5G European Research towards - Policy, Research and funding opportunities - iracon
←
→
Page content transcription
If your browser does not render page correctly, please read the page content below
European Research towards
5G
Policy, Research and funding opportunities
COST IRACON 2016, Lille
Rémy Bayou European Commission
DG CONNECT "Network Technologies" Unit
You are here
2
5G Action Plan
Injectable connected cancer cell
detection nanosensor
and LOGISTICS
Link to short video car traffic
Increased capacity x1000
New
air
Inter
face
Aggregation Mm-
Shared & wave
Unlicensed MORE
spectrum SPECTRUM
(Hz)
INCREASE
CAPACITY
massive
MORE Small
MORE SPATIAL
MIMO
SPECTRAL EFFICIENCY cells
EFFICIENCY (Bits/Sec/Hz/
(Bits/Sec/Hz) User)Sub 1ms latency
Heterogeneous networks: small cells
Millimeter-wave small cells
Spectrum resources available
worldwide (60 GHz, 71-86 GHz)
Multi-Gbps data rates and
x1000 user density
Low interferences
Beam-steering antenna arrays
High gain : 20-30 dBi Narrow beam : 3-15°
Beam steering over a wide angular sector (azimuth, elevation)
Spatial multiplexing
Hybrid architectures combining analog and digital beamforming
Source: Miwawes project
| 14Quest for Spectrum (mmW) 15-90 Ghz
• 60 GHz bands
• WiGig already operates at these bands
• Target: tens to hundreds of times more capacity
compared to current 4G cellular networks
• 28-30 GHz Bands
• 15-18 GHz Bands
• 42.5-43.5 GHz for TDD systems
• 70 and 80 GHz for FDD (backhaul)Two Unlicensed Contiguous Spectrum
Opportunities
• Exploiting unlicensed spectrum at 100-300 GHz
(still mmWaves !)
• large amount of contiguous spectrum
• suitable for short ranges communications (low atmospheric
attenuation)
• THz with visible light communication empowered
Li-Fi access points
• unlicensed and 10,000 times larger than the range of radio
frequencies between 0 Hz to 30 GHz
• no interference with RF and no interference with sunlight
• VLC enables low complexity and inexpensive wireless
transceivers5G‐PPP leveraging EU Framework Program 7 results
Individual and independent projects
iJOIN iJOIN
METIS 5GNOW Interworking and JOINt Design of
Mobile and wireless 5th Generation Non‐Orthogonal an Open Access and
communications Enablers for Waveforms for Asynchronous Backhaul Network Architecture
Twenty‐twenty (2020) Signalling for Small Cells based on Cloud
Information Society Networks
17
MiWaveS
Tropic Beyond 2020 Heterogeneous
DisTributed computing, storage Wireless Networks with
and radio resource allocation Millimeter‐Wave Small Cell
PHYLAWS
over cooperative femtocells Access and Backhauling PHYsical LAyer Wireless Security
Combo MOTO
COnvergence of fixed and Mobile Evolving MObile internet with
BrOadband innovative terminal‐To‐terminal MCN
access/aggregation networks Offloading technologies Mobile Cloud Networking
Source: 5G Infrastructure Association.Horizon 2020 5G‐PPP
Call 1 selected projects, 129M€, started July 2015
5G Ensure
Security
CogNet SELFNET CHARISMA
Building an Intelligent System of Framework for SELF‐organized network Converged Heterogeneous Advanced
Insights and Action for 5G Network management in virtualized and 5G Cloud‐RAN Architecture for
Management software defined NETworks Intelligent and Secure Media Access
SUPERFLUIDITY VirtuWind
Superfluidity: a 5GEx Virtual and programmable SONATA
super‐fluid, cloud‐ 5G Exchange industrial network prototype Service Programming and
native, converged deployed in operational Wind park Orchestration for Virtualized
edge system Software Networks
COHERENT
Coordinated control and spectrum 5G‐Norma
METIS‐II management for 5G heterogeneous
5G NOvel Radio Multiservice
Mobile and wireless communications radio access networks
Enablers for Twenty‐twenty (2020) adaptive network Architecture
SPEED‐5G
Information Society‐II SESAME
quality of Service Provision and capacity
Expansion through Extended‐DSA for 5G Small cEllS coordinAtion for
Multi‐tenancy and Edge services
FANTASTIC‐5G 5G‐Xhaul
Flexible Air iNTerfAce for Scalable service delivery Flex5Gware Dynamically Reconfigurable Optical‐Wireless
wiThin wIreless Communication networks of the 5th Flexible and Backhaul/Fronthaul with Cognitive Control
Generation efficient Plane for Small Cells and Cloud‐RANs
hardware/softwar
mmMAGIC e platforms for 5G Xhaul
network elements The 5G Integrated fronthaul/backhaul
Millimetre‐Wave Based Mobile Radio Access Network
for Fifth Generation Integrated Communications and devices
EURO‐5G
Quadriga
Coordination & Support
Source: EURO‐5G.H2020 5G PPP Phase 2 and Beyond
Call 2 for 5G Networks:
150 M€, industrial focus
Call for Networking Research Beyond 5G:
18 M€, academic focus
• Novel use of Spectrum, Thz Communications
• Advanced Signal Processing
• Novel Architectures for mobility, alternatives to 5G
Opening: 10 May 2016
Closing: 08 Nov 20165G R&I phase 2: 2017-2019 Focus on Proof of Concepts, Experiments, Verticals Critical technologies and Systems (€100 m) Radio Network and Architectures Optical Core SDN/NFV, architecture, net mgt; Convergent technologies (€45 m) Optical support to access Network apps Research cooperation in access nets (Taiwan) International cooperation (6M€ for 5G with SK and JP); Support Action (€3m)
ICT 7 – 5G PPP Research and Validation of critical technologies and systems a. Research & Innovation 100 M€ a.1. Strand wireless access and radio network architecture/technologies • Novel air interface technologies • Hardware architectures, building blocks • (Radio) Network functional architectures and interfaces leading to a reference architecture for 5G in support of the forthcoming standardisation work • Co‐operative operation of heterogeneous access networks integrating virtual radio functions into service delivery networks • Support of numerous devices with different capabilities, with unified connectivity management capabilities, in terms of security, mobility and routing • Coordination and optimization of user access to heterogeneous radio accesses • Multi‐tenancy for Radio Access Network (RAN) sharing, covering ultra‐dense network deployments • Integration of Satellite Networks
ICT 7 – 5G PPP Research and Validation of critical technologies and systems a. Research & Innovation a.2. Strand High capacity elastic ‐ optical networks Key: core and metro transport capacity/flexibility • New spectrally efficient, adaptive transmission, networking, control and management approaches to increase network capacity by a factor of >100 • To provide high service granularity, guarantees for end‐to‐ end optimization and QoS ‐ reducing power consumption, footprint and cost per bit and maintaining reach • integration of such new optical transport and transmission designs with novel network control and management paradigms (e.g., SDN)
ICT 7 – 5G PPP Research and Validation of critical technologies and systems a. Research & Innovation a.3. Strand Software Networks • Software network architecture to support an access agnostic converged core network and control framework enabling next generation services • A unified management of connectivity, with end to end security mobility and routing for flexible introduction of new services. Multi domain • Solutions (e.g API's and corresponding abstractions) that allow re‐location or anycast search of services and their components • Scalability and efficiency related to increasing deployment of software‐based network equipment and functions as well as corresponding more diverse services and usages • Realisation of the "plug and play vision” for computing, storage and network resources through appropriate abstraction, interfaces, and layering, targeting a Network Operating System (NOS), integration of exp facilities • Management and security for virtualised networks (incl. across multiple virtualised domains) and services to support service deployment decisions
ICT 8 – 5G PPP Convergent Technologies a. Innovation Actions 40 M€ a.1. Strand Ubiquitous 5G access leveraging optical technologies • to develop and assess new optical access network solutions based on integrated optical device prototypes • new optical transmission, switching and information processing techniques to support key access functionalities such as beam forming, high accuracy cm/mmWave generation and massive MIMO deployments • Co‐operative radio‐optical approaches • Techniques to map 5G channels to optical transport and a co‐design of the optical and wireless interfaces and protocols a.2. Strand Flexible network applications • targets development of a multiplicity of Virtualised Network Functions (VNF) for deployment of Network Applications • Targets a Cloud‐like 5G infrastructures, supporting network services, resource and service orchestration • open source development framework for control functionalities and application development, open platforms to third parties
ICT 8 – 5G PPP Convergent Technologies
b. Research and Innovation Actions
5 M€
Cooperation in access convergence
To take advantage of the supporting 5G research and
demonstration facilities offered by Taiwan towards collaborative
5G research with the EU
• Test beds making use of facilities offered by Taiwanese
partners
• Development and demonstration of an integrated convergent
access across different air interface technologies and the
fronthaul/backhaul/core network and capabilities of new
spectrum access schemes
• A system demonstrator showing applications potential is
favoured5G PPP ‐ Public Private Partnership (PPP) research programme • Up to 700 million € public funding • Matched by expected private funding of about 3.5 billion € ‐ Covers policy areas too • Pre standardisation • Spectrum • International cooperation ‐ Implementation through an Industrial Association, 5G‐I‐A ‐ 3 Phases until 2020 => WP 18‐20 includes 5G Long Term research, (consultation Networld2020, academics, 5GPPP..)
ICT 9 Challenges
Networking research beyond 5G
• 5G Networks technologies have an industrial
roadmap. Deployement from 2020
• Research in networks is needed beyond in
time and scope
• Blooming of new ideas and opportunities
• Foster new scientific concepts towards
industrial innovation
• Bring wireless systems to the speed of optical
technologiesScope of networking beyond 5G (1/3) Scientific and technology advances in Spectrum usage • frequencies above 90 Ghz up to Thz for wireless communications and new usages. • Realise visible light communications • Develop radically new approaches for spectrum efficiency.
Scope of networking beyond 5G (2/3)
• Advanced signal processing
• Antenna processing and massive MIMO
• New ideas and optimisation information
theory and coding
• Reach Tbit/s in wireless communicationsScope of networking beyond 5G (3/3)
• Demand-attentive and cooperation
networking
• Alternatives to 5G architectures,
heterogeneous networks
• Opportunistic networks
• Novel architectures and protocols for
routing, latency and caching in complex
networks notably for mobilityExpected Impact • Validation of disruptive communication concepts, technologies and architectures • Proof of applicability of challenging spectrum frequencies towards innovative and cost efficient applications • Advances in signal processing and information theory and scientific publication in world class journals • Industry competitiveness with exploitation of academic research through transfer and innovation towards industry, in particular SMEs or start ups
Type of instrument
• Research & Innovation Actions
• proposals requesting a contribution between EUR
2 and 3 million (indicative)
• Academic focus with Industrial component to
take up research
• Budget: €18 million
• http://ec.europa.eu/research/participants/portal/desktop
/en/opportunities/h2020/topics/5065-ict-09-2017.html
•Find out more
• Horizon2020 web site
• http://ec.europa.eu/programmes/horizon2020
• Participants portal
• http://ec.europa.eu/research/participants/portal
• http://ec.europa.eu/research/participants/portal/desktop/en/oppo
rtunities/h2020/topics/5064‐ict‐07‐2017.html
• http://ec.europa.eu/research/participants/portal/desktop/en/oppo
rtunities/h2020/topics/5062‐ict‐08‐2017.html
• http://ec.europa.eu/research/participants/portal/desktop/en/oppo
rtunities/h2020/topics/5065‐ict‐09‐2017.html
• 5G PPP: http://www.5G‐PPP.euBACK UP SLIDES
You are here
Ongoing activities in RAN
RAN
WS
Channel Modelling above 6 GHz
© 3GPP 2012
Radio Requirements
New RAT Feasibility Study
Sep 2015 Dec 2015 Mar 2016 Jun 2016 Sep 2016 Dec 2016 Mar 2017 Jun 2017
The normative phase on the New RAT will start in Release 15
Approval of the activity (Work Item) expected at March 2017)
© 3GPP 2016 365G Time Frame
You can also read
