New Age of PIONIER infrastructure
Artur Binczewski, Robert Pękal, Maciej Stroiński PSNC Where are we going?
Source: ICT Research and Innovation in Horizon 2020, Morten Moller, European Commission, 23.05.2013 PIONIER global collaboration
GÉANT GLIF
PIONIER EU PIONIER network infrastructure Regional Networks PIONIER National Infrastructure National Research and Education Network – PIONIER (transmission)
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) POZNAŃ 4x10 Gb/s
Sochaczew GÉANT 30 Gb/s WARSZAWA ZIELONA GÓRA
ŁÓDŹ
PUŁAWY LUBLIN RADOM 2 x 10 Gb/s (2 lambdas) WROCŁAW CZĘSTOCHOWA
CBDF 10Gb/s KIELCE
OPOLE Zamość Colorless, directionless and contentionless 80ch DWDM system KATOWICE UKRAINE 1x10 Gb/s PIONIER network node Bielsko-Biała RZESZÓW KRAKÓW
CESNET; SANET 2x10 Gb/s International Fiber Infrastructure
HAMBURG AMS-IX GLIF
DE-CIX
VIX
CERN 100G migration
MAN Olsztyn MAN MAN Toruń Koszalin
MAN Szczecin Gdańsk HPC KDMGdansk MAN MAN Białystok Zielona Góra
MAN Puławy
MAN Poznań Bydgoszcz HPC Poznan KDM HPC Warsaw MAN Radom
MAN MAN Łódź Lublin
100Gb/s Wrocław HPC KDMWroclaw HPC Krakow MAN N x 100Gb/s Kielce
MAN MAN MAN MAN Często Rzeszów Opole Śląsk chowa 100G migration
HAMBURG AMS-IX GLIF Gda
Poz Waw
DE-CIX Wroc Cra
VIX
CERN 100Gb/s
N x 100Gb/s
planned 100G migration
HPC PSNC NODE HPC HPC 2 resource
MPLS Switch Firewall 100GE/10GE IB/Eth HPC 5 DWDM SDN Switch 100GE SDN Transponders 100GE & 10x10GE LLE Muxponders MPLS Switch Switch Firewall 100GE/10GE SDN SDN 100NET DWDM Coherent ≥ 100G λ
NewMAN DWDM 10G & 100G λ
Existing Existing Juniper MPLS Switch Juniper MPLS Switch with new 100GE card with new 100GE card
MAN 1 MAN 21 Is it enough?
Research infrastructure must be equipted with advanced living labs • Available always and remotely • Provide possibility to make disruptive and repeatable tests • Provide full workflow for users (managing lab infrastructure, users access and experiments) Example of network technology laboratories in PIONIER network • Hardware Design and Prototyping Labolatory • Optical Technology Labolatory • Open Network Hardware Labolatory • Integrated Network Management and Simulation Labolatory • Software Defined Network Labolatory Hardware Design and Prototyping Laboratory HETEROGENOUS INSPECTION SYSTEM • Voiding check capabilities • Cold solder joints discover • Electrical correctness inspection PCB BOARD • Signal analysis in bandwidth of tens of GHz • Multilayered designs • Impedance controlled • Mostly FPGA powered • Gigabit transmission oriented
(10G / 3GSDI etc.)
STENCIL PRINTER
SMT PLACEMENT EQUIPMENT REFLOW OVEN • Robotic SMT machine • Multiple soldering zones • High speed • Conveyor belt PCB transmission • High precision • High quality thermal profiling
Examples of own hardware design
The miniaturized 4k camera The high precision atomic clock signals MUX
FPGA CHIP • Internal IP architecture based on DIGITAL VIDEO INTERFACES proprietary AXI4-like bus • HD-SDI & 3GSDI compatible • Unique design of quad head • Four independent video channels graphics controller • Multiple video modes available • Real time demosaicing and color space conversion
MULTIPLEXER FEATURES VIDEO RAM • integrated DDS for phase and freq • Post acquisition buffer for digital signal adjustment 10MHz clock processing purposes • phase shifting for PPS & 10MHz VIDEO HEADER • Video RAM for 4 independent video • programable delay line • 8 independent LVDS lines controllers • silent switching capability • Source synchronous mode • DDR2 technology @ 400MHz • OCXO oscillator • Up to 8Gbps throughput • Fitted for 8/10mpx sensors • backup clock for no input signal • 4K resolution @ 60fps • ETH statistics and management Optical Technology Laboratory
3 ROADM nodes supporting: – colourless, directionless, contentionless and gridless Interfaces: 10G, HD-SDI/3G, 100G and 400G link Tunnable lasers able to apply different modulation schemas (affecting the size of the signal spectral bandwidth)
Existing measurement tools Additional measurement tools and elements
PSO-200 POLMUX Tunable Broadband Sources light source WDM OSA CD i PMD OTDR IP tester 100G HR OSA
Router tester 10G EDFA/RAMAN Power Tunable Finisar MEMs Optical meter attenuator Polarizators WaveShaper Switch Filters PMD Controller 4000S Fibers Open Network Hardware Laboratory
ONH Laboratory in PSNC contains: – ATCA standard choice (Advanced Telecommunications Computing Architecture) – six chassis each of them equipped with several blades with different network processors (NP) and digital signal processors (DSP) Each ATCA chassis (node) in the ONH Laboratory has: – two switch Ethernet 14 SFP+ blades, – two dual Intel Xeon E5-2600 blade with SAS disk, – dual Cavium Octeon II CN68xx blade together with Cavium Octeon SDK, – dual Broadcom XLP832 module and dual EZchip NP4 blade. Each ATCA chassis is also equipped with Texas Instrument DSP media resource module that provides high density of media processing Nodes have 20 x 1G/10G interfaces for interconnections and seven free slots for future expansion and reconfiguration
Open Network Hardware Laboratory
ATCA node decomposition Integrated Network Management and Simulation Labolatory
TV TV Computer Center
STB STB FTTH Network
CPE CPE
Access Switch FTTH MPLS MPLS Switch Router Router
MPLS Network MPLS MPLS Network MPLS FTTH Router Router Switch
Access MPLS MPLS Switch Router Router CPE CPE FTTH Network Server (OpenStack, STB STB Computing OpenFlow, Resources MGMT…) Domain A Domain B Computer Center
TV TV Integrated Network Management and Simulation Labolatory
Software • IBM Tivoli / HP OpenView – Cloud and infrastructure management system – Network management – Virtualization management – Cloud management – Services management • SteelCentral (OpNET) – Network planning – Network performance simulator – Multi-technology, multi-vendor design – Lifecycle support Software Defined Network Laboratory
Current status • Mininet was used as first-choice for testing of SDN developments in PSNC • A simple testbed using MX80, MX240 and EX9208 was used for demonstrations (shared in time) • The number of SDN related projects increased, sharing the testbed is not possible anymore, it was decided to build a shared, flowspace based testbed • The testbed consists of: – Two Juniper MX80 supporting OpenFlow 1.0 – Flowvisor and servers to accommodate endpoints and controllers Software Defined Network Laboratory
Current status
• We used Floodlight and controller1
controller1
OpenDaylight as a Controller-3
controller Controller-n mgmt • In addition to „traditional flowvisor” we look also at other options for flowvisor slicing/virtualization (flowspace firewall, OVX)
VMA-1 VMB-1 • This simple testbed is VMA-2 Juniper MX 80 Juniper MX 80 VMB-2 VMA-3 VMB-3
integrated with current VMA-n OpenFlow OpenFlow VMB-n national testbed Endpoints Endpoints External External (PL-LAB) connections connections Software Defined Network Laboratory
• A new infrastructure project
received structural funds AGH funding: PL-LAB2020 PP • Joint collaboraiton of PSNC, IITiS 1 Gb/s 1 Gb/s 1 Gb/s NIT and 5 Polish Universities Sieć VPLS • 10 Gb/s interconnectivity PG 10 Gb/s 10 Gb/s betweeen SDN sites in the 10 Gb/s
core IŁ PSN C • Each site equipped with PW wireless and SDN testbeds 10 Gb/s • Deployment: 10 Gb/s Q3/Q4 2015 PWr PŚl
10 Gb/s Software Defined Network Laboratory
Typical SDN Island in PL-LAB2020
Summary
• Infrastructure brigde between East Europe countries and GÉANT, GLIF, CERN and Internet Exchange Points • Achieve synergy in development network and research infrastructures – Openess for public and comercial research sectors – Support to national & Horizon 2020 projects – Efficient use of Strucutral Funds • PIONIER is part of Polish Roadmap of Research Infrastructures – New list of 53 research initiatives – Integration with other research infrastructures – Access to special, dedicated funds – Period 2015-2020