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bristol.ac.uk/smart
(Future) Networks Architecture: Thinking out of the Box Prof. Dimitra Simeonidou, Director Smart Internet Lab, Co-Director Digital Futures Institute, University of Bristol
Smart Internet Lab
Smart Internet Lab: Who Are We?
• 200 academic and researchers, and growing…
• Founded by three research groups • Communication Systems & Networks
• https://www.bristol.ac.uk/engineering/research/csn/
• High Performance Networks • https://www.bristol.ac.uk/engineering/research/csn/
• Classical Photonics • http://www.bristol.ac.uk/engineering/research/pho/
• Combined expertise across optical, wireless, IoT and cloud technologies.
• Extensive expertise on hardware, software and co-design
• End-to-end Networking
• Real world deployments and large scale experimentation
http://www.bristol.ac.uk/engineering/research/smart/
Smart Internet Lab
Our “5G” Technical Approach• 5G and B5G is a Networks of Networks
• Integrating heterogeneous technologies (specific focus on fibre and wireless technologies)
• Needs to be future proof (i.e. design to evolve and change and not to be replaced)
• New business opportunities meeting the requirements of large range of use cases and service providers
(enabling verticals, neutral hosting)
5G PPP View on 5G Architecture – (White Paper), https://5g-ppp.eu/white-papers/
Smart Internet Lab
5G testbed West of England Region
July’17-Sept’19 Five Primary Sites• Smart Internet Lab, University of Bristol
• We The Curious, Bristol
• M-Shed Museum, Bristol/SS Great Britain
• The Pump Rooms, Bath
• KCL and Digital Catapult, London
Heterogeneous Networking• 60 GHz and 26 GHz mmWave mesh network from
CCS
• LTE-A and 5GNR Cellular from Nokia
• SDN and network slicing from Zeetta
• MEC and cloud compute via Openstack and Nokia
• End-to-End orchestration through OSM
• Network monitoring tools
• Slice creation and management for use-cases
5G Use-cases• Low latency remote rendering
• Dynamic networking and Slicing
• MEC based video rendering
Smart Internet Lab
5G Smart Innovations
Smart Internet Lab
5G Enabled Use-CasesConsortium
Members
#1 – User Experience
• Attractive use cases that engaged the industry and public
#2 – 5G NR & Mobile Edge Computing
• Integration of MEC and network edge (programmable hardware)
• AI and Image processing at the edge
#3 – Network Slicing & Service Orchestration
• Dynamic network slices enable partitioning, protection and prioritisation of services
• End-to-end service orchestration-multidomain
#4 – Wireless & Fibre Backhaul
• High performance, elastic high bandwidth backhaul
Smart Internet Lab
Roman Baths March’19: Window Back in Time
Smart Internet Lab
Bristol Harbour Festival – July’19, Bristol, UK
Inclusion and public safety
Smart Internet Lab
On-Demand High-Definition 3600 Streaming from 3 Stages
Application Access Network Network SlicingConnectivityEdge Compute
4,000 Users over
48 hours
360° Stream at
100Mbps per user
Edge
Processing
Backhaul
60GHz mmW
3 Slices: Media,
Retail & Safety
Application
783 Concurrent
Users
Smart Internet Lab
Create on-demand ‘network slices’ with guaranteed QoS & full control to
support media applications, CCTV video analytics & Digital Signage
Dynamically re-configure the network on external triggers e.g. emergency
5G Network Slicing for Public Safety
5G Technologies used in Safety Use Case:• 5G Network Slicing
• Providing visitors venues with their own “network slice” to acquire & deliver dedicated content
• On-demand generation of an “first responders’ slice” in case of emergency providing instant
connectivity to compliment existing networks
• mmWave or fibre Backhauling
• 4G/5G Small Cell and Wi-Fi seamless access connectivity
CCTV Video analytics
High Resolution,
Immersive Media
Digital
Signage
CCTV
https://www.bbc.co.uk/news/uk-england-bristol-47800751
Smart Internet Lab
Key Research Contributions/Prototypes
Smart Internet Lab
Infrastructure Control
VSwitch
VSwitch
VSwitch
VSwitch
VSwitch
Network Abstraction
Network Virtualisation
Information Model
SDN Agent
Real time Monitoring-
Monitoring Plane
Ontologies\
Cataloging
AI & ML
Analytics
Dynamic Abstraction
Node Slicing
Bandwidth Slicing
EPSRC TOUCAN
Smart Internet Lab
Synthesizable/Programmable Edge Nodes
EPSRC TOUCAN
Smart Internet Lab
Generic Border-Node Interface
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WiFi
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LTE-A/5G
LiFi
Border
Node
Optical
Interfaces
Multi-Access and Multi-protocol interfaces• Support for multiple access technlologies
• Multi-protocol support (i.e. CPRI, eCPRI, IP, Ethernet, OTN, propriatry …)
• Dynamic, low latency aggregation through advanced packet processing engines at the border node
• Elastic bandwidth allocation: frequency, time dimensions
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EPSRC TOUCAN
Smart Internet Lab
Enhanced Network Edge Functionality
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• Manage KPI trade-offs (latency, throughput, location
accuracy, density…)
• Traffic management• Address local traffic dynamics and network load
• Infrastructure slicing and virtualization:
• Elastic bandwidth allocation
• Programmable packet processing (queuing
virtualization, flow isolation, delay/jitter guarantees)
• Synchronization capabilities (inband)
• Enabler for MEC-assisted cloud operations
• Execution of AI/ML models at the edge
Smart Internet Lab
Control and Virtualization: Focus on Open Source
• NFV platform
• Open Source Mano (OSM)
• Interrogation with Open stack
• OSM monitoring tools deployed and
extended
• ML integration with the orchestration
platform
• SDN control framework
• NetOS SDN controller
• Integration with OSM and physical layer
Smart Internet Lab
Multidomain Resource Brokering: The 5G Exchange
• 5G Exchange:
• ETSI standard based multi-domain orchestrator
• Dynamic network interconnection and Virtual
Network Service deployment across multiple
network domains
• Supports L1/ L2/L3 Network services
• Quantum Secured
• Marketplace of VNFs, Nses
• AI-based inter-domain orchestration
• Smart contracts
• Automatic and on-demand creation, negotiation,
verification and enforcement of agreements tailored
to vertical requirements
Smart Internet Lab
Public Showcase: Orchestrating the Orchestra
• Three Locations:
• Millennium Square in Bristol
• Digital Catapult London (King’s Cross)
• King’s College London (Strand)
• A concert was performed by distributed orchestra:
• Piano, 2 violins & vocals
Violinist in Bristol
Pianist at King’s College London
Violinist & Vocalist at Digital Catapult
Smart Internet Lab
Orchestrating the Orchestra Live Demo, 16 March’19
Smart Internet Lab
The World’s First 5G Music Lesson with Jamie Cullum
• Three Locations:
• Roman Amphitheatre London
• Bristol
• Birmingham
• Three Networks:
• UoB 5GUK Test Network
• KCL 5GUK Test Network
• BT/EE 5G Network
• The lesson was performed
• By Jamie Cullum, London
• To:
Keyboard player, saxophone player & vocalists at Bristol
Drams player and 2 electric guitar players at Birmingham
Smart Internet Lab
ETSI OSM PoC
https://osm.etsi.org/wikipub/index.php/OSM_PoC_7_-_Orchestrating_The_Orchestra
Smart Internet Lab
B5G Network Vision
Smart Internet Lab
• Pervasive (everywhere, all services, all industries/verticals support)
• Multitenancy, multi-ownership, neutral hosting…
• 5D sliceable (lambdas, wireless spectrum, space, time, e2e)
• Monetizable/Tradeable
• Disaggregation of SW and HW functions- full commoditisation of HW
• Moving more functionality to the edge
• Advanced very large scale monitoring (for AI, ML, DL…)
• Programmable
• Automated and Autonomous network management and operations
• Resilient and secure-physical layer security
• Ultra low delay with high reliability
• 100 Gbps connectivity to the end-user
• Geolocation accuracy better than 1 cm
Future Evolution
Smart Internet Lab
• Disaggregated and composable network infrastructure
• Micro-service based composable networking
• Machine learning assisted network service and function composition
• Technology enablers
• Deep network programmability
• Data plane as a micro-service
• ML assisted automation
• Composable via real time monitoring and data analytics
• Key differentiators
• Programmable Hardware & Network HW Function Virtualization
• Quantum secured function chaining
Architecture Principles
Virtual Network
Service
Service Topology
VNFM
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Micro Service
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Micro Service
PNF
VNFM
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Micro Service
M
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Micro Service
PNF
VNFM
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Micro Service
QKD
QKD
QKD QKD
QKD
Smart Internet Lab
• To allow any service to mix-and-match and use compute, storage and
network resources upon request (at atomic level and on-the-fly)
• To support high scale: on demand levels (services, users); devices (IoT,
bodynets, etc.); points and types of technologies of access
• Distributed/decentralised solution focusing at the edge where requests arrive
(access, service, etc.)
• Targeted, customised solutions tailored for local network conditions and dynamics
(temporal and space locality)
• Enable high network dynamics: variable amounts and types of traffic;
devices (IoT, etc.); on-the-fly service composition
Network Disaggregation
Smart Internet Lab
Dynamic QKD Networking
A Natural QKD Network Evolution
Smart Internet Lab
QKD technology - state of the art
• Connected through Trusted Nodes
• Requires key management
• Point-to-point QKD links
• QKD network overlay to classical data-plane
Tokyo QKD network, 2011
Smart Internet Lab
QKD technology - Missing parts of the puzzle
• Develop dynamic QKD networking scenarios
• Overcome physical transmission/switching limitations
• Compatibility with classical optical networks
• Allow co-existence of classical-quantum channels
• World record co-existence 11.2Tbps
• Integrated with the 5G SW stack (SDN-QKD, OSM-QKD)
Smart Internet Lab
Field-Deployed Dynamic QKD Testbed
5GUK
TEST NETWORK NDFF
• 1st logical step
towards true QKD
networking: The first to deploy optical
switches in DVQKD links
• Induced losses limit
power budget
(typically 10dB)
• Increase functionality
CL2A1
CL3BCL2A2 CL2B2
Encryption Server
Encryption Server
CL3ADEMU
X
BVT
MUX
BVT
CL2B1
Encryption Server
OXC
OXCOXC
OXC OXC
DC
DC
SDN Control of
QKD and Classical
Quantum Key
Management
Encryption/Decryption
As a
Virtual Function
High-Speed Programable
Encryption/Decryption
High-Speed Programable
Encryption/Decryption
High-Speed Programable
Encryption/Decryption
High-Speed Programable
Encryption/Decryption
Smart Internet Lab
Q-ROADM: Ultimate QKD switching
• 30
Q1
Q1
Q2
WS
SW
SS
WSS
WS
S
WSS
BYPASS PORT
BYPASS PORT
BYPASS PORT
DROP
PORTSQ CL
DROP
PORTS
QCL
DROP
PORTS
QCL
DROP
PORTS
QCL
q-ROADM
BYPASS PORT
Optical Fibre Switch
EDFA
Multiple EDFA
OFS
Bandwidth Variable TransceiverBVT
WSSWSS Wavelength Selective Switches
Dashed Components are not implemented
Smart Internet Lab
Multidomain VNF migration with QKD-secured channels
VNF11 VNF12 VNF21 VNF22
Inter-island
Optical
Network
Deploy NS
VM11 VM12
NS
Deploy
inter-island
NS?
Deploy inter-
island NS
VM11 VM12VM21 VM22
QKD QKD
Quantum Secured & Optical Network Aware
Multi-Domain NFV Orchestrator
HPN OFC PDP 2019
Smart Internet Lab
Multi-layer Network-Aware & Quantum-Aware Multi-
domain NFV Orchestrator
OFC PDP 2019
Smart Internet Lab
Field-Deployed Dynamic QKD Testbed
Bradley Stoke
NSQI lab
HPN lab
We The Curious
1 Cathedral Sq.
23km
23.7 km
1.9 km
1.2 km
2 km
5GUK
TEST
NETWORK
NDFF
Sustainable co-existence for:
- 4x 100 Gb/s PM-QPSK channels
- Cl- channels unamplified
- Cl- channels close (0.5nm) to Q-channel
- Through switched QKD netwotk
Smart Internet Lab
Beyond Technology
Smart Internet Lab
Beyond Technology Innovation
Smart Internet Lab
• Announced July 2019
• Directors:
• Prof Dimitra Simeonidou (Engineering) & Prof Susan Halford (Sociology)
• Research England RPIF Bid: £29M 27 current partners with plans to grow the
partnership ecosystem
• Co-investment: £71.9M over 5 years
• University of Bristol contribution: 20 academic posts
• To build the UK’s first fully Instrumented facility for sociotechnical research
The Bristol Digital Futures Institute
Smart Internet Lab
Research Ecosystem & Partnership
Smart Internet Lab
• Co-location and co-creations across research teams from Engineering, Computer
Sciences and Social Sciences
• Challenge-driven research targeting:
• Digital technologies and applications
• Major societal challenges
• Transformational business models,
• Bringing technologies into use
• Open Innovation based on two pillars:
• Knowledge co-creation and co-production across academic disciplines in partnerships with
industry and communities;
• Making it real:
• Through experimental research platforms of representative scale driving research and
innovation through experiences
• Through in-depth knowledge and understanding of social contexts and pathways to use
Bristol Digital Futures Institute (BDFI)
Smart Internet Lab
Thank you