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Autori principali: Mamillapalli, Pujitha, Ramamoorthi, Yoghitha, Kumar, Abhinav, Murakami, Tomoki, Ogawa, Tomoaki, Takatori, Yasushi
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2509.03241
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author Mamillapalli, Pujitha
Ramamoorthi, Yoghitha
Kumar, Abhinav
Murakami, Tomoki
Ogawa, Tomoaki
Takatori, Yasushi
author_facet Mamillapalli, Pujitha
Ramamoorthi, Yoghitha
Kumar, Abhinav
Murakami, Tomoki
Ogawa, Tomoaki
Takatori, Yasushi
contents The increasing demand for high data rates and seamless connectivity in wireless systems has sparked significant interest in reconfigurable intelligent surfaces (RIS) and artificial intelligence-based wireless applications. RIS typically comprises passive reflective antenna elements that control the wireless propagation environment by adequately tuning the phase of the reflective elements. The allocation of RIS elements to multipleuser equipment (UEs) is crucial for efficiently utilizing RIS. In this work, we formulate a joint optimization problem that optimizes the RIS phase configuration and resource allocation under an $α$-fair scheduling framework and propose an efficient way of allocating RIS elements. Conventional iterative optimization methods, however, suffer from exponentially increasing computational complexity as the number of RIS elements increases and also complicate the generation of training labels for supervised learning. To overcome these challenges, we propose a five-layer fully connected neural network (FNN) combined with a preprocessing technique to significantly reduce input dimensionality, lower computational complexity, and enhance scalability. The simulation results show that our proposed NN-based solution reduces computational overhead while significantly improving system throughput by 6.8% compared to existing RIS element allocation schemes. Furthermore, the proposed system achieves better performance while reducing computational complexity, making it significantly more scalable than the iterative optimization algorithms.
format Preprint
id arxiv_https___arxiv_org_abs_2509_03241
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Unsupervised Learning based Element Resource Allocation for Reconfigurable Intelligent Surfaces in mmWave Network
Mamillapalli, Pujitha
Ramamoorthi, Yoghitha
Kumar, Abhinav
Murakami, Tomoki
Ogawa, Tomoaki
Takatori, Yasushi
Machine Learning
The increasing demand for high data rates and seamless connectivity in wireless systems has sparked significant interest in reconfigurable intelligent surfaces (RIS) and artificial intelligence-based wireless applications. RIS typically comprises passive reflective antenna elements that control the wireless propagation environment by adequately tuning the phase of the reflective elements. The allocation of RIS elements to multipleuser equipment (UEs) is crucial for efficiently utilizing RIS. In this work, we formulate a joint optimization problem that optimizes the RIS phase configuration and resource allocation under an $α$-fair scheduling framework and propose an efficient way of allocating RIS elements. Conventional iterative optimization methods, however, suffer from exponentially increasing computational complexity as the number of RIS elements increases and also complicate the generation of training labels for supervised learning. To overcome these challenges, we propose a five-layer fully connected neural network (FNN) combined with a preprocessing technique to significantly reduce input dimensionality, lower computational complexity, and enhance scalability. The simulation results show that our proposed NN-based solution reduces computational overhead while significantly improving system throughput by 6.8% compared to existing RIS element allocation schemes. Furthermore, the proposed system achieves better performance while reducing computational complexity, making it significantly more scalable than the iterative optimization algorithms.
title Unsupervised Learning based Element Resource Allocation for Reconfigurable Intelligent Surfaces in mmWave Network
topic Machine Learning
url https://arxiv.org/abs/2509.03241