Joint hybrid transceiver and reflection matrix design for RIS-aided mmWave MIMO cognitive radio systems
Joint hybrid transceiver and reflection matrix design for RIS-aided mmWave MIMO cognitive radio systems
In this work, a reconfigurable intelligent surface (RIS)-aided millimeter wave (mmWave) multiple-input multipleoutput (MIMO) cognitive radio (CR) downlink operating in the underlay mode is investigated. The cognitive base station (CBS) communicates with multiple secondary users (SUs), each having multiple RF chains in the presence of a primary user (PU). We conceive a joint hybrid transmit precoder (TPC), receiver combiner (RC), and RIS reflection matrix (RM) design, which maximizes the sum spectral efficiency (SE) of the secondary system while maintaining the interference induced at the PU below a specified threshold. To this end, we formulate the sum-SE maximization problem considering the total transmit power (TP), the interference power (IP), and the non-convex unity modulus constraints of the RF TPC, RF RC, and RM. To solve this highly non-convex problem, we propose a twostage hybrid transceiver design in conjunction with a novel block coordinate descent (BCD)-successive Riemannian conjugate gradient (SRCG) algorithm. We initially decompose the RF TPC, RC, and RM optimization problem into a series of subproblems and subsequently design pairs of RF TPC and RC vectors, followed by successively optimizing the elements of the RM using the iterative BCD-SRCG algorithm. Furthermore, based on the effective baseband (BB) channel, the BB TPC and BB RC are designed using the proposed direct singular value decomposition (D-SVD) and projection based SVD (P-SVD) methods. Subsequently, the proportional water-filling solution is proposed for optimizing the power, which maximizes the weighted sum-SE of the system. Finally, simulation results are provided to compare our proposed schemes to several benchmarks and quantify the impact of other parameters on the sum-SE of the system.
Singh, Jitendra
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Srivastava, Suraj
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Yadav, Surya P.
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K. Jagannatham, Aditya
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Hanzo, Lajos
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Singh, Jitendra
a98cf279-387d-412e-b5f8-8f1d623f3607
Srivastava, Suraj
7b40cb6c-7bc6-402c-8751-24346d39002c
Yadav, Surya P.
ff4c121d-2d1b-4e28-b002-cc836639d618
K. Jagannatham, Aditya
aee5dcc4-5537-43b1-8e18-81552dc93534
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Singh, Jitendra, Srivastava, Suraj, Yadav, Surya P., K. Jagannatham, Aditya and Hanzo, Lajos
(2024)
Joint hybrid transceiver and reflection matrix design for RIS-aided mmWave MIMO cognitive radio systems.
IEEE Transactions on Cognitive Communications and Networking.
(In Press)
Abstract
In this work, a reconfigurable intelligent surface (RIS)-aided millimeter wave (mmWave) multiple-input multipleoutput (MIMO) cognitive radio (CR) downlink operating in the underlay mode is investigated. The cognitive base station (CBS) communicates with multiple secondary users (SUs), each having multiple RF chains in the presence of a primary user (PU). We conceive a joint hybrid transmit precoder (TPC), receiver combiner (RC), and RIS reflection matrix (RM) design, which maximizes the sum spectral efficiency (SE) of the secondary system while maintaining the interference induced at the PU below a specified threshold. To this end, we formulate the sum-SE maximization problem considering the total transmit power (TP), the interference power (IP), and the non-convex unity modulus constraints of the RF TPC, RF RC, and RM. To solve this highly non-convex problem, we propose a twostage hybrid transceiver design in conjunction with a novel block coordinate descent (BCD)-successive Riemannian conjugate gradient (SRCG) algorithm. We initially decompose the RF TPC, RC, and RM optimization problem into a series of subproblems and subsequently design pairs of RF TPC and RC vectors, followed by successively optimizing the elements of the RM using the iterative BCD-SRCG algorithm. Furthermore, based on the effective baseband (BB) channel, the BB TPC and BB RC are designed using the proposed direct singular value decomposition (D-SVD) and projection based SVD (P-SVD) methods. Subsequently, the proportional water-filling solution is proposed for optimizing the power, which maximizes the weighted sum-SE of the system. Finally, simulation results are provided to compare our proposed schemes to several benchmarks and quantify the impact of other parameters on the sum-SE of the system.
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Accepted/In Press date: 12 June 2024
Identifiers
Local EPrints ID: 491368
URI: http://eprints.soton.ac.uk/id/eprint/491368
ISSN: 2332-7731
PURE UUID: 143a0789-3a1f-47f3-851d-5df81b5a86be
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Date deposited: 20 Jun 2024 17:06
Last modified: 20 Jul 2024 04:01
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Contributors
Author:
Jitendra Singh
Author:
Suraj Srivastava
Author:
Surya P. Yadav
Author:
Aditya K. Jagannatham
Author:
Lajos Hanzo
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