High Capacity Fiber-Connected Wireless MIMO Communication
Licentiate thesis, 2023
There will be more and more users while beyond-5G (B5G) and 6G bring more wireless applications. Current cellular communication networks assign specific serving boundaries for each radio, which becomes a limitation when too many users work with one radio simultaneously. By physically distributing radios. user’s service can be more uniform. Radio-over-fiber is a promising enabling technology for distributed antenna systems.
To have several tens of Gbit/s data rate, we need to apply millimeter-wave (mm-wave) frequency band in radio-over-fiber (RoF). However, mm-wave signals have weak penetration and high propagation loss. Hence, beamforming and/or multiple-input-multiple-output (MIMO) technology become necessary for mm-wave RoF to overcome those drawbacks.
This thesis introduces an automatic distributed MIMO (D-MIMO) testbed with a statistical MIMO capacity analysis for an indoor use case. Raytracing-based simulations also predicts the indoor case to make a comparison. The statistical MIMO capacity analysis shows that D-MIMO has a higher and more uniform capacity than co-located MIMO (C-MIMO) in measurements and simulations.
Next, a mm-wave sigma-delta-over-fiber (SDoF) link architecture is proposed for MIMO applications. In the implementation of this link, a QSFP28 fiber link connects a central unit with a remote radio unit with four bandpass sigma-delta-modulation (BPSDM) bitstreams. The remote radio unit generates four mm-wave signals from four BPSDM signals and feeds a linear array antenna. The measurement characterizes the remote radio head at each stage and concludes that this proposed link can reach 800 Msym/s data rate with -0.5 dBm output bandpower.
Furthermore, the proposed link is demonstrated with digital beamforming and multi-user MIMO (MU-MIMO) functionalities. The digital beamforming function reaches 700 Msym/s with -25 dB error vector magnitude (EVM) results by improving the received bandpower in comparison to (single-input-single-output) SISO results. The MU-MIMO function serves two independent users at 500 Msym/s symbol rate and satisfies 3GPP requirements at 1 m over-the-air distance.
In conclusion, this thesis proves that D-MIMO has a higher and more uniform capacity than C-MIMO by statistical analysis from measurements and simulations. The proposed novel mm-wave SDoF link can pave the way for future D-MIMO applications.
To have several tens of Gbit/s data rate, we need to apply millimeter-wave (mm-wave) frequency band in radio-over-fiber (RoF). However, mm-wave signals have weak penetration and high propagation loss. Hence, beamforming and/or multiple-input-multiple-output (MIMO) technology become necessary for mm-wave RoF to overcome those drawbacks.
This thesis introduces an automatic distributed MIMO (D-MIMO) testbed with a statistical MIMO capacity analysis for an indoor use case. Raytracing-based simulations also predicts the indoor case to make a comparison. The statistical MIMO capacity analysis shows that D-MIMO has a higher and more uniform capacity than co-located MIMO (C-MIMO) in measurements and simulations.
Next, a mm-wave sigma-delta-over-fiber (SDoF) link architecture is proposed for MIMO applications. In the implementation of this link, a QSFP28 fiber link connects a central unit with a remote radio unit with four bandpass sigma-delta-modulation (BPSDM) bitstreams. The remote radio unit generates four mm-wave signals from four BPSDM signals and feeds a linear array antenna. The measurement characterizes the remote radio head at each stage and concludes that this proposed link can reach 800 Msym/s data rate with -0.5 dBm output bandpower.
Furthermore, the proposed link is demonstrated with digital beamforming and multi-user MIMO (MU-MIMO) functionalities. The digital beamforming function reaches 700 Msym/s with -25 dB error vector magnitude (EVM) results by improving the received bandpower in comparison to (single-input-single-output) SISO results. The MU-MIMO function serves two independent users at 500 Msym/s symbol rate and satisfies 3GPP requirements at 1 m over-the-air distance.
In conclusion, this thesis proves that D-MIMO has a higher and more uniform capacity than C-MIMO by statistical analysis from measurements and simulations. The proposed novel mm-wave SDoF link can pave the way for future D-MIMO applications.
central unit
Radio-over-Fiber
millimeter-wave.
multiple-inputmultiple- output
remote radio head
Luftbryggan, MC2, Chalmers
Opponent: Dr. Ulf Gustavsson is a senior specialist in Ericsson Research, Gothenburg, Sweden. Researcher in the research group Communication Systems of E2, CTH, Gothenburg, Sweden.
Author
Husileng Bao
Chalmers, Microtechnology and Nanoscience (MC2), Microwave Electronics
Demonstration of Flexible mmWave Digital Beamforming Transmitter using Sigma-Delta Radio-Over-Fiber Link
2022 52nd European Microwave Conference, EuMC 2022,;(2022)p. 692-695
Paper in proceeding
Comparison of Co-located and Distributed MIMO for Indoor Wireless Communication
IEEE Radio and Wireless Symposium, RWS,;Vol. 2022-January(2022)p. 83-85
Paper in proceeding
Automatic Distributed MIMO Testbed for beyond 5G Communication Experiments
IEEE MTT-S International Microwave Symposium Digest,;Vol. 2021-June(2021)p. 697-700
Paper in proceeding
H. Bao, F. Ponzini, and C. Fager, "Flexible mm-Wave Sigma-Delta-over-Fiber MIMO Link"
MyWave - Efficient Millimetre-Wave Communications for mobile users
European Commission (EC) (EC/H2020/860023), 2019-10-01 -- 2023-09-30.
Areas of Advance
Information and Communication Technology
Infrastructure
Kollberg Laboratory
Driving Forces
Sustainable development
Innovation and entrepreneurship
Subject Categories
Telecommunications
Communication Systems
Signal Processing
Technical report MC2 - Department of Microtechnology and Nanoscience, Chalmers University of Technology: 460
Publisher
Chalmers
Luftbryggan, MC2, Chalmers
Opponent: Dr. Ulf Gustavsson is a senior specialist in Ericsson Research, Gothenburg, Sweden. Researcher in the research group Communication Systems of E2, CTH, Gothenburg, Sweden.