Towards Context Information-based High-Performing Connectivity in Internet of Vehicle Communications
Doctoral thesis, 2022
In order to mitigate the channel aging issue, i.e., the CSI becomes inaccurate soon at high speeds, the first part of the thesis focuses on one way to increase the prediction horizon of CSI in MRs: predictor antennas (PAs). A PA system is designed as a system with two sets of antennas on the roof of a vehicle, where the PAs positioned at the front of the vehicle are used to predict the CSI observed by the receive antennas (RAs) that are aligned behind the PAs. In PA systems, however, the benefit is affected by a variety of factors. For example, 1) spatial mismatch between the point where the PA estimates the channel and the point where the RA reaches several time slots later, 2) antenna utilization efficiency of the PA, 3) temporal evolution, and 4) estimation error of the PA-base station (BS) channel.
First, in Paper A, we study the PA system in the presence of the spatial mismatch problem, and propose an analytical channel model which is used for rate adaptation. In paper B, we propose different approximation schemes for the analytical investigation of PA systems, and study the effect of different parameters on the network performance. Then, involving PAs into data transmission, Paper C and Paper D analyze the outage- and the delay-limited performance of PA systems using hybrid automatic repeat request (HARQ), respectively. As we show in the analytical and the simulation results in Papers C-D, the combination of PA and HARQ protocols makes it possible to improve spectral efficiency and adapt the transmission parameters to mitigate the effect of spatial mismatch. Finally, a review of PA studies in the literature, the challenges and potentials of PA as well as some to-be-solved issues are presented in Paper E.
The second part of the thesis focuses on using advanced technologies to further improve the MR/IoV performance. In Paper F, a cooperative PA scheme in IoV networks is proposed to mitigate both the channel aging effect and blockage sensitivity in millimeter-wave channels by collaborative vehicles and BS handover. Then, in Paper G, we study the potentials and challenges of dynamic blockage pre-avoidance in IoV networks.
temporal correlation
relay
Internet-of-vehicles (IoV)
reconfigurable intelligent surface
throughput
wireless backhaul
outage probability
channel state information (CSI)
5G/B5G
spatial correlation
rate adaptation
mobile relay
6G
vehicle-to-everything (V2X)
Marcum Q-function
integrated access and backhaul (IAB)
predictor antenna
blockage
millimeter wave
Author
Hao Guo
Chalmers, Electrical Engineering, Communication, Antennas and Optical Networks
Rate Adaptation in Predictor Antenna Systems
IEEE Wireless Communications Letters,;Vol. 9(2020)p. 448-451
Journal article
A Semi-Linear Approximation of the First-Order Marcum Q-function with Application to Predictor Antenna Systems
IEEE Open Journal of the Communications Society,;Vol. 2(2021)p. 273-286
Journal article
Power Allocation in HARQ-based Predictor Antenna Systems
IEEE Wireless Communications Letters,;Vol. 9(2020)p. 2025-2029
Journal article
On Delay-limited Average Rate of HARQ-based Predictor Antenna Systems
IEEE Wireless Communications Letters,;Vol. 10(2021)p. 1628-1632
Journal article
Predictor Antenna: A Technique to Boost the Performance of Moving Relays
IEEE Communications Magazine,;Vol. 59(2021)p. 80-86
Journal article
High-Rate Uninterrupted Internet of Vehicle Communications in Highways: Dynamic Blockage Avoidance and CSIT Acquisition
IEEE Communications Magazine,;Vol. 60(2022)p. 44-50
Journal article
H. Guo, B. Makki, M. Åström, M.-S. Alouini, and T. Svensson, “Dynamic blockage pre-avoidance using reconfigurable intelligent surfaces,” submitted to IEEE Communications Magazine, Jan. 2022.
Imagine you are sitting in a high-speed train and using your mobile phone for checking messages or watching online streams. Although you already paid for 4G or even 5G services, the signal becomes weak now and then, especially when the train goes through caves and forests. You look out of the window, and the radio base station (BS) comes and goes. You can't stop but wonder: Can the data speed of my phone match the speed of the train?
Yes, of course! As one type of wireless communication service, internet-of-vehicles (IoV) communications becomes more and more important in our daily life. Serving in-vehicle users is one of the application scenarios in IoV networks. With the recent development of communication technologies, the radio signals become more and more robust in various IoV applications. However, there is still room for improvements especially when 1) the vehicle is moving quickly; 2) the environment changes fast; and 3) many users need to be served. Deploying moving relays (MRs) on the top of vehicles to enhance the signal propagation from the radio BS has great potential to mitigate these challenges.
This thesis focuses on how to improve the performance of MRs using the information from the environment. For example, what does the environment look like? Are there any big blockages between the MR and the BS? Can we ask another MR to help us with radio transmissions? In this work, we develop various communication schemes to establish efficient, low-latency, and highly reliable IoV radio links. Compared to benchmark methods, our setups provide order-of-magnitude performance gains with reasonable deployment costs. Our work has great potential to be (partly) involved in future communication standards and eventually, makes our life slightly better.
Areas of Advance
Information and Communication Technology
Subject Categories
Telecommunications
Communication Systems
Signal Processing
ISBN
978-91-7905-615-5
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5081
Publisher
Chalmers