Wireless communication systems play a pivotal role in modern society, yet they face significant challenges such as latency and multipath fading. Reconfigurable intelligent surface (RIS) is emerged as a promising solution to manipulate electromagnetic waves to enhance transmission quality, although their optimization presents several limitations. In this study, we propose a hybrid approach utilizing the quantum approximate optimization algorithm (QAOA) to effectively configure RIS in multipath environments, addressing the shortcomings of classical methods. The computational model trained by the Sherrington- Kirkpatrick Hamiltonian, demonstrates high accuracy in identifying optimal RIS configurations across various scenarios, without running optimization at each condition. However, the analysis of barren plateaus reveals that the cost function gradient diminishes exponentially as the number of cells increases, making hard the training for large-scale systems. To mitigate these issues, we conclude by suggesting some potential strategies for future research aimed at enhancing RIS performance in practical applications.
Quantum Algorithms for Reconfigurable Intelligent Surface Optimization: Barren Plateaus Analysis / Colella, Emanuel; Bastianelli, Luca; Primiani, Valter Mariani; Moglie, Franco; Gradoni, Gabriele. - ELETTRONICO. - (2025). ( 19th European Conference on Antennas and Propagation, EuCAP 2025 Stockholm, Sweden 30 March 2025 - 04 April 2025) [10.23919/eucap63536.2025.10999170].
Quantum Algorithms for Reconfigurable Intelligent Surface Optimization: Barren Plateaus Analysis
Colella, Emanuel
Writing – Original Draft Preparation
;Bastianelli, LucaWriting – Review & Editing
;Primiani, Valter MarianiWriting – Review & Editing
;Moglie, FrancoWriting – Review & Editing
;Gradoni, Gabriele
Writing – Review & Editing
2025-01-01
Abstract
Wireless communication systems play a pivotal role in modern society, yet they face significant challenges such as latency and multipath fading. Reconfigurable intelligent surface (RIS) is emerged as a promising solution to manipulate electromagnetic waves to enhance transmission quality, although their optimization presents several limitations. In this study, we propose a hybrid approach utilizing the quantum approximate optimization algorithm (QAOA) to effectively configure RIS in multipath environments, addressing the shortcomings of classical methods. The computational model trained by the Sherrington- Kirkpatrick Hamiltonian, demonstrates high accuracy in identifying optimal RIS configurations across various scenarios, without running optimization at each condition. However, the analysis of barren plateaus reveals that the cost function gradient diminishes exponentially as the number of cells increases, making hard the training for large-scale systems. To mitigate these issues, we conclude by suggesting some potential strategies for future research aimed at enhancing RIS performance in practical applications.| File | Dimensione | Formato | |
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