The Road of PIONIER Network to User Driven Infrastructure

Total Page:16

File Type:pdf, Size:1020Kb

The Road of PIONIER Network to User Driven Infrastructure The Road of PIONIER Network to User Driven Infrastructure Artur Binczewski, Robert Pękal, Maciej Stroiński National Research and Education Network: PIONIER • Area 312k sq km • Population 38M • Main academic centers 21 • State universities 165+ • Students 2M+ • R&D institutions and Univ. interconnected via PIONIER network 700+ 6663 km of fiber infrastructure in Poland 2359 km of fiber in Europe (IRU) 9022 km of fiber in total National Research and Education Network – PIONIER ROSSIA (PIONIER ready to connect) GDAŃSK LITHUANIA (LITNET 1 x 10G, GLIF 1 x 10G, Suwałki GÉANT 2 x 10G) KOSZALIN Elbląg SZCZECIN OLSZTYN BELARUS (BASNET 1 x 10G) GERMANY BYDGOSZCZ (DFN 1 x 10G) BIAŁYSTOK Gorzów TORUŃ Hamburg (AMS-IX, GLIF, SURFNet, NORDUnet) Frankfurt (DC-IX) Genewa (CERN) n x 100 Gb/s POZNAŃ WARSZAWA ZIELONA GÓRA PUŁAWY ŁÓDŹ RADOM LUBLIN CZĘSTOCHOWA WROCŁAW DWDM3 – n x 100G Zamość Colorless, directionless and KIELCE coherent 96 ch system OPOLE DWDM2 – n x 10G Colorless, directionless and UKRAINE contentionless 80ch system KATOWICE (URAN 1 x 10G, UARNET 1 x 10G) DWDM 1 – 2 x 10G KRAKÓW RZESZÓW Direct fiber connection CZECH REPUBLIC Bielsko-Biała (CESNET 1 x 10G GLIF 1 x 10G) PIONIER network node SLOVAKIA (SANET 1 x 10G) Pan-European backbone of PIONIER network Services deployed for eScience in PIONIER Network Communication Access & Clouds Data New Media Security Preservation Applications Eduroam on Demand Services for digital Federated Identity Databases libraries (Pionier.Id) on Demand Archiving Virtual firewall Infrastructure on Demand on Demand Service platforms deployed in PIONIER Network U1 – Videoconference Services MH1 – Virtual machines and applications U2 – Eduroam Services in the cloud U3 – Campus Services MH2 – Drive and computer in the cloud U4 – Archiving Services MH3 – Office applications in the cloud U5 – Science HD TV Services MH4 – SQL database in the cloud MH5 – PIONIER.Id Federated Identity Management MH6 – Services for the digital libraries – Web conferencing in the MAN-HA project MH8 – Local nodes monitoring MH9 – Virtual firewall Service Coordinator Main service node Service partner High Performance Computing Center Computing: • HPC infrastructure (1.4 PFLOPS now, 110th position on TOP500 list) • 2 data-centers • HPC/HTC systems • Additional prototype installations Storage: • Hierarchical data infrastructure (47 PB) • Part of European Data Infrastructure Environment: •300+ sqm in data center #1 •1600 sqm in d.c. #2 •Air, liquid coolled systems, DLC •Video monitoring, fire protection •24h monitoring PSNC is part of: •European HPC infrastructure (PRACE) •European and national grid infrastructure (EGI, PL-GRID) •National (Platon, NDS) and European data infrastructure (EUDAT) E-infrastrucutre for Big Data simulations and analitics Laboratories ready for ICT innovation • Laboratory of e-infrastructure management • Laboratory of integration of communication technologies • Laboratory of optical networks with programmable optics 100/400/1000G • Laboratory of open network equipment • Laboratory of simulation and integrated control resources in multi-domain network ecosystems • Laboratory of software-defined networks Laboratories ready for ICT innovation • Laboratory of UHD new media services in optical networks • Laboratory of data center management and energy-efficient systems • Laboratory of cyberspace security and critical infrastructures protection • Laboratory of enevironment-friendly information technology – „Green ICT” • Laboratory of service software technologies • Laboratory of remote processing and distribution of immersive content Laboratories ready for ICT innovation • Laboratory of visualization and interaction • Laboratory of voice interface technologies for next generation services • Laboratory of telemedicine • Virtual laboratory for e-Science • Laboratory of ICT integration with environment • Laboratory of integration of network services with IOT networks and scientific use of social infrastructures • Data Center / Experimental service support node for laboratories and remote access Lab(IT)aaS Living labs ready for ICT innovation • Digital Humanities • Intelligent environment • New Media • Innovative education • Coworking space The Social Aspects of Digital Science LivingLabs Coworking Space Production and dissemination of the results of User participation in research and quality Animates 16 communities around scientific research and development projects assessment solutions business-related and technology interests d.challenge TechKlub Business Cafe Scrum City Game Toastmasters TEDx AKAI Activity HIVE61 Java User Group Education Erlang Community 60+ Startup Weekend Mobilizator Angular JS (NG Poznan) Android Winter School REACT Poznan Meet PHP Interaction Digitization Support for StartUps with of cultural digital world Lab4motion SellBox SMS Eagle heritage (Motion capture) GUDO Studio Nukomeet MedVC Graphworks Service Models Lab(IT)aaS Cloud Laboratories – Lab(IT)aaS Cloud Applications – SaaS Cloud Platforms – PaaS Living Labs Innovation Hosted Databases, Operating Servers, Network Buildings, Labs applications, dvelopment Systems, Storage, technologies, Physical, Cloud Infrastructures user tools, Infrastructure Virtualization security, Fibers, Data – IaaS applications analytic tools Software firewalls center ROAM project • The orbital angular momentum of light (OAM) is the component of angular momentum of a light beam that is dependent on the field spatial distribution, and not on the polarization. Pictures below present different OAM modes and Ring Core Fiber structure.. ROAM project advances • The main goal of the ROAM project (Revolutionising optical fiber transmission and networking using the Orbital Angular Momentum of light) is to develop OAM (Optical Angular Momentum) integrated devices along with its networking applications. • Integrated OAM devices will enable construction of networking equipment that will use OAM modes for switching and transmission of optical data streams. • OAMs can be regarded as an another degree of freedom in the optical transmission. • OAM require special fiber that support Angular Momentum Modes transmission. ROAM project uses two types of fiber – Ring Core and IPGF. • OAM transmission provides higher transmission capacity and lower power consumprion. ROAM project advances • Currently ROAM project is in its final stages. Several developed solutions are beeing tested in the laboratory and the final configurations will be tested in the field trials conducted by PSNC. At CNIT-LNRF, setups are currently available for o 10 OAM x 16 WDM transmission experiments o 10 OAM x 16 WDM switching experiment ICT Innovation Development: PIONIER-LAB (2018-2023) National Platform for Integration of Research Infrastructures for Innovation Ecosystem (PIONIER-LAB) Innovating Networking Technologies Laboratory Distributed Time and Frequency Laboratory Smart Campus as a Smart City Laboratory Regional Living Laboratories of ICT Cloud Services Laboratory Multiscale Simulations Laboratory The E-training Laboratory The Pre-incubation Services PIONIER-LAB Nodes Innovating Networking Technologies Laboratory • Laboratory with nationwide reach based on dedicated fiber network infrastructure • Ability to provide experimantal virtual networks for the commercial and scientific research – Providing personalized resources and and function sets for the network users and integrating research infrastructure domains (ie. LOFAR/POLFAR) • Virtual networks services for – Optical domains – Packet domain • Access to the services and experiments management platform http://imageworksllc.com/files/social%20net.jpg Distributed Time and Frequency Laboratory 20162015201120122014 Centrum Astronomii UMK w Piwnicach http://imageworksllc.com/files/social%20net.jpg Distributed Time and Frequency Laboratory Access to unique services associated with time and frequency distribution covering whole country. • National, backbone, operational network based on dedicated fiber infrastructure used to maintain synchronization and proper operation of distributed atomic clocks • Regional 1st level T&F repositiries located in: Poznań, Warsaw i Gdańsk • Regional 2nd level T&F repositiries located in Koszalin, Olsztyn, Bydgoszcz, Białystok, Łodź, Puławy, Kielce i Rzeszów) • Regional signal distribution systems (Regional Networks) Partnership in Scientific Research and Digital Industry Research Driven Digital Industry – local and European FoF … Energy Climate CCI Smart Societal … AAL Challenges Agriculture Learning Smart Homes Smart AI and Skills &Cities Software New … IoT HPCC Future Media … Internet PPP Cybersecurity NGI R&D in Advanced Regional markets Key Technologies + eInfrastructure + Innovative companies .
Recommended publications
  • PIONIER – the National Fibre Optic Network for New Generation Services
    PIONIER – the national fibre optic network for new generation services Artur Binczewski, Maciej Stroiński Poznań Supercomputing and Networking Center e-IRG Workshop October 12 - 13, 2011; Poznań, Poland 18th years of Polish e-Infrastructure for Science • 1993 – starting academic MANs based on own fibers (FDDI) • 1995 – MANs’ transition to ATM • 1997 – POL-34, 155, 622 • 1999 – joining to TEN-155 (precursor of GÉANT) network • 2000 – PIONIER take-of • 2001 – dark fiber deployment & 1st EU funded project: ATRIUM • 2003 – 10GE • 2004 – multi-lambda • 2006 – PIONIER2 strategy • 2008 – PLATON project • 2009 – NEWMAN project • 2011 – 100NET project National Research and Education Network - PIONIER (topology) • Area 312k sq km • Population 38M • Main academic centers 21 • State universities 165+ • Researchers & Students 2M+ • R&D institutions and Univ. interconnected via PIONIER network 700+ 6494 km of fiber infrastructure in Poland 763 km of fiber in Germany (IRU) 7257 km of fiber in total 21 MANs and 5 HPC Centers in PIONIER Consortium with PSNC as Operator National Research and Education Network - PIONIER (3Q2011) RUSSIA (Kaliningrad) 1 x 10 Gb/s GDAŃSK LITHUANIA 1 x 10 Gb/s Elbląg Suwałki KOSZALIN OLSZTYN SZCZECIN BIELARUS 1 x 10 Gb/s BYDGOSZCZ BIAŁYSTOK Gorzów TORUŃ Hamburg (GLIF, Surfnet, Nordunet) 4x10 Gb/s POZNAŃ Sochaczew GÉANT2 10+10 Gb/s WARSZAWA ZIELONA GÓRA ŁÓDŹ PUŁAWY LUBLIN RADOM WROCŁAW CZĘSTOCHOWA KIELCE 2 x 10 Gb/s (2 lambdas) OPOLE Zamość CBDF 10Gb/s KATOWICE UKRAINE 1x10 Gb/s Colorless, directionless and contentionless Bielsko-Biała
    [Show full text]
  • The Polish Road to Optical Networks
    The Polish Road to Optical Networks Artur Binczewski, Maciej Stroiński artur | [email protected] Pisa, 10-12.05.2005 National programs of development IT infrastructure for academic community • State Committee of Scientific Research created the national program of development IT infrastructure in 1992-2000: 421 Metropolitan Area Networks 45 High Performance Computing Centers 4National Network (NASK, POL-34/155/622) 4LANs and campus networks in research institutions 4Resource servers and databases in MANs POZMAN – Poznan Metropolitan Area Network • Own fiber network (under 220 km) • 105 connections to research institutions • Simple migration to new technologies • 1992 - FDDI • 1995 - ATM • 2000 - Gigabit Ethernet • 2005 - 10 Gigabit Ethernet POZMAN Metropolitan Area Network 1Gb M10 ps 1G bps PSNC M10 Resources Network 10 G Juniper T320 bp s s p BD6808 Catalyst 6509 b PIONIER G 10 Catalyst 6503 Catalyst 6503 Catalyst 6506 Catalyst 6503 10GigabitEthernet Layer 2 Catalyst 6503 Catalyst 6503 Catalyst 6503 Core Network Catalyst 6503 1Gbps 1Gbps 1Gbps 1Gbps AT-8024GB 1GbpsAT-8326GB 1Gbps 1Gbps AT-8024GB AT-8326GB AT-8024GB Access Layer HPC centers in Poland PSNC: SGI Origin3800 (MIPS R12k/160), Cray SV1/8, Cluster PC (IA-64/250), SunFire 6800 (UltraSPARCIII/48), SGI Onyx2 (MIPS R16k/8, Infinity Reality Engine), SGI Altix ACK Cyfronet: SGI Origin2000 (MIPS R14k/128), HP Integrity Superdome (IA-64/8), SunFire 6800 (UltraSPARCIII/20), Cluster PC (Intel PentiumIII, Xeon/80), Cluster PC (IA-64/40). TASK: Cluster PC (IA-64/256), Cluster PC (IA-32/Xeon/128). ICM: Cray SV1ex (32), SGI Origin2000 (MIPS R14k/16), SUN E10K (UltraSPARC/16) WCSS: SGI Origin2400 (MIPS R14k/32), Cluster PC (Xeon/58).
    [Show full text]
  • KMD, PL-GRID PLATON Grid Infrastructure
    IntegrationIntegration ofof nationalnational andand EuropeanEuropean ee--InfrastructureInfrastructure Norbert Meyer On behalf of PIONIER Consortium Grids and e-Science workshop June 17th, 2009, Santander 15th years of Polish e‐Infrastructure for Science • 1993 –starting academic MANs (FDDI) • 1995 – MANs’ transition to ATM • 1997 – POL‐34, 155, 622 • 2000 –PIONIER take‐of • 2001 – dark fiber deployment • 2003 – 10GE • 2004 –multi‐lambda • 2006 – PIONIER2 strategy • 2008 – PLATON, PL‐GRID 21 ACADEMIC METROPOLITAN AREA NETWORKS • Area 320k sq km • Population 38M • Main academic centers 21 • State universities 120+ • Students 2M+ • R&D institutions and Univ. interconnected via PIONIER network 700+ MAN MAN & HPC Center What PIONIER is all about • developing country wide optical infrastructure based on the academic community ownership model • setting up national optical networks interconnecting on separate AS: 21 MANs, 5 HPCCs • extending optical reach to expensive and uniq national labs • grid technology as a main tool to integrate distributed R&D resources • portal as a main service delivery platform • broadband IP based services development • international co‐operation enabling and stimulating This was not that obvious in 1999, as is today… How PIONIER is organized: • PIONIER is a consortium of 22 academic MANs and HPCCs • PIONIER is supervised by PIONIER Board consisting of 22 representatives • PIONIER is managed by PIONIER Executive consisting of 4 people • PIONIER network is financed from the member fee • member fee is based on the cost
    [Show full text]
  • PIONIER-Research and Education Networking in Poland
    PIONIER - Research and Education Networking in Poland Bartosz Belter, Poznan Supercomputing and Networking Center, Poland SEAIP2014, December 2014, Tainan, Taiwan Poznan Supercomputing and Networking Center Center of e-Infrastructure • National Research and Education Network PIONIER • Research Metropolitan Area Network - POZMAN • HPC Center • Data repositories and Digital Libraries Federation Center for R & D • New Generation Networks • HPC, Grids & Clouds • Grand challenge applications • New media and visualization technologies • Knowledge Platforms • Future Internet - Technology, Applications and Services for IS • Cyber Security PIONIER in a nutshell The PIONIER Consortium: 21 MANs and 5 HPC Centers (PSNC as the operator) • Area 312k sq km • Population 38M • Main academic centers 21 • State universities 165+ • Students 2M+ • R&D institutions and Univ. interconnected via PIONIER network 700+ 6479 km of fiber infrastructure in Poland 2359 km of fiber in Europe (IRU) 8838Source km of- http fiber://www.glif.is/publications/maps in total PIONIER: international collaboration GÉANT GLIF PIONIER EU PIONIER @GLIF PIONIER network infrastructure Regional Networks PIONIER National Infrastructure NEWMAN project • Nation scale deployment of MPLS/IP platform for all MANs and PIONIER – Last mile is provided for most of users – Full portoflio of offered services: IPV4, IPv6, MPLS, VPLS, multicasts, QoS,… • New generation DWDM with automatic restoration (GMPLS) – 100G ready – Colorless, Directionless and Contentionless functions implemented – All nodes
    [Show full text]
  • PIONIER Services
    and then things speeded up… • 1993 – starting academic MANs (FDDI) • 1995 – MANs’ transition to ATM • 1997 – POL-34, 155, 622 • 2000 – PIONIER take-of • 2003 – 1 lambda - 10GE • 2004 – multi-lambda 21 ACADEMIC METROPOLITAN AREA NETWORKS • Population 38M • Main academic centers 21 • State universities 120+ • Students 2M+ • R&D institutions and Univ. interconnected via PIONIER network 700+ MAN MAN & HPC Center What PIONIER is all about • closing the gap to EC academic communities an more… • developing country wide optical infrastructure based on the academic community ownership model • setting up national optical networks interconnecting on separate lambdas: 21 MANs, 5 HPCCs and to-do-research network • extending optical reach to expensive national laboratories • grid technology as a main tool to integrate distributed R&D resources • portal as a main service delivery platform • broadband IP based services development • international co-operation enabling and stimulating This was not that obvious in 1999, as is today… How PIONIER is organized: • PIONIER is a consortium of 22 academic MANs and HPCCs • PIONIER is supervised by PIONIER Board consisting of 22 representatives • PIONIER is managed by PIONIER Executive consisting of 4 people • PIONIER network is financed from the member fee • member fee is based on the cost sharing model • each year PIONIER Board take a decision about the framework and parameters of a cost sharing model • one member is selected to play the role of the PIONIER network operator (PSNC) PIONIER dark fiber topology Operational
    [Show full text]
  • Optical Fiber Communications in Poland
    More light in Polish optical fibres Ryszard S. Romaniuk [email protected] Institute of Electronic Systems, Warsaw University of Technology ABSTRACT Optical communications infrastructure is undergoing an intense development in his country now. A number of international investors and domestic operators are building from the beginning, modernizing or developing proprietary network or leasing wide area systems on a large scale. The aggregate level of these processes is of the order of bil. $. Despite of this the network is not homogeneous, has not satisfactory bandwidth, lacks the QoS, has inadequate international connections, and (according to prevailing opinions) the prices are too high for corporate as well as private users. The intense development of the optical infrastructure is governed by two dominant tendencies: burying new large, fat, optical pipes – cables containing even as much fibers as 500 (for C, L and XL optical bands) and investments in DWDM for main traffic directions (previously working in 1300 nm band). Keywords: Optical fibre technology, optical fibers, optical communications, optoelectronics, Internet 1. INTRODUCTION The economic crisis of the last decade has touched also certain sectors of the communication field, in particular cable carriers, and to a lesser degree wireless and mobile carriers. This enforces strong consolidation activities in the global scale. The telecom market is segmented and re-grouped. Big operators aim frequently at new investments in such conditions. These processes can be observed on domestic telecom market in this country. The last years are a period of very intense investments in optical fibre communications infrastructure in this country, especially in backbone networks. Several operators carry out the investments: Telia, Energis, TPSA, Netia, Telbank, Tel-Energo, Railway-Telecom and others.
    [Show full text]
  • Prezentacja Programu Powerpoint
    Poland - e-Infrastructure ecosystem and relation to EOSC Norbert Meyer [email protected] in co-operation with Ministry of Science and Higher Education Polish research infrastructure stakeholders ✓ Owners of the infrastructure ✓ MAN institutions + HPC centres ✓ Service providers ✓ MAN + HPC and universities ✓ Users ✓ Universities, R&D institutions, Polish Academy of Science institutes ✓ Digital libraries, hospitals ✓ Founders ✓ Ministry of Science and Higher Education ✓ Ministry of Regional Development, Marshals of the regions ✓ Inkind contribution of MAN and HPC centres Partners: PIONIER consortium – easier together ! 1. Institute of Bioorganic Chemistry of the Polish Academy of Science – Poznań Supercomputing and Networking Center 2. University of Technology and Life Sciences in Bydgoszcz 3. AGH University of Science and Technology – Academic Computer Centre CYFRONET 4. Institute of Soil Science and Plant Cultivation – State Research Institute 5. Maria Curie – Skłodowska University in Lublin LUBMAN UMCS 6. Bialystok University of Technology 7. Czestochowa University of Technology 8. Gdansk University of Technology Academic Computer Centre TASK 9. Koszalin University of Technology 10. Technical University of Lodz 11. Technical University of Radom 12. Rzeszow University of Technology 13. West Pomeranian University of Technology Szczecin 14. Silesian University of Technology – Computer Centre 15. Kielce University of Technology 16. Wrocław University of Technology 17. Nicolaus Copernicus University 18. Opole University 19. University of
    [Show full text]
  • POLFAR Consortium Activities
    Current POLFAR Consortium Activities Andrzej Krankowski Leszek Blaszkiewicz Chair of POLFARO Consortium Space Radio-Diagnostics Research Centre (SRRC/UWM), University of Warmia and Mazury in Olsztyn, Poland BALTICS SCIENTIFIC CONFERENCE Latvia, Jūrmala, 5 December 2018 POLFARO August, 2015 University of Warmia and Mazury in Olsztyn, the leader of the POLFARO Consortium - (coordinator: prof. Andrzej Krankowski) Jagiellonian University, Krakow - (dr hab. Marian Soida, prof. UJ) Space Research Centre of PAS, Warsaw - (dr hab. Hanna Rothkaehl, prof. CBK) PCSS/PIONIER- (Robert Pekal) ż Nicolaus Copernicus Astronomical Center of PAS in Warsaw, Torun (dr hab. Jarosław Dyks, prof. CAMK) The Nicolaus Copernicus University in Torun (NCU) (dr hab. Magdalena Kunert-Bajraszewska) Szczecin University (dr hab. Ewa Szuszkiewicz, prof.US) University of Zielona Góra (dr hab. Jarosław Kijak, prof.UZ) Wrocław University of Environmental and Life Sciences (prof. Bernard Kontny) LOFAR- The Key Science Projects Epoch of Reionisation Surveys Transients ż Cosmic Rays Magnetism Sun, Space Weather Baldy, Borowiec, Lazy LOFAR stations ż POLFARO PIONIER GLIF GÉANT POLFARO PIONIER EU /PL Pulsars • Big help from the GLOW (D. Schwarz and Bielefeld group mainly) (We are using GLOW observational and raw data reduction tools and them well known software like DPSR and PSARCHIVE) ż • Close cooperation with Zielona Góra pulsar’s team POLFARO Sun and scintillations • Big help in observations initiating and support in solar LOFAR research from Richard Fallows (ASTRON), Derek McKay (Sodankyla Geophysical Observatory and STFC Rutherford Appleton Laboratory, Didcot, UK) and Gottfried Mann (Leibniz-Institut fur Astrophysik Potsdam) from KSP team. ż • Close cooperation on data analysis with University of Wroclaw solar team (prof.
    [Show full text]
  • PIONIER Organizational Model of E-Infrastructure for Research and New Services Development
    PIONIER Organizational model of e-infrastructure for research and new services development Robert Pękal [email protected] . 20th years of Polish e-Infrastructure for Science • 1993 – starting academic MANs based on own fibers (FDDI) • 1995 – MANs’ transition to ATM • 1997 – POL-34, 155, 622 • 1999 – joining to TEN-155 (precursor of GÉANT) network • 2000 – PIONIER take-of • 2001 – dark fiber deployment & 1st EU funded project: ATRIUM • 2003 – 10GE • 2004 – multi-lambda • 2006 – PIONIER2 strategy • 2008 – PLATON project • 2009 – NEWMAN project • 2011 – 100NET project • 2013 – CBPIO project Polish e-Infrastructure • 21 Academic Optical Based MAN (Metropolitean Area Network) • 5 HPC (High Performance Computing) Centers • Connected with owned fiber infrastructure – PIONIER network (Polish Optical Internet) • Science Services Platform - PLATON • Digital Libraries Federation • National Data Storage European & Polish Models of e-Infrastructure European Model Polish Model Responsible Intitutions MAN activity • Local dark fibre investment and ownership • Delivering IP based & VPN services • Cost sharing (recovery) model for academic community • Testbeds in new technologies • Taking part in Regional Development Plan setup • R&D regional IT infrastructure development coordination Every academic MAN: • Is acting under the umbrella of the legal entity of university or R&D institution • Is obliged to service regional academic community • Has a legal permission to act as IT operator or ISP • Is authorized to apply for Ministry of Science grants to develop new services • Is co-operating closely with local community • Is a member of the Polish national PIONIER Consortium Example of MAN – POZMAN 220 km of own Fiber Optic Cables in the city of Poznań • 600k city population • 105 connections to R&D institutions & Univ.
    [Show full text]
  • PDF Presentation
    TELEMEDICINE in POLAND AntoniAntoni NowakowskiNowakowski Department of Biomedical Engineering Gdansk University of Technology Gdańsk, POLAND Ministry of Science and Higher Education Committee of Information Infrastructure CODATA Poland Computer networks in Poland: KASK till 1990 (practically not existing); beginning of TCP/IP - EARN 1991 - CIUW INTERNET - NASK - 1993 (6000 hosts in Poland) HPCC - 1994 CI TASK - http://www.task.gda.pl/ GDANSK ICM - http://www.icm.edu.pl/ WARSZAWA CYFRONET - http://www.cyfronet.krakow.pl/ KRAKOW PCSS - http://rose.man.poznan.pl/ POZNAN WCSS - http://www.wcss.wroc.pl/ WROCLAW 1995 - 2000 - Programme of information infrastructure for science development (full accessibility of any scientist in Poland to the INTERNET & HPC) 2000 - e-Poland programme 2001 - 2005 - PIONIER: Polish Optical Internet - Advanced Applications, Services and Technologies for Information Society 2006 - 2012 - PIONIER 2 Development of MAN in 21 regions II is a property of regional scientific institutions! & since 2000 development of national inter-MAN optical backbone “PIONIER” - as property of MAN consortium NASK - 1998 2003 April POL 34 & MAN - 1998 PIONIERPIONIER • > 5000 km inter-metropolitan fiber-optic network (NZDS G.655 + SM G.652) • System DWDM with lambda (to 40Gb/s) • Optical switches - GMPLS • Optical VPN ¾ Internet ¾ HPC network ¾ administration network ¾ dedicated virtual networks for specific projects as ATLAS, VLBI Gdańsk Słupsk Elbląg Koszalin Olsztyn s / b M Bydgoszcz Białystok Szczecin 4 3 Toruń /s b M 5 5 1 Poznań
    [Show full text]
  • The New Challenges for PIONIER Infrastructure Artur Binczewski
    The New Challenges for PIONIER Infrastructure 10th CEF Networks Workshop 2019 Artur Binczewski Network Technology Division Director EU Policies for e-Infrastructures for research in IT area STRESSES the importance of PRACE, a world-class European High Performance Computing (HPC) infrastructure for research that provides access to computing resources and services for large-scale scientific and engineering applications; ACKNOWLEDGES the need to develop the new generation of HPC technologies and CALLS for the reinforcement of the interconnected network of data processing facilities GEANT. In this respect, INVITES ESFRI to explore MechanisMs for better coordination of MeMber States’ investMent strategies in e-infrastructures, covering also HPC, distributed coMputing, scientific data and networks; http://data.consilium.europa.eu/doc/document/ST-9360-2015-INIT/en/pdf The European Strategy ForuM on Research Infrastructures – Report 2018 http://roadmap2018.esfri.eu/media/1066/esfri-roadmap-2018.pdf Future visions: HPC Europe & EOSC but it is subject for another presentation Source: https://ec.europa.eu/newsroom/dae/document.cfm?doc_id=60156 https://publications.europa.eu/en/publication-detail/-/publication/78ae5276-ae8e-11e9-9d01-01aa75ed71a1/language-en Direction: national strategies and e-infrastructure initiatives: Polish RoadMap of Research Infrastructure (PRRI) • Launched in 2009 • Updated in 2013 • The current PRRI contains 53 project proposals in many broadly understood fields of science: • physical and mathematical sciences - 14, • technical
    [Show full text]
  • Why Is Ipv6 Deployment Important for the Internet Evolution?
    Paper Why is IPv6 Deployment Important for the Internet Evolution? Jordi Mongay Batallaa, Artur Binczewskib, Wojciech Burakowskic, Krzysztof Chudzikd, Bartosz Gajdab, Mariusz Gajewskia, Adam Grzechd, Piotr Krawiecc, Jan Kwiatkowskid, Tomasz Mrugalskie, Krzysztof Nowickie, Wiktor Procykb, Konrad Sienkiewicza, Robert Szumanb, Jarosław Śliwińskic, Jacek Światowiake, Piotr Wiśniewskic, Józef Woźniake a National Institute of Telecommunications, Warsaw, Poland b Poznań Supercomputing and Networking Center, Poznań, Poland c Institute of Telecommunications, Warsaw University of Technology, Warsaw, Poland d Institute of Informatics, Wrocław University of Technology, Wrocław, Poland e Faculty of Electronics, Telecommunications and Informatics, Gdańsk Univeristy of Technology, Gdańsk, Poland Abstract—Replacing the IPv4 protocol with IPv6 on the Inter- pool will be exhausted before 2013. Methods: polynomial net is currently one of the aims of the European Union policy. and exponential estimate the depletion of addresses during The main reason for this replacement is the effeteness of the the year 2012. Regardless of the method of research, the addresses pool in the IPv4 protocol, which can cause serious prospect of exhaustion of IPv4 addresses is so close that complications in the evolution of the Internet and its adapta- the urgent implementation of IPv6 has become a necessity. tion in new areas, e.g., in next generation mobile telephony or the so called Internet of Things. Simultaneously, the address- ing capabilities of the IPv6 protocol are practically unlimited and its new functionalities increase the attractiveness of its usage. The article discusses the problems connected with the IPv6 deployment on the Internet. Especially, the rules for re- alization of the IPv6 deployment and rules for cooperation of IPv4 with IPv6 (including cooperation tests) in network in- frastructure and in applications are presented.
    [Show full text]