.2.P2.SC5.11 Nazemosadat, Elham W.4.P1.SC1.7 Panapakkam, Vivek Tu.3.C.1 Negin, Maxim CLEO 4.4 Pang, Xiaodan M.2.C.4 / W.4.P1.SC4.3 / W.4.P1.SC5.9 Neilson, David Th.1.B.1 Paolucci, Francesco Tu.1.B.4 Nejabati, Reza WS2.6 / Tu.1.B.2 / Tu.1.B.5 / W.1.F.2 / Th.1.E.2 Park, Jongchul W.4.P1.SC2.8 Nesic, Aleksandar W.3.F.4 Parmigiani, Francesca Tu.2.D.4 Nespola, Antonino W.1.D.3 Parolari, Paola Th.2.P2.SC7.11 Neugroschl, Dan W.4.P1.SC2.8 Parsons, Kieran W.2.C.1 / W.2.C.2 / W.2.D.1 / Th.2.P2.SC3.7 / Neumeyr, Christian Tu.3.C.4 / Th.1.C.1 Th.2.P2.SC5.11 Nguyen Tan, Hung Th.2.P2.SC3.4 Parsons, Nick W.3.E.4 / W.2.F.1 Nielsen, Torben M.2.B.3 Paskov, Milen M.1.D.4 / W.2.C.1 / W.2.C.5 / W.4.P1.SC5.11 Nikolova, Dessislava Th.2.P2.SC2.12 Pattavina, Achille W.4.P1.SC7.9 Ning Liu, Gordon WS3 Patterson, William Tu.1.D.3 Nishi, Hidetaka W.4.P1.SC2.1 Payne, Frank W.3.B.2 Nishihara, Susumu W.4.P1.SC7.4 / Th.1.D.3 Peczek, Anna Th.2.P2.SC4.14 Nishimura, Kosuke W.4.P1.SC7.2 / W.4.P1.SC7.8 Pederzolli, Federico M.1.F.1 / W.1.F.5 / Th.2.P2.SC6.1 Nishitani, Takashi M.1.E.3 Pelusi, Mark Th.2.P2.SC3.4 Niwa, Masaki W.4.P1.SC4.7 / Th.1.E.3 Peng, Junsong CLEO 5.4 Noda, Masaki Th.1.D.1 Pepe, Teresa Tu.1.B.4 Nodjiadjim, Virginie M.2.C.1 Pérez, Daniel Th.2.P2.SC4.2 Noguchi, Hidemi Tu.2.B.4 Perry, Philip Tu.3.C.1 Noguchi, Masataka Tu.3.A.4 Peserico, Nicola W.4.P1.SC2.3 Noguchi, Yuita Th.1.D.1 Pesic, Jelena W.3.A.2 Nordwall, Fredrik M.2.C.4 Petermann, Klaus W.2.E.5 / W.3.C.2 / Th.2.P2.SC4.14 / Nosaka, Hideyuki Tu.3.C.2 Th.2.P2.SC5.14 Numkam Fokoua, Eric Tu.2.F.3 / Th.2.P2.SC2.6 Peters, Adaranijo M.1.F.2 Petousi, Despoina W.2.E.5 O Petropoulos, Periklis WS4 / Tu.2.D.4 / Tu.2.F.1 Obraztsova, Elena CLEO 4.4 Peucheret, Christophe Tu.2.E.6 / Th.2.P2.SC4.9 Oda, Shoichiro Tu.2.B.1 / Tu.2.C.1 / M.1.B.2 / Th.1.D.2 / Pfeiffer, Martin Tu.3.E.3 / CLEO 4.2 / Th.2.P2.SC2.5 Th.2.P2.SC4.12 Pfeiffer, Thomas WS3.9 / W.3.E.5 Oda, Takuya W.2.E.4 Pham Van, Quan W.1.F.6 Ogawa, Kensuke W.2.E.4 Pham, Tien Dat W.4.P1.SC7.5 / Th.2.P2.SC7.2 Ogiso, Yoshihiro Tu.3.A.2 Phelan, Richard M.2.D.6 Oh, Chin Wan Tu.2.C.5 / W.1.E.3 Phillips, Ian Tu.3.B.2 / Th.2.P2.SC5.16 / Th.2.P2.SC2.1 Ohishi, Yasutake W.4.P1.SC1.1 Piels, Molly Th.2.P2.SC3.2 Ohiso, Yoshitaka Tu.3.A.2 Pilipetskii, Alexei WS6.5 / Tu.1.D.3 / W.3.D.4 Öhlen, Peter Th.1.D.6 Pinto, Armando W.4.P1.SC3.3 Oka, Akira W.2.E.4 Pintus, Paolo W.3.F.1 / W.3.F.3 / Th.2.P2.SC4.10 Okamoto, Seiji Th.2.P2.SC5.4 Pishvaibazargani, Hamed CLEO 3.4 Okonkwo, Chigo M.2.B.5 / M.2.D.1 / Tu.2.D.1 / W.4.P1.SC3.4 / Pittalá, Fabio Th.2.P2.SC3.9 W.4.P1.SC4.14 Plant, David Tu.3.B.3 / W.2.D.2 / W.4.P1.SC4.11 Oliveira, Juliano M.1.B.4 / W.4.P1.SC4.6 / Th.2.P2.SC2.11 Pniov, Alexey CLEO 4.4 Oliveira, Julio Cesar M.1.C.2 / Th.2.P2.SC2.11 Poehlmann, Wolfgang W.3.E.5 Olivier, Ségolène WS5.4 / M.2.E.3 Poggiolini, Pierluigi WS6.8 / Tu.3.D.4 / W.1.D.3 Olmedo, Miguel M.2.C.4 / W.4.P1.SC5.9 Pohl, Udo CLEO 3.3 Olsson, Samuel Th.1.A.3 Poletti, Francesco Tu.2.F.3 / Th.2.P2.SC2.6 Ono, Yoshimasa Th.2.P2.SC5.15 Polo, Victor M.1.E.5 / W.4.P1.SC7.7 Orbah, Mordechay Tu.3.C.3 Popescu, Ion Tu.3.D.3 Ori, Teijiro W.2.E.4 Popov, Sergei M.2.C.4 / W.4.P1.SC4.3 / W.4.P1.SC5.9 Ortiz, Roy W.1.B.3 Porschatis, Caroline Th.2.P2.SC2.10 Ortsiefer, Markus Tu.3.C.4 / Th.1.C.1 Porto da Silva, Edson M.1.B.5 / M.1.D.1 / W.3.C.3 Ortuño, Rubén Th.2.P2.SC4.10 Porto, Stefano W.3.E.4 Ossieur, Peter W.3.E.4 Porzi, Claudio Tu.2.E.1 O‘Sullivan, Maurice Tu.2.C.3 / Tu.3.B.1 / W.4.P1.SC5.8 / Potì, Luca W.4.P1.SC4.2 / Th.2.P2.SC3.10 / Th.2.P2.SC4.7 W.4.P1.SC5.13 / W.4.P1.SC5.15 Pottie, Paul-Eric CLEO 1.4 Otaka, Akihiro M.1.E.4 / Tu.1.F.2 / W.4.P1.SC7.4 / Th.1.D.3 / Th.1.D.5 Pous, Robert M.1.E.5 Oton, Claudio W.3.F.1 Prat, Josep M.1.E.5 / W.4.P1.SC7.7 Ottaviano, Luisa W.3.C.3 Preite, Valerio Tu.2.C.4 Ou, Hiroshi Th.1.D.5 Presi, Marco M.1.E.5 Oveis Gharan, Shahab Tu.3.B.1 Press, Marie Th.2.P2.SC4.13 Owschimikow, Nina CLEO 3.3 Preve, Giovan Battista Th.2.P2.SC4.10 Oxenløwe, Leif M.1.D.1 / M.2.F.1 / Tu.2.F.4 / W.1.D.1 / Price, Alasdair W.1.F.2 W.1.E.5 /W.3.C.3 / Th.2.P2.SC4.9 Prifti, Kristif W.2.F.3 Oyama, Tomofumi M.1.B.3 Prilepsky, Jaroslaw CLEO 2.4 / Tu.3.B.2 / Th.2.P2.SC5.16 Ozaki, Josuke Tu.3.A.2 Prinzen, Andreas Th.2.P2.SC2.10 Ozolins, Oskars M.2.C.4 / W.4.P1.SC4.3 / W.4.P1.SC5.9 Prodaniuc, Cristian M.2.C.3 / W.4.P1.SC4.13 / W.4.P1.SC5.5 Proietti, Roberto M.2.F.3 P Provost, Jean-Guy M.2.E.3 Pacheco-Labrador, Jorge W.4.P1.SC5.2 Pruessing, Bernd Tu.1.B.3 Pagano, Annachiara W.3.D.3 Pu, Minhao W.3.C.3 63 Author List Author Session No. Author Session No. Pupalaikis, Peter M.1.C.5 Ruepp, Sarah M.2.F.1 Puttnam, Benjamin M.1.F.3 / Tu.1.D.2 Ruiz, Marc Th.2.P2.SC3.10 / Th.2.P2.SC4.7 Rumley, Sébastien Th.2.P2.SC2.12 Q Rupeter, Jörg M.1.C.4 Qi, Minghao Th.2.P2.SC2.3 Ryf, Roland M.1.C.5 / Tu.2.D.3 / W.2.B.5 / Th.1.B.1 Qiu, Ciyuan Th.1.B.3 / Th.1.B.4 Rymanov, Vitaly Tu.2.E.3 Qiu, Kun Th.2.P2.SC7.12 Qiu, Meng Tu.3.B.3 / W.2.D.2 / W.4.P1.SC4.11 S Qiu, Shaofeng Th.2.P2.SC4.11 Saavedra, Gabriel W.4.P1.SC5.11 / Th.1.A.2 Qu, Zhen Th.2.P2.SC3.12 Sackey, Isaac W.3.C.2 Quere, Antoine Tu.1.F.3 Saito, Tsunetoshi M.2.A.2 Quintin, Nicolas CLEO 1.4 Saitoh, Kunimasa W.2.B.2 / Th.2.P2.SC2.7 Quiquempois, Yves W.3.B.3 / W.4.P1.SC1.3 Saitoh, Shota W.4.P1.SC1.6 Quiring, Viktor CLEO 2.6 Sakaguchi, Jun Tu.1.D.2 / W.4.P1.SC5.12 Sakamaki, Yohei Th.1.B.2 R Sakamoto, Taiji M.2.A.4 / W.2.B.3 / W.4.P1.SC1.2 Rademacher, Georg WS1.4 / Th.2.P2.SC5.14 Sakamoto, Takahide Tu.1.E.2 Radic, Stojan CLEO 1.1 / Tu.3.B.4 Sakaue, Yuki W.4.P1.SC7.4 Rafel, Albert M.1.E.5 Sales, Salvador Th.2.P2.SC2.4 Rafique, Danish WS6.6 / W.3.D.3 Saliou, Fabienne Tu.1.F.3 / W.3.E.2 / Th.2.P2.SC3.3 / Th.2.P2.SC7.4 Rahman, Talha W.3.D.3 Salmon, David M.1.F.5 Ralph, Stephen Th.1.C.5 Samadi, Payman Tu.2.B.3 / M.2.F.2 Ramachandran, Siddharth WS1.3 / W.3.B.1 / W.3.B.5 Sambo, Nicola W.4.P1.SC6.5 / Th.2.P2.SC4.7 Ramantanis, Petros W.3.A.2 / Th.2.P2.SC5.12 Samoud, Wiem Tu.2.B.3 Ramdane, Abderrahim WS5.7 / Tu.3.C.1 / WS 5.1 Sanchez, Christian Tu.1.E.4 / Tu.2.D.2 Ramírez Molina, Julio César W.4.P1.SC5.2 Sanjabi Eznaveh, Zeinab Tu.2.D.3 / Tu.2.F.5 Randel, Sebastian WS1.8 Sano, Akihide W.3.D.2 / W.2.D.3 Rannello, Mario M.1.E.5 Sansoni, Linda CLEO 2.6 Rarity, John W.1.F.2 Santarelli, Giorgio CLEO 1.4 Rasmussen, Christian M.2.B.3 Saridis, George M.1.F.3 / Th.1.E.2 Rasmussen, Jens M.1.B.2 / M.1.B.3 / Tu.2.B.1 / Tu.2.C.1 / Tu.2.C.2 / Sasa, Toru M.2.A.2 Th.1.D.2 / Th.2.P2.SC4.5 / Th.2.P2.SC4.12 Sasaki, Yusuke W.2.B.2 / W.2.B.4 / W.4.P1.SC1.6 / Th.2.P2.SC2.9 Rausch, Marko W.4.P1.SC2.2 Sato, Ken-Ichi W.2.F.2 / Th.1.E.3 / W.4.P1.SC4.7 / W.4.P1.SC6.3 Raybon, Gregory M.1.C.2 / M.1.C.5 Saucke, Karen W.4.P1.SC5.3 Raza, Muhammad Rehan Th.1.D.6 Savory, Seb M.1.B.1 / M.1.E.2 / Tu.2.A.1 / W.2.C.1 / W.4.P1.SC5.15 / Rehbein, Wolfgang W.2.E.2 Th.1.A.2/ Th.2.P2.SC3.5 Reimer, Michael Tu.2.C.3 / Tu.3.B.1 / W.4.P1.SC5.15 Sazonkin, Stanislav CLEO 4.4 Reis, Jacklyn M.1.B.4 / W.4.P1.SC3.3 / W.4.P1.SC4.6 / Schaeffer, Christian Tu.3.E.4 / Th.2.P2.SC5.8 Th.2.P2.SC2.11 Schatz, Richard M.2.C.4 / W.4.P1.SC4.3 / W.4.P1.SC5.9 Reithmaier, Johann Peter WS5.3 / WS 5.1 / Th.2.P2.SC2.2 Schell, Martin W.2.E.2 / W.4.P1.SC2.2 / Th.2.P2.SC2.4 Renaudier, Jeremie Tu.1.E.5 Schießl, Johann W.4.P1.SC3.6 Rezania, Ali M.2.C.2 / Tu.2.A.3 / W.4.P1.SC5.8 / Th.2.P2.SC5.9 Schlosser, Michael Th.1.E.4 Riccardi, Emilio W.3.D.3 Schmalen, Laurent M.1.D.2 / M.1.D.3 / W.1.C.1 / W.1.C.3 / Richardson, David M.2.D.6 / W.2.B.4 / W.3.B.2 / Tu.2.D.4 / Tu.2.F.3 W.2.D.5 / W.4.P1.SC3.5 / Th.2.P2.SC3.6 Richter, Ines W.4.P1.SC5.3 Schmid, Rolf M.1.C.4 Richter, Thomas W.2.F.4 / W.3.C.1 / W.3.C.2 Schmidt, Christian W.4.P1.SC5.7 Ricken, Raimund CLEO 2.6 Schmidt, Christopher W.4.P1.SC5.2 Riesen, Nicolas Th.2.P2.SC2.9 Schmidt, Friederike Th.2.P2.SC5.14 Riet, Muriel M.2.C.1 Schmidt-Langhorst, Carsten W.1.C.4 / W.2.F.4 / W.3.C.1 Rios-Müller, Rafael M.2.B.2 / Tu.1.E.5 Schrenk, Bernhard Th.2.P2.SC7.10 Rito, Pedro W.2.E.5 Schubert, Colja W.1.C.4 / W.2.F.4 / W.3.C.1 / W.3.C.2 Riumkin, Konstantin W.4.P1.SC1.4 Schug, Michael CLEO 2.5 Rivas, Jose Manuel M.1.F.1 / M.1.F.4 Schuh, Karsten M.1.C.4 / M.1.D.3 Rizzelli Martella, Giuseppe CLEO 5.3 Schulte, Patrick W.1.C.1 / M.1.D.2 / M.1.D.3 Rizzelli, Giuseppe WS2.10 Schulze, Jan-Hindrik CLEO 3.3 Roberts, Kim W.4.P1.SC5.8 / W.4.P1.SC5.13 Schulzgen, Axel Tu.2.F.5 Roelkens, Gunther WS4.4 / M.2.E.1 Secondini, Marco WS6.11 / Th.2.P2.SC3.10 Romagnoli, Marco Tu.2.C.4 Seel, Stefan W.4.P1.SC5.3 Ropers, Claus CLEO 5.1 Segawa, Toru Th.2.P2.SC4.8 Rosa, Paweł CLEO 5.3 Semenova, Elizaveta W.3.C.3 Rosales, Ricardo CLEO 3.3 Semrau, Daniel W.4.P1.SC5.11 Rösener, Detlef Th.2.P2.SC3.6 Seno, Kazunori W.4.P1.SC2.7 / Th.1.B.2 Rosenkranz, Werner Th.2.P2.SC3.9 Serafino, Giovanni Tu.2.E.1 Rossi, Nicola W.4.P1.SC3.7 / Th.2.P2.SC5.12 Serbay, Murat Th.2.P2.SC4.13 Rossi, Sandro M.1.B.4 / Th.2.P2.SC2.11 Serena, Paolo WS6.10 Rostami, Ahmad Th.1.D.6 Sgambelluri, Andrea Tu.1.B.4 Rottenberg, Xavier Th.2.P2.SC2.13 Shah, Bhupen M.2.B.3 Rottwitt, Karsten Tu.2.D.4 Shahpari, Ali W.4.P1.SC3.3 Roudas, Ioannis Th.2.P2.SC3.11 Shalaby, Badr CLEO 1.3 Rozental, Valery M.1.B.4 / Th.2.P2.SC2.11 Shamee, Bishara W.3.C.4 / Th.2.P2.SC5.3 Rožić, Ćiril Tu.3.D.5 Shariati, Behnam M.1.F.1 / M.1.F.4 Rubenchik, Alexander CLEO 1.2 Shchukin, Vitaly W.4.P1.SC4.12 / Th.2.P2.SC4.11 64 Author List Author Session No. Author Session No. Shelestov, Dmitry CLEO 4.4 Suckow, Stephan Th.2.P2.SC2.10 Shen, Alexandre M.2.E.3 / Th.2.P2.SC4.9 Suda, Satoshi W.2.F.2 / W.4.P1.SC2.6 Shen, Li Th.2.P2.SC3.13 Sugavanam, Srikanth CLEO 5.4 Shen, Yiwen M.2.F.2 Sugawa, Tomoki Th.2.P2.SC7.6 Shevchenko, Nikita W.4.P1.SC5.11 Sugihara, Kenya W.2.C.1 / W.2.C.2 / W.2.C.3 Shi, Kai WS1.7 / M.1.E.2 / M.2.B.1 Sugihara, Takashi W.2.C.3 / Th.2.P2.SC3.7 Shi, Yan Th.2.P2.SC7.8 Sugizaki, Ryuichi M.2.A.2 / W.2.B.1 / Th.2.P2.SC2.1 / Shieh, William Tu.1.C.1 / Th.2.P2.SC7.3 Th.2.P2.SC5.3 Shikama, Kota Th.1.B.2 Suikat, Detlef Th.2.P2.SC3.6 Shimada, Tatsuya Tu.1.F.2 / Th.1.D.3 / Th.1.D.5 Sun, Changzheng W.4.P1.SC2.5 Shimizu, Hidekazu Th.2.P2.SC7.6 Sun, Chunlei W.4.P1.SC2.11 Shimizu, Satoshi W.4.P1.SC5.1 Sun, Lu Tu.3.D.2 Shimizu, Tatsuya Tu.1.F.2 Sun, Ninghui M.2.F.3 Shinada, Satoshi Th.2.P2.SC4.8 Sun, Yi Th.1.C.5 Shiner, Andrew Tu.2.C.3 Sun, Yu Tu.1.D.3 Shitaba, Toshiaki W.4.P1.SC7.4 / Th.2.P2.SC7.6 Sutorius, Gustaaf Tu.2.C.5 Shoji, Yuya W.3.F.3 Suzuki, Daiki W.4.P1.SC5.4 Shrestha, Amita W.4.P1.SC5.2 Suzuki, Keijiro W.2.F.2 / W.4.P1.SC2.6 Shtyrina, Olga CLEO 1.2 Suzuki, Ken-Ichi M.1.E.4 / W.4.P1.SC7.4 Shubochkin, Roman Th.1.C.5 Suzuki, Kenya W.4.P1.SC2.7 / Th.1.B.2 Sibson, Phil W.1.F.2 Suzuki, Makoto Tu.2.C.2 Sichkovskyi, Vitalii Th.2.P2.SC2.2 Suzuki, Masatoshi W.4.P1.SC7.2 / W.4.P1.SC7.8 Silberhorn, Christine CLEO 2.6 Suzuki, Naoki M.1.E.1 / Th.1.D.1 Sillard, Pierre Tu.2.D.1 / Tu.2.D.3 / Tu.2.F.5 / W.3.B.3 / W.3.B.4 Suzuki, Takahiro M.1.E.4 Sillekens, Eric W.4.P1.SC3.4 Suzuki, Takanori Th.2.P2.SC2.5 Simeonidou, Dimitra M.1.F.3 / Tu.1.B.2 / Tu.1.B.5 / W.1.F.2 / Suzuki, Takenobu W.4.P1.SC1.1 W.1.F.4 / Th.1.E.2 Svaluto Moreolo, Michela W.1.F.3 / Th.2.P2.SC6.3 Simões, Glauco Th.2.P2.SC2.11 Sygletos, Stylianos Tu.1.E.4 / Tu.2.D.2 Simoff, Debra W.1.B.3 Sylvestre, Thibaut CLEO 5.2 Simon, Gael W.3.E.2 / Th.2.P2.SC3.3 / Th.2.P2.SC7.4 Szczecinski, Leszek W.2.C.5 Simpanen, Ewa Th.1.C.3 Szczerba, Krzysztof Th.2.P2.SC4.6 Singer, Jonathan W.4.P1.SC2.8 Szyrkowiec, Thomas Tu.1.B.2 / Tu.1.B.3 Sinkin, Oleg Tu.1.D.3 / W.3.D.4 Siracusa, Domenico M.1.F.1 / Tu.1.B.1 / W.1.F.5 / Th.2.P2.SC6.1 T Skubic, Björn Tu.1.F.1 / Th.1.D.6 Tabares, Jeison M.1.E.5 Slavík, Radan M.2.D.6 Tafur Monroy, Idelfonso M.2.B.5 / M.2.D.1 / Tu.1.C.2 / Smit, Meint Th.2.P2.SC2.1 Tu.3.C.4 / W.3.D.5 / Th.1.C.1 / Th.2.P2.SC3.9 Smolders, A. B. (Bart) Tu.2.E.2 Taga, Hidenori M.2.A.3 / W.4.P1.SC3.10 Smolski, Viktor CLEO 3.2 Taguchi, Katsuhisa W.4.P1.SC7.4 Snyder, Brad W.4.P1.SC2.8 Tajima, Akio Tu.2.B.4 / W.2.F.2 Soccali, Oriana W.4.P1.SC1.5 Tajima, Kazuyuki W.3.A.3 Soenen, Wouter Th.1.C.4 Takagi, Shinichi W.3.F.2 Sofien, Mhatli Th.2.P2.SC3.1 Takahashi, Hiroshi Th.2.P2.SC2.3 Solis-Trapala, Karen Th.2.P2.SC3.4 Takahashi, Ryo Th.2.P2.SC4.8 Solli, Daniel CLEO 5.1 Takahashi, Seigo Th.2.P2.SC5.15 Soma, Daiki M.2.A.3 Takahashi, Shigeki Tu.3.A.4 Sone, Kyosuke Th.1.D.2 Takasaka, Shigehiro M.2.A.2 / Th.2.P2.SC2.1 / Th.2.P2.SC5.3 Song, Binhuang W.2.D.4 / W.4.P1.SC2.9 / W.4.P1.SC3.2 Takeda, Koji W.4.P1.SC2.1 Song, Jeong Hwan Th.2.P2.SC2.13 Takenaga, Katsuhiro W.2.B.2 / W.4.P1.SC1.6 Soref, Richard Th.2.P2.SC4.2 Takenaka, Mitsuru Tu.3.A.4 / W.3.F.2 Sorianello, Vito Tu.2.C.4 Takenouchi, Hirokazu Tu.2.E.5 / W.4.P1.SC2.4 Soriano, Miguel CLEO 2.1 Takeshima, Koki M.2.A.2 Souza, André M.1.B.4 Takeshita, Hitoshi Tu.2.B.4 Sowailem, Mohammad W.2.D.2 Takiguchi, Koichi W.4.P1.SC2.12 Spadaro, Salvatore W.1.F.4 Takita, Yutaka W.3.A.3 Spagnolini, Umberto Th.2.P2.SC7.11 Takizawa, Motoyuki Th.1.D.2 Sparks, Kevin WS2.7 Taku, Saito Th.2.P2.SC4.5 Spiga, Silvia Th.1.C.4 Talli, Giuseppe Tu.3.F.2 / W.3.E.4 Spinnler, Bernhard W.3.D.3 / Th.2.P2.SC5.7 Tan, Mingming CLEO 5.3 Stefani, Fabio CLEO 1.4 Tan, Yuanlong Th.2.P2.SC6.2 / Th.2.P2.SC7.5 Steffan, Andreas Tu.2.E.3 Tanaka, Kazuki W.4.P1.SC7.2 / W.4.P1.SC7.8 Steiner, Fabian M.1.D.2 / M.1.D.3 / W.1.C.1 Tanaka, Shigehisa Th.2.P2.SC2.5 Stephens, Marc Th.2.P2.SC2.1 Tanaka, Takafumi Tu.3.D.1 Stepniak, Grzegorz W.4.P1.SC4.12 Tanemura, Takuo M.2.E.4 Stevens, Gary WS4.1 Tang, Hong Th.2.P2.SC4.13 Stiller, Birgit W.4.P1.SC5.3 Tang, Ming W.2.D.2 / W.4.P1.SC4.3 Stöhr, Andreas Tu.2.E.3 Tang, Xuefeng Th.2.P2.SC5.13 Stojanovic, Nebojsa M.2.C.3 / W.4.P1.SC4.13 / W.4.P1.SC5.5 Tangdiongga, Eduward Tu.2.C.5 / Tu.2.E.2 / Tu.3.F.4 / W.1.E.3 / Straullu, Stefano W.4.P1.SC7.6 Th.2.P2.SC7.8 Strittmatter, Andre CLEO 3.3 Taniguchi, Tomohiro W.4.P1.SC7.4 / Th.2.P2.SC7.6 Su, Xiaofei M.1.B.2 / Tu.2.C.1 Tanimura, Takahito M.1.B.3 / Tu.2.C.2 / W.2.F.4 / W.3.C.1 Su, Yikai Th.1.B.3 / Th.1.B.4 Tanizawa, Ken W.2.F.2 / W.4.P1.SC2.6 65 Author List Author Session No. Author Session No. Tanobe, Hiromasa Tu.3.A.2 V Tao, Minghui W.4.P1.SC7.3 Vaernewyck, Renato Tu.3.A.1 / Th.1.C.4 Tao, Zhenning WS6.4 / M.1.B.2 / Tu.2.C.1 / Th.2.P2.SC4.5 / Vall-llosera, Gemma M.1.E.5 Th.2.P2.SC4.12 Van Campenhout, Joris W.4.P1.SC2.8 Tarasov, Nikita CLEO 5.4 van den Boom, Henrie Th.2.P2.SC7.8 Tartaglia, Antonio WS2.2 / Tu.1.F.6 van der Heide, Sjoerd M.2.B.5 / M.2.D.1 Taru, Toshiki W.2.B.5 van der Linden, Robbert Tu.2.C.5 / Tu.3.F.4 Tatarczak, Anna Tu.1.C.2 Van Dijk, Frédéric Tu.2.E.4 Tatum, Jim Th.1.C.5 van Putten, Lieke Th.2.P2.SC2.6 Taunay, Thierry W.1.B.2 / W.1.B.3 Van Steenberge, Geert Th.1.C.4 Tayq, Zakaria Tu.1.F.3 / Th.1.D.4 / Th.2.P2.SC3.3 van Uden, Roy Tu.2.D.1 / W.4.P1.SC3.4 / W.4.P1.SC4.14 Teixeira, Antonio W.4.P1.SC3.3 van Veen, Dora W.2.A.2 / Tu.3.F.5 / Th.2.P2.SC7.1 Tekce, Kemal CLEO 3.5 van Weerdenburg, John Tu.2.D.1 / W.4.P1.SC3.4 / W.4.P1.SC4.14 Templ, Wolfgang M.1.C.4 van Zantvoort, J. H. C. (Johan) Tu.2.E.2 Temprana, Eduardo Tu.3.B.4 Vanhoecke, Michael Tu.3.A.1 Ten, Sergey Th.2.P2.SC5.2 Vanvincq, Olivier W.4.P1.SC1.3 Terada, Jun Tu.1.F.2 / Th.1.D.3 / Th.1.D.5 Vaquero Caballero, Francisco Javier Th.2.P2.SC3.9 Tessema, Netsanet Tu.2.E.2 Varughese, Siddharth Th.1.C.5 Testa, Francesco Tu.2.C.4 Varvarigos, Emmanouel W.4.P1.SC6.5 Tezuka, Hiroshige W.4.P1.SC1.1 Vasilyev, Sergey CLEO 3.2 Thomas, Varghese Th.1.C.5 Vegas Olmos, Juan Jose M.2.B.5 / M.2.D.1 / Tu.3.C.4 / Thompson, Mark W.1.F.2 W.3.D.5 / Th.1.C.1 Thomsen, Benn WS1 / M.1.E.2 / M.2.B.1 / M.2.D.6 / Vela, Alba Tu.2.B.2 / Th.2.P2.SC4.7 WS 1.1 / W.2.C.1 Velasco, Luis M.1.F.1 / Tu.2.B.2 / Th.2.P2.SC4.7 Thomson, Robert R. Th.1.B.5 Velásquez Micolta, Juan M.1.E.5 / W.4.P1.SC7.7 Thrane, Jakob Th.2.P2.SC3.2 Velázquez-Benítez, Amado Tu.2.D.3 / Th.1.B.1 Tian, Yongjie Tu.2.F.2 Velha, Philippe Tu.2.C.4 / Tu.2.E.1 Toenger, Shanti CLEO 5.2 Verbist, Jochem M.2.E.1 Toge, Kunihiro Th.2.P2.SC2.3 Verchere, Dominique W.1.F.6 / Th.1.E.1 Tolmachev, Alex Tu.3.C.3 Verheyen, Koen Tu.3.A.1 Tomkos, I M.1.F.1 / M.1.F.4 / Tu.3.D.5 Vgenopoulou, Vassiliki Th.2.P2.SC3.11 Tomkos, Ioannis Th.2.P2.SC3.11 Via, Anna Tu.2.B.2 Tonello, Alessandro CLEO 1.3 Vila, Chantal M.1.E.5 Tong, Hoang Tuan W.4.P1.SC1.1 Vilalta, Ricard Tu.1.B.2 / W.1.F.1 / W.1.F.3 / Th.2.P2.SC6.4 Torfs, Guy Tu.3.A.1 Vílchez, Francisco Javier Th.2.P2.SC6.3 Tornatore, Massimo W.4.P1.SC7.9 Viñés, Albert W.1.F.4 Torres Vega, Maria W.4.P1.SC4.9 Voigt, Karsten W.2.E.5 Torrijos Gijon, Jose Alfonso Tu.1.F.1 von der Weid, Jean Pierre Th.2.P2.SC4.3 Touch, Joe W.3.C.4 / Th.2.P2.SC5.3 Vusirikala, Vijay Tu.3.B.4 Townsend, Paul Tu.3.F.2 / W.3.E.4 Tran, Nguyen-Cac Tu.3.F.4 W Tran, Patrice Tu.1.E.1 / Tu.3.B.5 Wabnitz, Stefan CLEO 1.3 / CLEO 4.5 Triki, Ahmed Tu.3.D.3 Wada, Masaki M.2.A.4 / W.2.B.3 / W.4.P1.SC1.2 Trinel, Jean-Baptiste W.4.P1.SC1.3 Wada, Naoya M.1.F.3 / Tu.1.D.2 / W.4.P1.SC6.2 / Trocha, Philipp Tu.3.E.3 W.4.P1.SC5.1 / W.4.P1.SC5.12 / Th.2.P2.SC4.8 Troendle, Daniel W.4.P1.SC5.3 Wada, Tomoyuki M.1.E.4 Tsang, Hon Th.2.P2.SC7.7 Wahlbrink, Thorsten Th.2.P2.SC2.10 Tse, Kathy Tu.2.B.1 Wakayama, Yuta M.2.A.3 Tsuchida, Yukihiro M.2.A.2 Wale, Michael J. Th.2.P2.SC2.1 Tsuritani, Takehiro M.2.A.2 / M.2.A.3 / Tu.1.B.2 / Tu.1.D.1 / Wallace, Steven WS3.3 Tu.3.D.3 / W.2.B.1 / W.2.C.4 / W.4.P1.SC3.10 Wang, Andong Th.2.P2.SC3.13 / Th.2.P2.SC4.15 Tu, Xiaoguang W.2.E.4 Wang, Bin Th.2.P2.SC2.2 Tur, Moshe W.3.C.4 / Th.2.P2.SC5.3 / Th.2.P2.SC2.5 Wang, Honghai W.3.B.2 Turitsyn, Sergei Tu.3.B.2 / CLEO 1.2 / CLEO 2.4 / Th.2.P2.SC5.16 Wang, Hongya W.4.P1.SC2.10 Turkcu, Onur W.4.P1.SC6.6 Wang, Jian W.4.P1.SC2.5 / W.4.P1.SC2.10 / Th.2.P2.SC3.13 / Turkiewicz, Jarosław W.4.P1.SC4.12 Th.2.P2.SC4.15 Turukhin, Alexey Tu.1.D.3 Wang, Jing W.1.E.2 / W.4.P1.SC7.1 / Th.2.P2.SC2.3 Wang, Junxi W.4.P1.SC2.5 U Wang, Lai W.4.P1.SC2.5 Ubaldi, Fabio Tu.1.B.4 Wang, Liang W.4.P1.SC4.8 Uceda, Víctor Tu.1.B.2 / Tu.1.B.4 / Th.2.P2.SC6.4 Wang, Nannan Th.2.P2.SC6.2 Udalcovs, Aleksejs M.2.C.4 Wang, Ning Tu.2.F.5 Ueda, Koh W.2.F.2 Wang, Suyi W.3.E.1 Ueda, Yuta Tu.3.A.2 Wang, Xiaodong W.3.E.1 Uenohara, Hiroyuki W.4.P1.SC3.1 Wang, Xiaozhou Th.2.P2.SC5.7 Ulusoy, Ahmet Cagri W.2.E.5 / Th.2.P2.SC4.14 Wang, Xie Th.2.P2.SC5.5 Umeki, Takeshi W.4.P1.SC2.4 Wang, Xue W.4.P1.SC4.6 Umezawa, Toshimasa Th.2.P2.SC7.2 Wang, Ye W.2.C.2 Urban, Patryk Th.2.P2.SC4.3 Wang, Yi Th.2.P2.SC3.13 Urushibara, Azusa W.4.P1.SC1.2 Wang, Yiguang W.4.P1.SC4.8 Uto, Kenichi M.1.E.1 Wang, Yi-Hsiang W.4.P1.SC3.10 Wang, Yuanquan M.2.D.5 / W.3.D.1 66 Author List Author Session No. Author Session No. Ware, Cedric Tu.2.B.3 Yamazaki, Hiroshi Tu.3.A.2 / Tu.3.C.2 / W.2.D.3 / W.3.D.2 Wass, Jesper Th.2.P2.SC3.2 Yan, Fulong M.2.F.4 Watanabe, Kei Tu.2.E.5 Yan, Hui Juan Th.2.P2.SC4.13 Watanabe, Kengo M.2.A.2 Yan, Jianchang W.4.P1.SC2.5 Watanabe, Shigeki Tu.2.C.2 / W.2.F.4 / W.3.C.1 Yan, Li Th.2.P2.SC6.5 Wei, Chia-Chien W.4.P1.SC3.10 / Th.2.P2.SC4.1 Yan, Shuangyi Th.1.E.2 Wei, Jinlong Th.1.C.1 Yan, Yan Th.1.E.2 Wei, Tongbo W.4.P1.SC2.5 Yanagimachi, Shigeyuki W.2.F.2 Weis, Erik Tu.1.F.1 Yang, Guangyao Th.2.P2.SC2.2 Wen, He Tu.2.F.5 Yang, Hui Th.2.P2.SC6.2 / Th.2.P2.SC7.5 Wesemann, Lukas CLEO 3.5 Yang, Qi W.3.E.1 Westbergh, Petter Th.1.C.3 Yang, Ying W.3.E.1 Westbrook, Paul W.1.B.3 Yang, Yucheng W.3.B.2 Westergren, Urban M.2.C.4 / W.4.P1.SC4.3 / W.4.P1.SC5.9 Yang, Yuxing Th.1.B.3 Wetzel, Benjamin CLEO 5.2 Yangzhang, Xianhe CLEO 2.3 Wilke Berenguer, Pablo W.1.C.4 Yankov, Metodi M.1.D.1 / W.1.C.5 / W.1.D.1 / W.3.C.3 Wilkinson, Steven W.3.C.4 Yao, Shuchang W.4.P1.SC7.3 / W.4.P1.SC7.10 Williams, Kevin W.2.F.3 Yao, Weiming Th.2.P2.SC2.1 Willner, Alan W.3.C.4 / Th.2.P2.SC2.5 / Th.2.P2.SC5.3 Ye, Chenhui Tu.3.F.3 Winzer, Georg W.2.E.5 / Th.2.P2.SC4.14 Ye, Yabin Th.2.P2.SC3.9 Winzer, Peter M.1.C.2 / M.1.C.5 / M.2.A.1 / Tu.3.A.5 / Yeh, Chien-Hung Th.2.P2.SC7.7 W.1.C.2 / W.1.D.2 / W.4.P1.SC5.10 Yeminy, Tomer Th.2.P2.SC2.5 Winzer, Peter J. M.0.4 Yi, Lilin W.3.E.1 Wiotte, Fabrice CLEO 1.4 Yin, Xin M.2.E.1 / Tu.3.A.1 / Tu.3.F.4 / Th.1.C.4 Withford, Michael Th.2.P2.SC2.9 Ying, Kai W.4.P1.SC7.1 Witzens, Jeremy WS5.8 / WS 5.1 Yoo, S. J. Ben M.2.F.3 / Tu.3.D.2 Wlodawski, Mitch W.4.P1.SC2.8 Yoo, Sun Tu.1.F.3 Woggon, Ulrike CLEO 3.3 Yoshida, Masato M.1.C.3 / W.4.P1.SC5.6 / W.4.P1.SC5.14 Wolf, Stefan Tu.3.A.3 / Tu.3.E.3 / Th.2.P2.SC2.7 Yoshida, Setsuo Tu.2.B.1 / Th.1.D.2 / Th.2.P2.SC4.12 Wolter, Gregory Tu.1.D.3 Yoshida, Tsuyoshi W.2.D.1 / Th.2.P2.SC3.7 / Th.2.P2.SC5.11 Wosinska, Lena WS2.1 / M.2.F.2 / W.4.P1.SC6.1 / Th.1.D.6 Yoshida, Yuki W.2.E.4 Wu, Baojian W.4.P1.SC4.11 Yoshikane, Noboru Tu.1.B.2 / Tu.3.D.3 Wu, Bo Th.2.P2.SC4.11 Yoshima, Satoshi Th.1.D.1 Wu, Hongchao W.1.B.3 Yoshinaga, Hisao Th.2.P2.SC7.6 Wu, Hsin-Yu Th.2.P2.SC7.7 Yousefi, Mansoor CLEO 2.3 Wu, Jian Tu.2.F.2 Yu, Ao Th.2.P2.SC7.5 Wu, Jinhua Th.2.P2.SC4.13 Yu, Jianjun M.1.C.1 / M.2.D.5 / W.1.E.2 / W.1.E.4 / W.3.D.1 Wu, Xinru Th.2.P2.SC7.7 Yu, Jinlong W.1.E.5 Wu, Xuming W.4.P1.SC7.10 Yu, Shaohua W.3.E.1 Yu, Xianbin W.1.E.5 X Yu, Xiaosong W.4.P1.SC7.11 / Th.2.P2.SC6.2 Xiao, Jiangnan W.1.E.4 Yu, Yi Th.2.P2.SC5.5 Xie, Mutong W.4.P1.SC4.1 Yu, Yu W.4.P1.SC2.11 Xie, Yiwei W.4.P1.SC3.2 Yu, Zhenhua W.4.P1.SC7.1 Xiong, Bing W.4.P1.SC2.5 Yuan, Feng Tu.1.C.1 / Th.2.P2.SC7.3 Xu, Cheng Th.2.P2.SC3.8 Yuan, Guojun M.2.F.3 Xu, Danxia CLEO 3.1 Yuan, Hui M.1.F.2 Xu, Junbo W.3.E.1 Yuan, Shuai W.2.C.4 Xu, Mu W.1.E.2 / W.4.P1.SC7.1 Yuefeng, Ji W.4.P1.SC7.11 Xu, Sugang W.4.P1.SC6.2 Yvind, Kresten W.3.C.3 Xu, Tianhua W.4.P1.SC3.9 / W.4.P1.SC5.11 Xu, Wenjing W.4.P1.SC4.1 Z Xu, Yuming W.1.E.4 Zabada, Bidossessi Charlyse Th.2.P2.SC3.3 Xuan, Yi Th.2.P2.SC2.3 Zakharian, Aramais Th.2.P2.SC5.2 Xue, Chenpeng Th.2.P2.SC7.12 Zamani, Mahdi W.4.P1.SC3.8 Xue, Lei W.3.E.1 Zami, Thierry W.3.A.2 / Th.1.E.5 Xue, Xiaojie W.4.P1.SC1.1 Zanardi, Andrea W.1.F.5 / Th.2.P2.SC6.1 Zanaty, Abdullah Th.2.P2.SC3.9 Y Zang, Dawei M.2.F.3 Yam, Scott M.2.C.2 Zawadzki, Crispin W.2.E.2 Yamada, Eiichi Tu.3.A.2 Zech, Herwig W.4.P1.SC5.3 Yamada, Koji W.1.A.1 Zeghlache, Djamal W.1.F.6 Yamada, Takashi Tu.3.A.2 Zemen, Thomas Th.2.P2.SC7.10 Yamaguchi, Keita W.4.P1.SC2.7 / Th.1.B.2 Zeng, Huaiyu W.1.E.1 / W.4.P1.SC7.3 Yamaguchi, Yuya Th.2.P2.SC2.6 Zeng, Xinglin Tu.2.F.2 Yamamoto, Fumihiko W.2.B.3 Zervas, Georgios M.1.F.2 / M.1.F.3 / W.4.P1.SC6.1 Yamamoto, Naokatsu Tu.1.E.2 / W.4.P1.SC4.5 / W.4.P1.SC7.5 / Zervas, Michael M.1.A.1 Th.2.P2.SC7.2 ZHai, Wensheng W.4.P1.SC4.1 Yamamoto, Shuto M.2.D.4 Zhan, Wenhui M.2.E.4 Yamamoto, Takashi M.2.A.4 / W.2.B.3 / W.4.P1.SC1.2 Zhang, Chong W.3.F.3 Yamamoto, Tsuyoshi W.4.P1.SC2.1 Zhang, Fangyuan Tu.3.B.3 / W.2.D.2 / W.4.P1.SC4.11 Yamauchi, Tomohiro Tu.2.C.1 / Th.2.P2.SC4.12 Zhang, Jiankun Th.2.P2.SC5.1 67 Author List Author Session No. Author Session No. Zhang, Jiawei W.4.P1.SC7.11 Zhou, Lei W.4.P1.SC7.10 / W.4.P1.SC7.3 Zhang, Jie W.4.P1.SC7.11 / Th.2.P2.SC3.8 / Th.2.P2.SC6.2 Zhou, Peng M.2.E.4 Zhang, Jie Th.2.P2.SC7.5 Zhou, Xian W.4.P1.SC4.8 / Th.2.P2.SC4.11 Zhang, Junwen W.1.E.2 / W.3.D.1 / W.4.P1.SC7.1 Zhou, Xiang WS3.1 Zhang, Kaibin Tu.3.F.3 Zhou, Xingyu W.2.D.2 / W.4.P1.SC4.11 Zhang, Liang M.2.D.2 / Tu.3.F.1 / Th.1.C.2 / Th.2.P2.SC5.6 Zhou, Yingjun W.4.P1.SC4.8 Zhang, Lin Th.2.P2.SC2.5 Zhu, Chen W.2.D.4 / W.4.P1.SC2.9 / W.4.P1.SC3.2 / Zhang, Qiang M.2.C.3 / M.2.D.2 / Tu.3.F.1 / W.4.P1.SC4.13 / W.4.P1.SC3.12 Th.1.C.2 / Th.2.P2.SC5.6 Zhu, Haike W.2.E.4 Zhang, Rui W.3.B.2 Zhu, Long Th.2.P2.SC4.15 Zhang, Ruiyong Th.2.P2.SC4.13 Zhu, Long Xiu Th.2.P2.SC4.13 Zhang, Sen Tu.3.F.1 Zhu, Ruijie Th.2.P2.SC6.2 Zhang, Xinliang W.4.P1.SC2.11 Zhu, Shilin Tu.3.D.2 Zhang, Yong Th.1.B.3 / Th.1.B.4 Zhu, Zuqing Tu.3.D.2 Zhang, Yun W.4.P1.SC2.5 Zhuang, Leimeng W.4.P1.SC2.9 Zhang, Zhuhong W.4.P1.SC3.8 / Th.2.P2.SC5.13 Zhuge, Qunbi WS6.3 / Tu.3.B.1 / Tu.3.B.3 / W.2.D.2 / Zhao, Mingyang W.4.P1.SC4.1 W.4.P1.SC4.11 Zhao, Yifan Th.2.P2.SC4.15 Zibar, Darko M.1.B.5 / M.1.D.1 / M.2.C.4 / W.1.D.1 / Zhao, Ying M.1.B.2 / Th.2.P2.SC4.5 / Th.2.P2.SC4.12 W.3.C.3 / W.4.P1.SC5.9 / Th.2.P2.SC3.2 Zhao, Yongli W.4.P1.SC7.11 / Th.2.P2.SC6.2 Zimmermann, Lars W.2.E.5 / W.3.C.2 / W.3.F.5 / Th.2.P2.SC4.14 Zheng, Cao M.2.F.3 Ziyadi, Morteza W.3.C.4 / Th.2.P2.SC5.3 / Th.2.P2.SC2.5 Zhiyong, Feng Th.2.P2.SC4.11 Zlobina, Ekaterina CLEO 5.5 Zhong, Kangping W.4.P1.SC4.8 / Th.2.P2.SC4.11 Zuo, Tianjian M.2.D.2 / Tu.3.F.1 / Th.1.C.2 / Th.2.P2.SC5.6 Zhou, Enbo M.2.D.2 / Tu.3.F.1 / Th.1.C.2 / Th.2.P2.SC5.6 Zussman, Gil Tu.2.B.3 Zhou, Hongyan W.3.B.2 Zwickel, Heiner Tu.3.A.3 / Th.2.P2.SC2.7 Zhou, Jie M.2.D.2 / Tu.3.F.1 / Th.1.C.2 / Th.2.P2.SC5.6 N E R I N W Connecting, Extending and Assuring the Cloud A W A R D At ADVA Optical Networking we’re creating new opportunities for tomorrow’s networks, a new vision for a connected world. Our intelligent telecommunications hardware, software and services have been deployed by several hundred service provid- ers and thousands of enterprises. Over the past twenty years, our innovative connectivity solutions have helped to drive our customers’ networks forward, helped to drive their businesses to new levels of success. We forge close working relationships with all our customers. As your trusted partner we ensure that we’re always ready to exceed your networking expectations. www.advaoptical.com 68 LED BASED OPTICAL WIRELESS BACKHAUL LINK N E R I N W Connecting, Extending and Assuring the Cloud Robust, low latency infrared LED link for mobile backhaul A W A R D Specifications Benefits Applications At ADVA Optical Networking we’re creating new opportunities Infrared LED based Wireless point-to-point Low cost optical wireless link communication in industrial for tomorrow’s networks, a new vision for a connected world. based on infrared LEDs Easy alignment: environments Our intelligent telecommunications hardware, software and 500 Mbps over 100 m 250 Mbps over 200 m Backhauling for WiFi and LTE services have been deployed by several hundred service provid- Bidirectional data exchange Building to building connectivity ers and thousands of enterprises. Over the past twenty years, our innovative connectivity solutions have helped to drive our Dynamic rate adaptation Redundancy for fixed line connection customers’ networks forward, helped to drive their businesses Latency: < 2 ms to new levels of success. We forge close working relationships 1 GbE chipset and interface with all our customers. As your trusted partner we ensure that Footprint and weight: 240 mm x 230 mm x 130 mm, 3 kg Distributed by: we’re always ready to exceed your networking expectations. E-Mail: [email protected] www.advaoptical.com Web: www.hhi.fraunhofer.de/LED-Backhaul 69 Fraunhofer Heinrich Hertz Institute | Photonic Networks and Systems General Informations ECOC 2016 Conference Venue The basic charge is 4.50 EUR, each additional kilometre will cost 2 EUR. For credit card payments, a surcharge of 2 EUR will apply. Congress Center Düsseldorf (CCD) For taxi rides from Düsseldorf Airport to all of the entrances of Mes- Stockumer Kirchstraße 61 se Düsseldorf or vice versa, a special price of 20,00 EUR for each 40474 Düsseldorf, Germany ride applies day and night. www.d-cse.de By Car ECOC 2016 Organization Office Just follow the signs to Messe Düsseldorf. When you reach the VDE-Conference Services Phone: +49-(0)69-63 08-477 immediate congress centre environs, follow the special signs CCD Ms Hatice Altintas Fax: +49-(0)69-63 08-144 Stadthalle, CCD Süd or CCD Ost and the parking signs P3, P4 or Stresemannallee 15 E-mail: [email protected] P5. If necessary, the big car parks at Messe Düsseldorf can also 60596 Frankfurt, Germany Internet: www.ecoc-conference.org be used. Input data for your GPS: ECOC 2016 Website and App Rotterdamerstrasse 144 All the information concerning the ECOC 2016 Conference can be 40474 Düsseldorf found at: www.ecoc-conference.org Parking (Fee: 3 € per hour/max. 15 €) The Conference app ECOC 2016 is available to download for And- roid devices (https://play.google.com/store/apps) and Apple de- More than 1,200 parking spaces are available right by the CCD vices (https://www.apple.com/itunes/) Congress Center Düsseldorf. The Düsseldorf fair is easily reached by car and around the CCD Congress Center Düsseldorf are seve- Wi-Fi ral parking areas, which provides many and close parking options. There will be free WIFI access available in the conference venue Parking space 1: including the conference rooms, the foyers as well as the Exhibition CCD 4: Address: Stockumer Kirchstraße, 40474 Düsseldorf Hall. Parking space 2: Search for network name: ECOC2016 CCD 3: Address: Stockumer Kirchstraße, 40474 Düsseldorf Enter Password: pam4keysight Parking space 3: CCD 5: Address: Rotterdamer Straße, 40474 Düsseldorf Parking space 4: How to get to Düsseldorf & the Venue P7 Messe Ltu-Arena / Esprit Arena: Address: Ltu-Arena-Straße 1, 40474 Düsseldorf By Public Transport Travelling from the north The U78/U79 underground lines and the 722 bus will take you Follow the A52 in the direction of Düsseldorf. Change to the A44 quickly and conveniently to the CCD Congress Center Düsseldorf. in the direction of the airport (Düsseldorf Flughafen). Leave the mo- torway at the Düsseldorf Stockum exit and follow the signs CCD Take the U78 (from the direction of the city centre) or the U79 (from Süd / CCD Stadthalle. the direction of the city centre, Kaiserswerth, Wittlaer and Duis- burg) to the Messe Ost/Stockumer Kirchstrasse stop. From Travelling from the south there it is a roughly 15-minutes’ walk, across Stockumer Kirch- Follow the A57. At Meerbusch switch to the A44 in the direction of strasse, to the CCD Congress Center Düsseldorf. the airport (Flughafen). After the tunnel leave the motorway at the Alternatively you can take the 722 bus (from the main train station) Messe / Arena exit and follow the signs CCD Süd / CCD Stadthalle. to the last stop CCD Stadthalle (entrance to the ECOC venue). Travelling from the east Shuttle Busses Follow the A3. At Velbert take the A44 in the direction of the airport Shuttle busses will be available from the underground station (Flughafen). Leave the motorway at the Düsseldorf Stockum exit ”Messe Ost/Stockumer Kirchstrasse” to the CCD Stadthalle. and follow the signs CCD Süd / CCD Stadthalle. Travelling from the west Free Public Transportation Ticket Follow the A57. At Meerbusch switch to the A44 in the direction of All the registered conference delegates will receive a 5 day the airport (Flughafen). After the tunnel leave the motorway at the “KombiTicket” giving access to all the public transportations Messe / Arena exit and follow the signs CCD Süd / CCD Stadthalle. (Bus, Underground, S-Bahn) within and in the surroundings of Düs- seldorf including the Düsseldorf Airport. Taxi from Airport Accommodation The airport is just three kilometres from the CCD Congress Center During the conference you can contact the hotels agencies below Düsseldorf. for room changes or any other questions concerning your room Düsseldorf taxi switchboard: +49 (0)211 333-33 reservation. or: +49 (0)211 999-99 Rhein-Taxi: +49 (0)211 212121 70 Business Travel & Convention Service Team Social Events Phone: +49 (0)211 17 202-839 Fax: +49 (0)211 17 202-3221 E-mail: [email protected] Get Together Drink Website: www.duesseldorf-tourismus.de/en/conference/ecoc Sunday, September 18, 18:00 - 19:30 Location: Conference Venue CCD, Wintergarden Restaurant South Smart and More Service Team Attendance to the Get Together is included in the Conference re- Phone: +49 (0)40 88 171 240 gistration fee. Conference delegates will not be issued an extra E-mail: [email protected] ticket, the Conference badge will grant you access to the Get To- Website: www.tms.smartandmore.de/ecoc/2016 gehter.Join your colleagues for a pre-conference drink. Access is free to all registered conference delegates. Onsite Registration Welcome Reception Monday, September 19, 18:00 - 20:30 The Conference Registration desk is located in the Foyer of the Location: Conference Venue CCD, Big Foyer Stadthalle Stadthalle (see map on page 79) Attendance to the Welcome Reception is included in the Confe- Please note that the Exhibition registration desk will also be located rence registration fee. Conference delegates will not be issued an at the Congress Centre Stadthalle. You do not need to register for extra ticket, the Conference badge will grant you access to the the exhibition as the Conference badge gives you full access to it. Welcome Reception. Additional Welcome Reception tickets can be The Exhibition will be located in Hall 3 (see map on page 78, 79). booked at the Conference registration desk. Conference Registration Opening Times Conference Dinner Wednesday, September 21, 19:30 - 22:30 Sunday, September 18. . . . 08:00 – 18:00 Monday, September 19 . . . 08:00 – 18:00 Location: The Classic Remise (a center for vintage cars in a his- toric roundhouse for locomotives.) Tuesday, September 20. . . 08:00 – 18:00 Wednesday, September 21 . . 08:00 – 18:00 The Conference Dinner is NOT included in the conference regist- ration fees. Thursday, September 22 . . . 08:00 – 16:00 Conference delegates who have registered and paid for the confe- Name Badges rence dinner will get a ticket together with their conference badge at the Conference Registration desk. Delegate badges must be worn at all times to gain access to the conference sessions, exhibition and social events. A limited number of tickets are still available to purchase at the Conference registration desk. Baggage Room and Cloakroom for Delegates The transfert to the location Classic Remise will be done by There are cloakroom facilities at the CCD within the Conference Oldtimer busses: and Exhibition registration area. The Organizers cannot be held Meeting point and departure: In front of the Conference Registrati- responsible for damage to or loss of their personal property hows- on desk at 18:00 h. oever caused. Return bus services will be provided from the Classic Remise to the Congress Centre. Opening Times Classic Remise Düsseldorf Sunday, September 18. . . . 08:00 – 20:00 Harffstr. 110a Monday, September 19 . . . 08:30 – 22:00 D – 40591 Düsseldorf Tuesday, September 20 . . . 08:00 – 18:30 Phone: +49 (0)211 22950570 Wednesday, September 21 . . 08:00 – 18:00 Fax: +49 (0)211 22950579 E-Mail: [email protected] Thursday, September 22 . . . 08:00 – 17:00 Coffee Breaks and Lunch Coffee breaks: Coffee breaks are included in the conference registration and will be held in the following places and times: Day Location Time Sunday, September 18 Foyer CCD close to the conference rooms 15:30 – 16:00 Monday, September 19 Exhibition Hall 15:30 – 16:00 Tuesday, September 20 Exhibition Hall 10:30 – 11:00 Wednesday, September 21 Exhibition Hall 10:30 – 11:00 + 15:30 – 16:00 Thursday, September 22 Foyer CCD close to the conference rooms 10:30 – 11:00 71 General Informations Lunch: Lunch is NOT included in conference registration fees. However there are a variety of “Food Beverage selling points” and Restau- rants in the CCD as well as inside the Exhibition Hall, where the coffee breaks will be served from Monday to Wednesday. Restaurant / Refreshment Opening Days and Times Sunday, September 18 CCD Süd Restaurant 10:00 – 17:00 Monday, September 19 Exhibition Hall - Pick up One 09:00 – 16:30 Exhibition Hall - Pick up Two 09:00 – 16:30 Main Foyer Bar 08:00 – 18:00 Exhibition Hall Delegate Coffee Point 1 09.30 – 16:30 When delegate coffee is not being served. Exhibition Hall Delegate Coffee Point 2 09.30 – 16:30 When delegate coffee is not being served. Exhibition Hall Restaurant 11:00 – 15:00 Sit down. Hot and cold food served. CCD Süd Restaurant 11:00 – 15:00 Sit down. Hot and cold food served. Tuesday, September 20 Exhibition Hall Pick up One 09:00 – 16:30 Exhibition Hall Pick up Two 09:00 – 16:30 Main Foyer Bar 08:00 – 18:00 Exhibition Hall Delegate Coffee Point 1 09.30 – 16:30 When delegate coffee is not being served. Exhibition Hall Delegate Coffee Point 2 09.30 – 16:30 When delegate coffee is not being served. Exhibition Hall Restaurant 11:00 – 15:00 Sit down. Hot and cold food served. CCD Süd Restaurant 11:00 – 15:00 Sit down. Hot and cold food served. Wednesday, September 21 Exhibition Hall Pick up One 09.30 – 16:00 Exhibition Hall Pick up Two 09.30 – 16:00 Main Foyer Bar 08:00 – 18:00 Exhibition Hall Delegate Coffee Point 1 09.30 – 16:00 When delegate coffee is not being served. Exhibition Hall Delegate Coffee Point 2 09.30 – 16:00 When delegate coffee is not being served. Exhibition Hall Restaurant 11:00 – 15:00 CCD Süd Restaurant 11:00 – 15:00 Thursday, September 22 CCD Süd Restaurant 10:00 - 17:00 ECOC Exhibition ECOC 2016 Programme The Exhibition will take place in Hall 3 of the CCD. The conference Details of times and technical sessions can be found on the ECOC participants have automatically access to the exhibition. On Tues- website: day, September 20, the conference will stop from 14:00 – 16:00 www.ecoc-conference.org/Programme to allow the Conference participants to visit the Exhibition. www.ecocexhibition.com A printed copy of the programme will be included in the conference bags upon registration. Exhibition opening hours: A digital copy of the programme and papers will be also included Monday, September 19 . . . 09.30 – 17:00 on the USB memory stick (proceedings) as well as in the confe- Tuesday, September 20. . . 09:30 – 17:00 rence app. Wednesday, September 21 . . 09:30 – 16:00 72 Workshops Post Deadline Papers Proceedings Sunday, September 18, 13:30 – 18:00 ECOC 2016 printed proceedings of post-deadline papers will be Conference Venue (CCD) available starting Tuesday, September 20, morning on the messa- See details in your printed copy of the programme or on the websi- ge board and at the Confverence Registration desk. te or in the conference app ECOC 2016 which is available to down- Currency & ATM Machine load for Android devices (https://play.google.com/store/apps) and Apple devices (https://www.apple.com/itunes/). The 6 workshops The currency in Germany is Euros €. are open to all conference delegates. The venue has an ATM Machine located at the south entrance. Opening and Plenary Session Electrical Charging Points Monday, September 19, 10:00 – 12:00 There will be electrical charging points in the CCD (voltage is Auditorium (Room 1), Conference Venue (CCD Stadthalle) 220 v.). Depending on your device, a plug adaptor may be neces- The plenary session is open to delegates, exhibitors / exhibition sary; please check in advance. visitors and the general public. Press Room Poster Sessions The Press Room is located in the Exhibition Hall. The poster area will be located in the Big Foyer of the CCD Stadt- Only press representatives correctly identified will be allowed to halle. use this room. Poster presenting authors can display their poster starting from Tu- esday, September 20, from 09:00 h and they may remain until the Messages end of the Conference on September 22, 2016, 16:00 h. A board is at the disposal of delegates in the Conference Registra- Posters not withdrawn after that time will be destroyed. tion area to leave messages to their colleagues and friends. Poster Session I: Wednesday, September 21, 16:00 – 17:30. First Aid Poster Session II: Thursday, September 22, 11:00 – 12:30. The venue medical centre is located within the south entrance of Oral Sessions the CCD. Please also come to the organizers office and report any medical instances. All oral, contributed, invited, tutorial, symposia and post-deadline sessions will be presented at the Conference Venue (CCD Stadt- In case of medical emergency or unexpected need, please come halle). to the onsite registration desk located in the CCD Stadthalle, ground floor. From Monday, September 19 to Thursday, September 22. See details in your printed copy of the programme or on the web- No smoking policy site or conference app. According to German law smoking is prohibited inside any buil- ding, venue, hotels, busses, etc. Smoking is only allowed at open Media Check air zones. The media check room is located in the CCD Room 10. Lost-and-Found Authors are asked to upload their PowerPoint Presentation in the media check room at least 30 min. prior to their sessions begin. Lost-and-Found will be collected in room 12, located at the first floor of the CCD Stadthalle. For authors scheduled on Sunday, September 18 during a work- shop, they should bring their memory stick at least 1 hour before Insurance the beginning of the workshop, directly to their workshop room. The Organizers cannot be held responsible for accidents to parti- Media Check Room opening hours cipants or for damage to or loss of their personal property hows- Sunday, September 18. . . . 14:00 – 18:00 oever caused. Monday, September 19 . . . 08:00 – 18:00 Shopping Tuesday, September 20. . . 08:00 – 18:00 Düsseldorf is one of the most elegant shopping metropolises wor- Wednesday, September 21 . . 08:00 – 18:00 ldwide. Thursday, September 22 . . . 08:00 – 15:00 Visit the exclusive boulevard “Königsallee”, with its variety of lu- xury stores and of course the trendy boutiques of the Altstadt. Closing Ceremony This is shopping at its best! More and more renowned labels are Thursday, September 22, 15:30 – 16:00. attracted to Königsallee. The names of fashion designers having shops in Düsseldorf read like the Who‘s Who of the trade – Armani, The closing ceremony, including the Best Student Paper Award Dior, Gucci, Strenesse, Prada, Miu Miu, JOOP, Jil Sander, Zegna, sponsored by ADVA will take place in Room 1 (Auditorium). The Féraud and many more. closing ceremony is open to all registered participants. 73 74 Route Map U79 / Duisburg S6 Essen t mund a r Bochum S1 Do Fernbahnhof/Station D–Airport Lohausen Skytrain S11 ESPRIT arena/ D-Flughafen/ Messe Nord Airport U78 No Terminal Bus rd/No 896 rth örikestraße M D-Unter- Freiligrathplatz rath t Bus 896 r o p r i A le Sü Ost/ / al d/ n th S Eas ad outh t fe St a D d h C Sü t Bus 722 Am g C u CD Messe Ost/ Hain l C F CCD Os Stockumer Mahnmal 1 Kirchstr. 1 S Messe-Center / Messe/ Nordpark/Aquazoo 1 Nordpark Nordfriedhof S Reeser Platz Roßstraße D-Derendorf Bus 722 Th.-Heuss-Brücke D-Zoo Frankenstraße Golzheimer Platz D-Wehrhahn Bankstraße e n er in Kennedydamm g lin Kolpingplatz -F /Rh D Klever Straße ein S8 h Venloer Straße U76/U70 R Wuppertal Duisburger Straße Krefeld Nordstraße S28 U79 / Schloß Jägerhof Duisburg S6 Essen mund U75 Neuss/ t a r Mettmann Bochum S1 U74 H.-Heine- Adlerstraße Do Meerbusch alle Fernbahnhof/Station Allee D–Airport nh Pempelforter Straße Lohausen Skytrain o S11 T ESPRIT arena/ D-Flughafen/ Messe Nord Airport Worringer Platz U78 No Terminal Bus rd/No 896 rth örikestraße M D-Unter- Freiligrathplatz rath t Bus 896 r o p r U78 i A / le Sü Ost/ / al d/ n e e th S DüEas sseldorf o fe ß U79 ad uth t ß St a ten a D d h r e ra C Sü t Bus 722 Am g C u e t CD Hbf/MainMesse Statio Ost/ n Hain l l C F l s CCD Os Stockumer nst a t Mahnmal 1 i s Kirchstr. 1 s lksgarS e O Messe-Center / t g Messe/ Nordpark/Aquazoo o 1 i S S Nordpark NordfriedhofV ön K Reeser Platz D- Roßstraße D-Derendorf Bus 722 Th.-Heuss-Brücke D-Zoo Frankenstraße D-Oberbilk Golzheimer Platz D-Wehrhahn S1 Bankstraße e n er in Kennedydamm Solingeng lin Kolpingplatz -F S28 Kaarst/Neuss /Rh D ein Klever Straße h S8 R D Venloer Straße U76/U70 Wuppertal -F Duisburger Straße Krefeld Nordstraße S28 U75 Neuss/ rie Schloß Jägerhof Mettmann S8 U7D4 H.-Heine- Adlerstraße Meerb-Busch dalle nh Allee Pempelforter Straße To ric Mönchengladbach/ ilk Worringer Platz h s Neuss ta U78 e/ S ß U79 ße Düsseldorf ten 0 ra e ra 6 d lle st Hbf/Main Station 1 inst sa st t te g O olksgar 0 S ni V K Kö D- ö 2 ln / D-Oberbilk S1 3 0 S11 Solingen S28 Kaarst/Neuss : D -F d rie D n Köln/Dormagen/Neuss S8 -B d ric Mönchengladbach/ ilk a h t Neuss sta S S 6 0 d 1 t K 0 ö 2 ln / 3 0 S11 : d Köln/Dormagen/Neuss n a t S 75 Exhibitor Index 3D-Link Technology Co Ltd 527 Dimension Technology Co Ltd 592 HUBER+SUHNER Cube Optics AG 259 3M Electronics TT106 Discovery Semiconductors Inc. 569 Hunan Newfiber Optical Electronics 691 AC-UNION Technology Co Ltd 341 DLL Partners 639 Co Ltd Accelink Technologies Co Ltd 650 Dongguan Mentech Optical & Magnetic 135 HYC Co Ltd 312 ACE Marketing Inc 597 Co Ltd HYESUNG Cable & Communication 394 Adamant Company Ltd 658 DongJie Optical Co Ltd 340 Hysolution Co Ltd 398 Adsantec Inc 344 East Photonics Inc 296 IHP GmbH 350 Advantest 228 ECOC Conference 2017 545 II-VI Photonics 730 ILSINTECH 316 AEMtec GmbH 315 EFFECT Photonics BV 625 INNO Instrument Inc 200 Agilecom 225 EGIDE 212 InnoLight Technology Corporation 704 Alfafonet S.A. 646 Electro Rent Europe NV 424 Innolume GmbH 670 AFL 612 Electrovac Hermetic Packages 638 Inphi Corporation 250 AFL Noyes 102 Eloik Communication Equipment 230 Technology Co Ltd InPhoTech sp. z o. o. 338 Aitelong Technology Co,Ltd 270 Ensure International Ltd 346 Intel Corporation 208 Aksh Optifibre Limited 131 Eoptolink Technology Inc Ltd 127 IXBLUE 395 Albis Optoelectronics AG 418 EPIC - European Photonics Industry TT112 Jabil AOC Technologies 637 AMICRA Microtechnologies GmbH 214 Consortium Jakob Thaler GmbH 216 Amphenol Fiber Optic Products 714 EUROMICRON Werkzeuge GmbH 554 JBTX Communications Co Ltd 713 AMS Technologies AG 132 EXFO Inc 129 JGR Optics Inc 558 Anritsu Ltd 419 EZconn Corporation 678 Jiangsu Hengtong Optic-electric Co Ltd 276 APEX Technologies 374 Fasten Group Imp & Exp Co Ltd 521 Joinwit Optoelectronic Technical Co Ltd 640 Applied Optoelectronics Inc 102 Fi-ra Photonics Co Ltd 328 Jyh Eng Technology Co Ltd 642 Aragon Photonics Labs 660 Fiber Instrument Sales 226 Kaiam Corporation 389 Arden Photonics Ltd 540 Fiber Optic Center Inc 706 Keynet Systems 137 ATK Fibra Optica 345 Fibercore Limited 132 Keysight Technologies Deutschland 400 Axetris AG 630 FiberFox Inc 220 GmbH Baylite Opto-Electornics Technology 620 Fiberlaunch PH Palden TT105 Kingfisher International Pty Ltd 132 Co Ltd Fibernet 390 Kohoku Kogyo Co Ltd 286 Berlin-Brandenburg Pavilion 350 Fiberon Technologies, Inc 719 Korea Optron Corp 241 Birla Ericsson Optical Limited 596 FIBERPRO Inc 716 KS Photonics 240 BKT Elektronik 367 FiberQA 711 KTI-Katron Technologies Inc 626 BKtel components GmbH 297 FibreFab Limited 209 Lande Rack Cabinet & Fiber Optic 644 Blue Sky Instruments LLC TT111 ficonTEC Service GmbH 288 Solution Browave Corporation 619 Finisar Corporation 500 Laser Components GmbH 102 CAILabs 676 FITEL Furukawa Co Ltd 102 LiComm Co Ltd 388 CBS Products Ltd 216 Flyin Optronics Co Ltd 321 Light Tec 231 Cellco Communications Ltd 700 Fraunhofer Heinrich Hertz Institute 350 Lightel 102 CENKABLO AS 285 Fraunhofer IPMS 327 Linktel Technologies Co Ltd 708 Changzhou LINKET Electronic 677 Lite Linke 289 Technology Co Ltd Fujikura Europe Ltd 612 Luciol Instruments SA 132 Changzhou Myway Electronics Co Ltd 280 Fujitsu Optical Components Limited 725 Lumentum 600 Chengdu Huajingkeli Industry Co Ltd 281 Gamm-Bud sp.z o.o. 399 MACOM Technology Solutions Inc 645 China Aviation Optical-Electrical 588 General Photonics 102 Technology Co Ltd GigPeak, Inc 514 Mellanox Technologies 124 Cixi Feitian Technology Factory 595 GIP Technology Corp 624 Metallife Inc 298 Cixi Jitong Electronics Co Ltd 593 Global Optical Communication Co Ltd 227 METZ CONNECT GmbH 292 CMP 397 Gloriole Electroptic Technology Corp. 714 Micram Microelectronic GmbH 362 CN-J Technology Co Ltd 668 GO!FOTON Corporation 429 micro photonics 350 CODIXX AG 634 GOLDTEL (Korea) 330 Mills Limited 125 Coherent Solutions Ltd 542 Hansen Technology Co Ltd 635 ModuleTek Limited 692 ColorChip 717 HARTING Electronics GmbH 331 Molex LLC 300 Connected Fibers TT107 Hexatronic AB 378 MoSys, Inc 343 CRESTEC Corporation 599 Heylo-Tubes S.A. 121 Munich-Instruments GmbH 335 Crowntech Photonics 387 HIKIFUNE Co Ltd 218 municom GmbH 117 CYT International (HK) Limited 320 Himachal Futuristic Communications 392 Nanjing DVP Tech Co Ltd 525 Data Communication Technology 728 Limited (HFCL) Nanjing Jilong Optical Communication 574 Limited HJ3•W Inc 266 Co Ltd DATA-PIXEL 664 HOBBES GmbH 217 Nanjing Suntrap Co Ltd 690 Deviser Instruments, Inc 703 HOLOEYE Photonics AG 336 Nanjing Tianxingtong Electronic 325 Technology Co Ltd DiCon Fiberoptics Inc 213 HongAn Group Co Ltd 334 Huawei Technologies Co Ltd. 517 Nanolap Technologies LLC 132 76 Exhibitor Index nanosystec GmbH 621 SANWA Electronics USA Corporation 215 SYLEX, s.r.o. 128 NeoPhotonics 562 SEDI 102 Synopsys, Inc. 231 Netram Memory GmbH 329 Seikoh Giken 512 Synox Tech Co Ltd 695 Ningbo Geyida Cable Technology Co 581 Semtech Corporation 308 SZ Jingmi Weiyi Optical Electricity Tech 722 Ltd SENKO Advanced Components (Euro) 263 Co Ltd Ningbo Haishu EFON Communication 239 Limited T Plus Co. Ltd TT108 Equipment Limited Shanghai Changyue Communications 710 T&S Communications Co Ltd 324 Ningbo Jinze Telecommunication 580 Co Ltd Takfly Communications Co Ltd 407 Equipment Co,Ltd Shanghai Grandway Import & Export 686 Tech Optics Ltd 126 NISSIN KASEI Co Ltd 639 Co Ltd Tektronix UK 370 Norland Products Inc 132 Shanghai Stone Communication Tech 134 Teledyne LeCroy GmbH 542 Novobit AG 663 Co Ltd Telegaertner Karl Gaertner GmbH 366 Novoptel GmbH 350 Shenzhen Allopto Limited 618 TeraXion 666 NTest, Inc TT110 Shenzhen C-Light Network 386 Communication Co Ltd Tongding Interconnection Information 526 NTT Advanced Technology Corporation 567 Co Ltd Shenzhen Chinaopticcable Co Ltd 529 NTT Electronics Corporation 566 Tri-Comms Suzhou Limited 689 Shenzhen Datolink Communication 326 O-Net Communications (Shenzhen) Ltd 422 Technology Co,Ltd TTI Fiber Communication Tech Co,Ltd 274 Oclaro Inc 384 Shenzhen DYS Fiber Optic Technology 575 ULTRA TEC Manufacturing Inc 102 OE Solutions 538 Co,Ltd Universität Duisburg-Essen 694 OFC 113 ShenZhen FI-Cable Technology Co,Ltd 272 UNO Electronic (Ningbo )Co Ltd 224 OFR Telecom Private Limited 120 Shenzhen Fibercan Optical Co.Ltd 547 US Conec Ltd 404 Open Line Fiberoptic Srl 428 Shenzhen FlyinLink Co,Ltd 323 VeEX Inc 723 Oplink Communications LLC 300 Shenzhen Gigalight Technology Co,Ltd 701 Vetter GmbH Kabelverlegetechnik 680 OpTek Ltd 132 Shenzhen HKT Electronic Science & 571 Viavi Solutions 550 Optic River Communication Ltd 688 Technology Ltd Viavi Solutions Deutschland GmbH 102\ Optical Connections TT109 Shenzhen LASUN Network Cabling 291 VietFiber Limited Liability 629 Co Ltd Optiwave 391 VLC Photonics S.L. 116 Shenzhen OlinkPhotonics Inc.,Ltd 322 Opto Marine Co Ltd 541 VPIphotonics GmbH 350 Shenzhen Owire Investment & 628 OPTOKON a.s. 101 Wenzhou Hantang Telecommunications 284 Development Co Ltd Optoscribe Ltd 674 Co Ltd Shenzhen SDG Information Co Ltd 577 OptoTest Corporation 622 Wuhan Fiberpon Technology Co Ltd 234 Shenzhen Sinovo Telecom Co Ltd 587 Optoway Technology Inc 515 Wuhan Huagong Genuine Optics 576 Shenzhen Sourcelight Technology 675 OPTRAL 337 Technology Co Ltd Limited Opwill Technologies(Beijing) Co Ltd 671 Wuhan RayOptek Co,Ltd 271 Shenzhen Tibtronix Technology Co,Ltd 721 OSA 104 Wuhan Yilut Technology Co Ltd 520 Shenzhen Wonderwin Technology 715 Wuxi Taclink Optoelectronics 235 Otrans Communications Technologies 238 Co,Ltd. Co Ltd Technology Co Ltd Shenzhen YiXi Electronics Co Ltd 693 OZ Optics Limited 718 www.fiberopticshop.rs 661 Shenzhen Youngsun Com Optical Fiber 720 XGIGA Communication Technology Co 570 Peak Fiber Communications Co Ltd 539 Cable Co.Ltd. Ltd Phenix Fiber Optic Co,Ltd 530 SHF Communication Technologies AG 350 Xinsenhua Technology Industrial 229 Philips GmbH U-L-M Photonics 586 Shineway Technologies (China) Inc 681 Development Phoenix Contact GmbH & Co. KG 122 Sichuan Guangfa Technology Co Ltd 279 Yangtze Optical Fibre & Cable Joint 684 Phoenix Photonics Ltd 425 Sichuan Jiuzhou Optical Electronics Ltd 524 Stock Co Ltd Photon Delta 648 Sichuan Tianyi Comheart Telecom 687 YENISTA OPTICS 534 Photon Design 100 Co,Ltd Yokogawa Europe B.V 516 Photonics Cluster in Berlin and 350 Sicoya GmbH 350 Yueqing Reepure Telecom Technology 237 Brandenburg SiFotonics Technologies Co Ltd 544 Co Ltd PhoxTroT 350 SMART Photonics B.V. 627 ZGT Optical Comm Limited 669 Phyforce Technologie GmbH & Co. KG 350 Source Photonics 608 Zhejiang Chaoqian Communication 277 Picometrix 262 Sticklers® Fibre Optic Cleaners by 376 Equipment Co,Ltd Plumettaz SA 680 MicroCare Corp Zhejiang Tribrer Communication 531 Polatis Inc 616 Sumec Machinery & Electric Co.Ltd. 546 Technology Limited Polymicro Technologies 102 Sumitomo Electric Europe Limited 410 Zhengzhou Shijia Communication 584 Technology Co,Ltd Polywater Europe BV 427 Sumix Corporation 314 ZTT International Limited 408 PPI Inc 342 Suncall America Inc 115 PriTel Inc 662 Sunstar Communication Technology 679 Prolabs 258 Co,Ltd Proximion AB 378 Suzhou Green Telecom Technology Co 236 Ltd RANOVUS 672 Suzhou TFC Optical Communication 273 Redfern Integrated Optics 102 Co Ltd Santec Europe 406 77 MR4MR6 MR7 MR8 MR9MR10MR11MR13 MR15 TV Studio MR2 MR3 MR5 645 648 599 596 547 546 399398 3462297 98 MR12 MR14 Exhibition Floorplan 644 597 397 396 296 MR1 695 694 595 594 545 544 395394 345344 292 MR16 Press 716 693 692 642 593 592 542 392 343342 Office 137 MR4MR6 MR7 MR8 MR9MR10MR11MR13 MR15 TV StudioExhibition MR2 715 691 690 639 640 588 541 540 391 390 341 340 291 288 241 240 135 730 120 MR3 MR5 645 648 599 596 547 546 399398 3462297 98 MR12 MR14 Floorplan 714 689 688 638 539 538 389388 337 338 289 239 238 119 644 597 397 396 296 687 686 637 587 586 534 387 386 336 286 237 236 MR1 118 695 694 595 594 545 544 395394 345344 292 634 MR16 Delegate Coffee and 285 713 684 635 584 Refreshment Area 384 335334 284 235 234 134 19 - 21 Sept 2016 728 Press 117 716 693 692 642 593 592 542 392 343342 Office 137 116 711 681 680 629 630 581 580 531 530 429 428 408 378 331 330 281 280 231 230 132 Exhibition 727 115 715 691 690 639 640 588 541 540 391 390 341 340 291 288 241 240 135 679 678 628 577 576 529 526 427 424 329328 279 276 229 228 MR15 MR16 120 119 118 117 730 116 115 113 112 111 110 109 108 107 106 105 104 102 101 100 725 120 113 710 131 Floorplan 714 689 688 638 539 538 389388 337 338 289 239 238 677 676 627 626 527 425 376 327326 277 227 226 119 687 686 637 587 586 534 387 386 336 286 237 236 118 634 Delegate Coffee and 285 MR14 137 135 134 132 713 131 684 129 635 128 127 584 126 125 124 Refreshment Area 122 38121 4 335334 284 235 234 134 19 - 21 Sept 2016 728 708 675 674 625 624 117 575 574 525 524 CTTS 407 374 325 324 273 2742225 24 129 Training 671 672 621 622 116 571 570 521 520 422 370 323 322 272 220 112 24 406 23 0 22 8 22 6 21 8 21 6 23 6 23 4 20 8 24 0 23 8 21 4 21 2 R1 3 711 681 680 629 630 581 580 531 530 429 428 408 378 331 330 281 280 231 230670 132 620 321 320 271 270 111 Press Office 727 115 225 231 229 227 220 217 200 237 235 209 241 239 215 213 MR12 679 678 628 577 576 529 526 427 424 329328 279 276706 229 228 128 110 725 Delegate 113 710 Coffee 131 677 676 627 626 527 425 376 327326 and 277 227669 226668 619 618 569 566 517 516 367366 316 266 217 218 127 109 Refreshment 98 Area 27 42 27 2 28 0 27 6 27 0 28 6 28 4 258 26 2 28 8 29 6 666 616 567 216 108 273 281 279 277 271 266 250 285 259 263 291 289 297 292 R1 1M 704 126 107 708 675 674 625 624 575 574 525 524 CTTS 407 374 325 324 273 2742225 24 129 Training 671 672 621 622 571 570 521 520 422 370 323 322 723 272 220663 664 612 112 562 515 514 362 315314 263 262 215 214 106 406 125 28 26 34 14 44 42 32 4 32 2 33 0 32 0 33 6 34 0 33 8 670 620 321 320 271 270 662 111 512 312 213 212 105 08 325 33 1 32 93 32 73 32 1 31 6 300 33 7 33 53 31 53 31 2 34 1 34 53 34 33 32 3 34 62 706 128 110 R1 0M Delegate Coffee and 669 668 619 618 569 566 517 516 367366 316 266 703 217661 218660 127608 109 558 510 419 418 4043350 08 259 258 209 208 124 Refreshment Area 722 658 104 66 88 94 98 666 616 567 216 108 38 6 39 0 39 6 704 721 126 107 102 37 4 37 8 37 6 37 0 36 73 35 0 38 7 38 4 36 2 39 1 38 93 39 7 39 53 39 2 39 93 500 MR 9M 723 663 664 612 562 515 514 362 315314 720 263 262 215 214 106 701 650 600 554 410 400 300 250 200 122 125 662 512 312 719 213 212 105 101 550 718 100 40 8 40 0 40 43 40 7 40 6 700 121 703 661 660 608 558 510 419 418 4043350 08 717 259 258 209 208 124 722 658 104 424 418 422 428 TS Refreshment Area Delegate Coffee and CT raining 721 T 102 429 427 425 410 500 419 720 701 650 600 554 410 400 300 250 200 122 719 101 550 TV Studio 546 544 540 538 718 530 526 524 520 516 514 100 700 121 547 545 542 541 539 534 531 529 527 525 521 515 512 510 500 717 517 MR 8 574 580 576 570 566 586 596 594 592 575 581 577 571 569 567 554 550 587 584 558 562 588 597 595 593 599 630 628 626 624 622 620 618 634 640 638 644 648 MR 7 629 627 625 621 619 616 600 637 635 608 612 639 645 642 680 678 676 674 672 670 668 686 660 664 662 690 688 694 692 R6 681 679 677 675 671 650 687 684 661 658 663 691 689 695 693 669 666 MR5 MR 3 716 715 714 713 711 710 708 706 704 703 701 700 MR 4M 730 728 727 725 723 721 720 719 718 717 722 MR 1 an d Area Coffee Delegate Refreshment MR 2 78 Floorplan Exhibition 19 - 21 Sept 2016 Exhibition, Delegate Coffee, FTTx Centre, Market Focus, CTTS Training Centre, Press Office, Exhibitor floor Meeting Rooms, Refreshment Areas 42nd European Conference and HALL 3 Exhibition on Optical Communication 12 Activity area Restaurant CCD Stadthalle September 18 - 22, 2016 120 capacity Bar Cash & Coffee Point Big foyer Hall 2 CCD Stadthalle Hall XY (CCD Stadthalle) 1st Floor Hall XHall Y VIP Exhibition, Delegate Coffee, FTTx Centre, SH Market Focus, CTTS Training Centre, Press Office, 11 Floor Overviews Exhibitor floor Meeting Rooms, Refreshment Areas HALL 3 10 12 Activity area Restaurant Small foyer 9 19 112 CCD Stadthalle 120 capacity CCD Stadthalle Bar 14 Cash & Coffee Point MR4MR6 MR7 MR8 MR9MR10MR11MR13 ExhibitionMR15 TV Studio Pavillon MR2 Organisers Office 18 111 Big foyer CCD Stadthalle Hall 2 MR3 MR5 645 648 599 596 547 546 399398 3462297 98 MR12 MR14 Hall XY Hall 1 (CCD Stadthalle) CCD Sud Restaurant 420 capacity 644 597 397 396 296 Floorplan Conference and Exhibition Hall XHall Y MR1 695 694 595 594 545 544 395394 345344 292 MR16 VIP 17 Press SH 716 693 692 642 593 592 542 Ground392 Floor343342 Office 137 11 1 Ground Floor 10 (Auditorium) Exhibition Exhibition, Delegate Coffee, FTTxSmall Centr foyer 9 e, 19 112 Conference Opening 110 715 691 690 639 640 588 541 540 391 39Hall0 34 13340 291 288 241 240 135 CCD Stadthalle 16 14 and Keynote Sessions 730 120 Market Focus, CTTS Training Centre, Press Office, Floorplan 714 689 688 638 539 538 389388 337 338 289 239 238 Pavillon 119 Exhibitor floor Meeting Rooms, Refreshment Areas 18 111 687 686 637 587 586 534 387 386 336 286 237 236 Hall 1 CCD Sud Restaurant 420 capacity 118 Hall 2 634 Delegatend CoffeeOffice Officeand 285 Exhibition, Delegate Coffee, FTTx Centre, Up to rooms 713 684 635 584 Up to Exhibition 42 European1 2 Conference384 3353 and34 284 235 234 134 Refreshment Area HALL 3 27, 28, 29 17 19 - 21 Sept 2016 728 and conference 117 Exhibition on Optical CommunicationMarket Focus, CTTS Training Centre, Press Office, 1 Counter 116 (Auditorium) 15 Exhibitor floor Meeting Rooms, Refreshment Areas 12 Activity area Conference Opening 110 711 681 680 629 630 581 580 531 530 429 428 408 378 331 330 281 280 231 230 132 Restaurant 16 727 115 CCD Stadthalle and Keynote Sessions nd SeptemberFoyer 18Conference - 22, &2016 Exhibition 120 capacity 42 European Conference and CCD Stadthalle Bar 679 678 628 577 576 529 526 427 424 329328 279 276 229 228 Bar 725 Registration and Cloakroom HALL113 3 6 Flags Exhibition, Delegate Coffee, FTTx Centre, 710 Exhibition on Optical Communication 131 Cash & Coffee Point 677 676 627 626 527 425 376 327326Market277 Focus,227 226 CTTS Training Centre, Press Office, 12 Activity area Restaurant 15 Entrance CCD Stadthalle September 18 - 22, 2016CCD 120 capacity Stadthalle Exhibitor floor Meeting Rooms, Refreshment Areas Bar Activity area Bar 708 675 674 625 624 575 574 525 524 CTTS 407 374 325 324 273 2742225 24 129 Big foyer Süd 8 Cash & Coffee Point Entrance Hall 2 nd Training CCD Stadthalle Messe Düsseldorf Hall XY Foyer 42 European671 672 Conference621 622 571 and570 521 520 422 370 323 322 272 220 112 (CCD Stadthalle) Activity area CCD Süd ECOC 406 HALL 3 2 Süd 8 Foyer b Exhibition on Optical670 620CommunicationEntrance 321 320 271 270 111 Foyer 2 CCD Süd Rooms 5-8 Hall XHall Y Foyer b 706 Big foyer 1281st Floor110 Rooms 5-8 7 Delegate 12 Activity area Roof Hall 2 7 Coffee CCD Stadthalle Hall 1 Roof Restaurant 2nd Floor Terrace VIP a b c a CCD Stadthalle Hall XY Terrace 4a 4b 4c a 4 4 4 and 669 668 619 618 569 566 517 516 367366 316 266 217 218 127 109 5 5 RefreshmentSeptember 18 - 22, 2016 Exhibition, Delegate Coffee, FTTx Centre, (CCD Stadthalle) 120 capacity SH Area Market Focus, CTTSBar Training Centre, Press Office, Exhibitor Meeting 666 616 567 216 108 11 6 Exhibitor floorCash Meeting & Coffee Point Rooms, Refreshment Areas 26 Floor Overviews Side entrance 1 Hall XHall Y Foyer 6 704 1st Floor 126 107 Rooms 27, 28, 29 CCD Süd (Auditorium) HALL 3 3 10 26 VIP Foyer 723 663 664 612 562 515 514 Exhibition, Delegate Cof362 fee, FTTx Centr315314e,Confere263nce Opening262 215 214 106 SH TAXI 12 Activity area 9 3 and Keynote Sessions 125 Restaurant 28 Small foyer 19 112 Market Focus, CTTS T02raining Centre, Press Office, CCD Stadthalle 662 512 312 213 212 120 capacity105 11 CCD Stadthalle Bar 14 Exhibitor floor Meeting Rooms, Refreshment Areas Cash & Coffee Point Floor Overviews Big foyer 27 TAXI Taxi and Bus Exhibition 01 Hall 2 HALL 3 CCD Stadthalle 10 Pavillon Drop Off PointOrganisers Office Hall XY 703 661 660 608 558 510 419 418 4043350 08 259 258 209 208 124 Entrance 2. Floor 28 ■ Meetin18g rooms 111 Big foyer Foyer (CCD Stadthalle) ■ Backstage 12 Activity area Messe Düsseldorf Hall 2 Restaurant CCD Stadthalle above thSmalle wint foyeer r 9 19 112 Hall 1 CCD Stadthalle CCD Süd Hall XY ■ Service spaces 120 capacity garden restaurantCCD Sud Restaurant 420 capacity 722 658 (CCD Stadthalle) 104 CCD Stadthalle ■ Foyers Bar 14 ■ Cash & Coffee Point Internal usable space Hall XHall Y 27 721 102 Hall XHall Y Exhibition P5 Facility Manager 500 1st Floor Entrance VIP Pavillon 500 Spaces Office 17 Messe Düsseldorf SH 720 Organisers Office Garden- 18 111 1st701 Floor650 600 554 410 Big foyer 400 300 250 200 122 11 VIP 1 Ground Floor Lounge Hall 2 ■ ConferenceExhibition, Rooms DelegateCCD Stadthalle Coffee, FTTxHall CentrXY e,Exhibitor Meeting Rooms SH 2. FlooHall 1r Meeting rooms 719 (CCD Stadthalle) CCD Sud Restaurant 420 capacity101 (Auditorium) 10 ■ Backstage 550 Market Focus, CTTS Training Centre, Press Office, above the winter Small foyer 9 19 112 Conference Opening 110 ■ 718 Hall XHall Y 100 11 Service spaces Hall 3 CCD Stadthalle 16 700 Exhibitor floor Meeting Rooms, Refreshment Areas 14 121 and Keynote Sessions garden restaurant Business-VI P 17 ■ Foyers Restaurants/Bars ExhibitionSH Organisers Office Floor Overviews Lounge Pavillon 717 ■ Internal usable space Ground Floor 11 Counter 18 1 111 10 HALL 3 1 Hall 1 Hall10 2 CCD Sud Restaurant 420 capacity (Auditorium) Office Office Up to Exhibition Up to rooms 1 2 12 Activity area Restaurant Small foyer 9 VIP 19 112 Confe17 rence Opening Small foyer 9 19110 112 and conference CCD Stadthalle 27, 28, 29 Hall 3 CCD Stadthalle 16 14 120 capacity Süd 1 and Keynote Sessions CCD Stadthalle Counter Bar Counter 14 Counter(Auditorium) 15 Cash & Coffee Point Pavillon 3 2 Conference Opening 110 18 111 16 Exhibition R Hall 1 and Keynote SessionsEntrance Foyer CCD Sud Restaurant 420 capacity Conference & Exhibition South / Pavillon CCD Stadthalle Hall 2 Bar Office Office Registration and Cloakroom Up to rooms Messe Süd Up to Exhibition 1 2 Organisers6 Flags Office 111 H 27, 28, 29 17 18 and conference Big foyer 1 Entrance Hall 2 CCD Stadthalle Hall XY CCD Süd Hall 1 Counter (Auditorium) 41 Flags 15 Entrance I (CCD Stadthalle) CCD Sud Restaurant 420 capacity 15 110 CCD Conference Opening 16 Stadthalle N and Keynote Sessions Bar Activity area Foyer Conference & Exhibition Hall XHall Y Süd CCD Stadthalle 18 Flags TAXIAAXI Bar 8 Registration and Cloakroom Entrance 6 Flags E Messe Düsseldorf VIP 17 Foyer Activity area CCD Süd ECOC SH 2 Süd 8 Foyer b Entrance 11 15 Foyer 1 GroundEntrance Floor CCD Süd Rooms 5-8 2 CCD Foyer b 7 Bar Rooms 5-8 (Auditorium) Activity area Stadthalle 10 Roof 7 Hall 1 Roof 2nd Floor Terrace Süd a b c a Terrace 4a 4b 4c a 8 4 4 4 Entrance 5 110 5 Messe Düsseldorf Small foyer 9 19 112 ConfereFoyernce Opening Hall 3 CCD Stadthalle Exhibitor Meeting 16 14 Activity area 2 and6 KeynoteCCD Süd Sessions ECOC Süd 8 26 Foyer b Entrance Side entrance 1 Foyer Foyer P3 6 Pavillon Rooms 27, 28, 29 CCD Süd 2 CCD Süd 3 Rooms 5-8 Foyer 230b Spaces (Auditorium) 111 26 Foyer 18Rooms 5-8 ■ 7 Roof 7 Conference OpeningRoof Hall 1 TAXI Hall 1CCD Sud Restaurant 420 capacity 2nd Floor Terrace a b c a Terrace 4a 4b 4c a 4 4 4 3 02 Hall 2 and Keynote Sessions 28 5 5 Office Office Up to rooms Up to Exhibition 1 2 Exhibitor Meeting and conference 27, 28, 29 17 27 6 TAXI Taxi and Bus 01 26 Side entrance 1 Foyer 6 Drop Off Point Rooms 27, 28, 129 CCD Süd 3 28 ■ Meeting rooms Counter (Auditorium) Entrance (Auditorium) 2. Floor 26 Foyer Foyer ■ Backstage 15 Messe Düsseldorf above the winter Conference Opening CCD Süd TAXI ■ Service spaces Conference Opening garden restaurant 110 16 ■ Foyers and Keynote Sessions 28 and Keynote Sessions 3 02 ■ Internal usable space Foyer Conference & Exhibition 27 CCD Stadthalle P5 Facility Manager Bar 27 Entrance Registration and Cloakroom 500 Spaces Office TAXI 6 Flags Taxi and Bus 01 Messe Düsseldorf Garden- Drop Off Point Lounge Entrance 2. Floor 28 ■ Meeting rooms ■ Meeting rooms Conference RoomsFoyer Exhibitor Meeting Rooms ■ Backstage 2. Floor Messe Düsseldorf above the winter ■ CCD Süd ■ Service spaces Backstage garden restaurant 15 above the winter Entrance ■ Foyers ■ Service spaces ■ CCD Business- Internal usable27 space garden restaurant ■ Bar Foyers Stadthalle P5 FacilityRestaurants/Bars Manager Exhibition Organisers Office Activity area Entrance Lounge ■ 500 Spaces Office Counter Süd Internal usable space Messe Düsseldorf 8 Entrance Garden- 1 Foyer Conference Rooms ExhibitorMesse Düsseldor MeetingLoungf e Rooms 2. Floor ■ Meeting rooms VIP Activity area 2 CCD Süd ■ Backstage ECOC aboveSüd the winter Süd 8 ■ Foyer b Foyer Service spaces Entrance Counter Counter garden restaurant Business- CCD Süd ■Rooms 5-8 3 2 2 Foyers Restaurants/Bars ExhibitionLounge Organisers Office Foyer b R Entrance ■ Internal usable space 7 Counter 79 South / Roof Rooms 5-8 1 7 Hall 1 Roof 2nd Floor Messe Süd Terrace a b c a H Terrace 4a 4b 4c a 4 4 4 Entrance 5 5 VIP CCD Süd Süd I 41 FlagsExhibitor Meeting NCounter Counter 6 3 26 Side entrance 2 Foyer TAXIAAXI R 1 Entrance Rooms 27, 28, 2918 Flags 6 CCD Süd (Auditorium) E South / 3 26 Messe Süd Foyer H TAXI Conference Opening Entrance 3 02 I and Keynote Sessions 41 Flags CCD Süd 28 N 18 Flags TAXIAAXI 27 TAXI Taxi and Bus 01 E Drop Off Point P3 Entrance 2. Floor 230 Spaces 28 ■ Meeting rooms Foyer ■ ■ Backstage Messe Düsseldorf above the winter CCD Süd ■ Service spaces garden restaurant ■ Foyers ■ Internal usable27 space P5 Facility Manager Entrance 500 Spaces Office P3 Messe Düsseldorf Garden- 230 Spaces ■ Lounge ■ Meeting rooms Conference Rooms Exhibitor Meeting Rooms 2. Floor ■ above the winter Backstage ■ Service spaces garden restaurant Restaurants/Bars ExhibitionBusiness- Organisers Office ■ Foyers Lounge ■ Counter Internal usable space 1 VIP Süd Counter Counter 3 2 R Entrance South / Messe Süd H Entrance I 41 Flags CCD Süd N 18 Flags TAXIAAXI E P3 230 Spaces ■ 42nd European Conference ECOC 2016 on Optical Communication September 18 - 22, 2016, CCD Congress Center Düsseldorf organized by ECOC 2016 is supported by following companies SPONSORS Platinum level Gold level Silver level Bronze level PARTNERS MEDIA PARTNERS Innovationsnetz Optische Technologien