Optimal Multi-RIS Placement: Coverage-Guaranteed Sum Rate Maximization Under Inhomogeneous User Distributions
Abstract
The realization of the full potential of Reconfigurable Intelligent Surfaces (RIS) in a wireless system is tied to their strategic spatial deployment. While existing literature primarily focuses on enabling fairness by maximizing coverage to navigate through obstacles, these approaches often fail to exploit the spatial distribution of user density to maximize throughput. Thus, to enable fairness without loss in throughput, we formulate a novel hierarchical problem that maximizes the expected sum rate of the system while guaranteeing probabilistic coverage with the least possible number of RISs deployed. To solve this multi-layered non-convex problem, firstly, we obtain optimal regions where we can deploy RISs to provide the coverage guarantee by solving a constrained set-cover problem on a visibility graph. Then, the minimum number of RISs we require to satisfy the coverage guarantee is obtained by a greedy minimum partitioning on an intersection hypergraph formed using the optimal regions. Finally, a Bayesian Optimization based approach is used to compute the final optimal RIS placement. Numerical results are provided to show that the proposed framework consistently identifies placements that jointly achieve good coverage and throughput, without impractical system assumptions.
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