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An affine precoded superimposed pilot based mmWave MIMO-OFDM ISAC system

An affine precoded superimposed pilot based mmWave MIMO-OFDM ISAC system
An affine precoded superimposed pilot based mmWave MIMO-OFDM ISAC system
A new affine-precoded superimposed pilot (AP-SIP) scheme is conceived for both wireless channel and radar target parameter estimation in a millimeter wave (mmWave) multiple-input multipleoutput (MIMO) orthogonal frequency division multiplexing (OFDM)-based integrated sensing and communication (ISAC) systems. The AP-SIP scheme leads to enhanced estimation accuracy and improved utilization of spectral resources. Initially, the pilot-assisted radar (PAR) and data-assisted radar (DAR) parameter estimation models are separately developed for the estimation of the radar target parameters. Subsequently, these are combined into a joint pilot-data radar (JPDR) model for simultaneously harnessing both the signals to further boost the estimation accuracy. The sparse Bayesian learning (BL)-based joint-BL (J-BL) technique is developed for this system that efficiently exploits the sparsity of the radar scattering environment. Next, a group sparse BL (G-BL) technique is also derived that exploits the group sparsity across subcarriers for the estimation of the wireless beamspace channel vector, which outperforms the competing techniques, including conventional sparse BL. The optimal pilot, transmit precoder (TPC) and receive combiner (RC) are determined at the dual-function radar-communication (DFRC) base station (BS) and also at the user equipment (UE) for maximizing the performance attained. The Bayesian Cramer-Rao bounds (BCRB) are explicitly derived to benchmark the performance of the wireless channel and radar
target parameter estimation. Simulation results are provided to demonstrate the improved performance of the proposed schemes considering multiple metrics, such as the normalized mean squared error (NMSE), bit error rate (BER) and achievable spectral efficiency (ASE).
2644-125X
Gupta, Awadhesh
1c1bc688-2dbf-4eec-896e-e73e657a331e
Jafri, Meesam
46e4ee57-9ee8-4e2e-b4a9-6d26d7c796b8
Srivastava, Suraj
7b40cb6c-7bc6-402c-8751-24346d39002c
K. Jagannatham, Aditya
aee5dcc4-5537-43b1-8e18-81552dc93534
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Gupta, Awadhesh
1c1bc688-2dbf-4eec-896e-e73e657a331e
Jafri, Meesam
46e4ee57-9ee8-4e2e-b4a9-6d26d7c796b8
Srivastava, Suraj
7b40cb6c-7bc6-402c-8751-24346d39002c
K. Jagannatham, Aditya
aee5dcc4-5537-43b1-8e18-81552dc93534
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1

Gupta, Awadhesh, Jafri, Meesam, Srivastava, Suraj, K. Jagannatham, Aditya and Hanzo, Lajos (2024) An affine precoded superimposed pilot based mmWave MIMO-OFDM ISAC system. IEEE Open Journal of the Communications Society. (In Press)

Record type: Article

Abstract

A new affine-precoded superimposed pilot (AP-SIP) scheme is conceived for both wireless channel and radar target parameter estimation in a millimeter wave (mmWave) multiple-input multipleoutput (MIMO) orthogonal frequency division multiplexing (OFDM)-based integrated sensing and communication (ISAC) systems. The AP-SIP scheme leads to enhanced estimation accuracy and improved utilization of spectral resources. Initially, the pilot-assisted radar (PAR) and data-assisted radar (DAR) parameter estimation models are separately developed for the estimation of the radar target parameters. Subsequently, these are combined into a joint pilot-data radar (JPDR) model for simultaneously harnessing both the signals to further boost the estimation accuracy. The sparse Bayesian learning (BL)-based joint-BL (J-BL) technique is developed for this system that efficiently exploits the sparsity of the radar scattering environment. Next, a group sparse BL (G-BL) technique is also derived that exploits the group sparsity across subcarriers for the estimation of the wireless beamspace channel vector, which outperforms the competing techniques, including conventional sparse BL. The optimal pilot, transmit precoder (TPC) and receive combiner (RC) are determined at the dual-function radar-communication (DFRC) base station (BS) and also at the user equipment (UE) for maximizing the performance attained. The Bayesian Cramer-Rao bounds (BCRB) are explicitly derived to benchmark the performance of the wireless channel and radar
target parameter estimation. Simulation results are provided to demonstrate the improved performance of the proposed schemes considering multiple metrics, such as the normalized mean squared error (NMSE), bit error rate (BER) and achievable spectral efficiency (ASE).

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Accepted/In Press date: 10 February 2024

Identifiers

Local EPrints ID: 487116
URI: http://eprints.soton.ac.uk/id/eprint/487116
ISSN: 2644-125X
PURE UUID: c4819295-dfb1-4a76-9da8-02b905f01082
ORCID for Lajos Hanzo: ORCID iD orcid.org/0000-0002-2636-5214

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Date deposited: 14 Feb 2024 17:36
Last modified: 18 Mar 2024 02:36

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Contributors

Author: Awadhesh Gupta
Author: Meesam Jafri
Author: Suraj Srivastava
Author: Aditya K. Jagannatham
Author: Lajos Hanzo ORCID iD

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