Beyond 2020 Heterogeneous Wireless Networks with Millimeter-Wave Small Cell Access and Backhauling

Beyond 2020 Heterogeneous Wireless Networks with Millimeter-Wave Small Cell Access and Backhauling L. Dussopt, CEA-LETI Nov. 20 th, 2015. Workshop on Millimetre-Wave Technology for High-Speed Broadband Wireless Networks www.miwaves.eu

MiWaveS vision Heterogeneous networks: small cells within macro cells Improve user data rate near the access point Offload data from the macro cell to the small cell Reduce transmit power (terminal and BS) Flexible deployment in dense areas Millimeter-wave small cells Spectrum resources available worldwide (60 GHz, 71-86 GHz) Multi-Gbpsdata ratesand x1000 user density Low interferences MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 2

S&T Objectives Objective 1: mobile access with up to 5 Gbpsdata rate through mmw radios and above 10 Gbps aggregate capacity for backhaul. Backhaul link (50-100m) Access link (10-50m) MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 3

S&T Objectives Objective 1: mobile access with up to 5 Gbpsdata rate through mmw radios and above 10 Gbps aggregate capacity for backhaul. Objective 2: reductionof the overall EMF exposure Reduction of 3G/4G traffic through offloading (WP2) High directivity antennas (WP4) EMF exposure assessment in WP4 MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 4

S&T Objectives Objective 1: mobile access with up to 5 Gbpsdata rate through mmw radios and above 10 Gbps aggregate capacity for backhaul. Objective 2: reduction of the overall EMF exposure Objective 3: reductionof the power consumption per bit transmitted (access and backhaul) (green radio) Offloading to small-cell access points (short range comm.) (WP2) mmwave radios (WP3) Directive antennas (WP4) Smart activation of BS/APs w.r.t. network load (WP2) MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 5

S&T Objectives Objective 1: mobile access with up to 5 Gbpsdata rate through mmw radios and above 10 Gbps aggregate capacity for backhaul. Objective 2: reduction of the overall EMF exposure Objective 3: reductionof the power consumption per bit transmitted (access and backhaul) (green radio) Objective 4: improvement of flexibility, QoS, robustnessfor operator networks Split of data and signaling traffic, priority traffic on the 3G/4G network (WP2) self-organizing network (WP2) mmw directive and short-range access links (WP3, WP4) MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 6

Targeted results Definitionand specificationof an heterogeneous wireless network with mmw access and backhaul. Proof of concept of networking functions and algorithms for mmw access and backhaul (Data routing, antenna beam-steering and beam-forming). Demonstration of the radioand antenna technologies for 60 GHz and E-band communications. EMF exposure assessment of users. Demonstration of an heterogeneous network prototype with mmw backhaul and access links. Contribution to standards, regulation and scientific dissemination. MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 7

Project structure 8 WP7: Dissemination, standardisation, exploitation WP8: Project management MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015

Consortium Coordination: Research institutes Universities Large companies Small-Medium Enterprises MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 9

Use cases and requirements Use cases 1. Massive public events and gatherings 2. Hotspot in shopping malls 3. Urban street-level outdoor mobile access and backhaul 4. Indoor wireless networking and coverage from outdoor 5. Rural detached small-cell zones and villages Requirements High end-user capacity (multi-gbps data rate) and site capacity (>10Gbps aggregated capacity) Ease of small-cell APs installation, configuration and management Interconnection of APs by short backhaul hops, achievable with reasonable antenna sizes, energy consumption and equipment cost To Macro MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 10

Dynamic self-organising network functional description and algorithms Scenarios and requirements for the self-organized heterogeneous network with mmw small cells, integrated backhaul and access link. Overall heterogeneous network design with flexible small cell-macro cell relationships and dedicated mmw multi-hop backhaul network. Radio resource management (RRM) theoretical aspects and algorithms with respect to heterogeneous networks (HetNet) with multi-hop backhaul link. Function description and algorithms for the backhaul link and multi-hop relay, and for the access link. Principles and functions for power consumption optimization MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 11

Antenna beamsteeringand beamforming Access: Practical beamforming and beam tracking algorithms for restricted antenna designs are investigated. Also, beam tracking for mobilityscenario is taken into account. MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 12

Antenna beamsteeringand beamforming Access: Practical beamforming and beam tracking algorithms for restricted antenna designs are investigated. Also, beam tracking for mobilityscenario is taken into account. Backhaul: Beam switching as a potential solution for high throughput point to multipoint transmission; code-book design, channel estimation algorithm MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 13

Antenna beamsteeringand beamforming Access: Practical beamforming and beam tracking algorithms for restricted antenna designs are investigated. Also, beam tracking for mobilityscenario is taken into account. Backhaul: Beam switching as a potential solution for high throughput point to multipoint transmission; code-book design, channel estimation algorithm Backhaul: typical small-cell installation mast movement measurements and analysis. MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 14

Radio and antenna technologies User Terminal: V-band Tx/Rx module (57-66 GHz) LCP multi-layer substrate Single antenna (fixed beam), linear polarization Transceiver flip-chipped on the bottom side Module flip-chipped on the terminal board Interface: baseband I/Q signals, digital controls Interposer (top) Interposer (bottom) Cross section IC Size : 10x10 mm 2 Courtesy CEA-LETI MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 15

Radio and antenna technologies Access point: V-band Tx/Rx phased array Same technology blocks developed for the User Terminal: transceiver chip, antenna elements, multi-layer stack-up Add Tx/Rx switch, power splitter, and active phase-shifter circuits Targeted antenna array: 1x4, 2x4 or 4x4 elements Gain: 12 dbi, 15 dbi or 18 dbi. SPDT PS θ t1 PA SPDT 1 Preliminary layout (19x19 mm 2 ) Radiating elements Phase shifter θ r1 LNA RFFE TX RX SPDT Feeding Network Transceiver SPDT (Tx/Rx) SPDT PS θ tn PA SPDT N Courtesy CEA-LETI θ rn LNA Cross section MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 16

Radio and antenna technologies Access point: V-band Tx/Rx phased array High antenna gain (20-30 dbi) Beamsteering capability over a wide angular sector Spatial multiplexing Hybrid architectures with beam-steering sub-arrays AP Courtesy CEA-LETI MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 17

Radio and antenna technologies Backhauling: V-band and E-band arrays and lenses Low cost dielectric lens and printed focal array (fixed beam) Courtesy STMicroelectronics MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 18

Radio and antenna technologies Backhauling: V-band and E-band arrays and lenses Low cost dielectric lens and printed focal array (fixed beam) Discrete lens antenna array with switched focal array (switched beams) Courtesy VTT & CEA-LETI G a in (d B i) 30 20 10 0-10 -20 Phi = 90 30 27.5 25 22.5 20 17.5 15 12.5-50 0 50 X: 0 Y: 29.31 10 7.5 5-10 -7.5-5 -2.5 0 2.5 5 7.5 10 MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 19

Radio and antenna technologies Backhauling: V-band and E-band arrays and lenses Low cost dielectric lens and printed focal array (fixed beam) Discrete lens antenna array with switched focal array (switched beams) Continuous Transverse Stub antenna (fixed beam) Courtesy Univ. Rennes. MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 20

Demonstrations Base Station Backhaul links Access Point Access links User Equipment E-band V-band V-band KPIs: Max. throughput, Power cons., Beamforming perf., Latency, etc. MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 21

Demonstrations E/V-Band antenna WP4 (UR1, CEA, ST-F, VTT) E/V-Band antenna E/V-Band transceiver WP3 (SIV, CEA, ST-F) E/V-Band transceiver DAC/ADC WP5 (NI, TUD, UNIS) DAC/ADC Tx/RxPHY processing Tx/RxPHY processing BF / RF Ctrl MAC / Link control MAC / Link control BF / RF Ctrl MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 22

Impacting standardisation bodies Workshop on candidate technologies for IMT-2020 New ITU-R recommendation for IMT-2020 IMT Vision for programme IMT for 2020 and beyond Recommendation ITU-R M.[IMT.VISION] Report ITU-R M.[IMT.FUTURE TECHNOLOGY TRENDS] Report ITU-R M.[IMT.ABOVE 6 GHz] Use cases, Algo. Analysis WRC 2015 Perf requirements, eval criteria, methodology of new IMT radio Proposal phase WRC 2018/2019 MiWaves Mulit-Gbit/s mmwave Backhaul and Access Link Algo. Implem., Integration, Demonstrator RF / Ant opt. Measurements Provide basis for Rel 14 work items Global mmwave Spectrum Allocation, Proposals Eval Support Rel 13 study items (SI) First mmwave SI / WI Main mmwave SI / WI Rel 12 (09/2014) Rel 13 (expected H1/2016) Rel 14 (expected end 2017) Rel 15 (expected end 2019) Rel 16 LTE-A / 4G B4G 5G 2013 2014 2015 2016 2017 2018 2019 2020 mmwave Research / Prototyping Phase mmwave Standardization / Product Pre-Development mmwave Field Deployment MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 23

Conclusion MiWaveSis developing key technologies for mm-wave wireless access and backhaul in future 5G heterogeneous mobile networks. Definition and specification of an heterogeneous wireless network with mmwave access and backhaul Networking functions and algorithms (Data routing, antenna beamsteering and beam-forming). Demonstration of radio and antenna technologies in V band and E band EMF exposure assessment of users Contribution to standards, regulation and scientific dissemination MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 24

Thank you for your attention www.miwaves.eu

MiWaveS at a Glance Large scale integrating project (IP), 15 partners Duration: Jan. 2014 Dec. 2016 Project coordinator: Dr. Laurent Dussopt (CEA-LETI, Fr). Project officer: Pertti Jauhiainen(EC). Call: FP7-ICT-2013-11, Objective : ICT-2013.1.1 Future networks Contract: CNECT-ICT-619563 Total cost: 11 349 195 ; EC funding: 7 358 113 Communication: Web: www.miwaves.eu Twitter: https://twitter.com/fp7_miwaves LinkedIn: www.linkedin.com/groups/fp7-miwaves-6694097 MiWaveS mmw 2015 workshop Valencia, Spain 20/11/2015 26