RIS-Assisted Millimeter Wave Communications for Indoor Scenarios: Modeling and Coverage Analysis

TL;DR

This paper develops an advanced stochastic geometry model for RIS-assisted indoor mmWave networks, incorporating height, boundary, blockage, and user clustering effects to analyze coverage and guide deployment strategies.

Contribution

It introduces a comprehensive indoor mmWave model with RIS, considering key environmental factors and user behavior, providing new analytical tools for network coverage analysis.

Findings

RIS significantly improves coverage with limited transmitters or power.

Coverage is affected by obstacle and RIS densities, and user cluster size.

Simplified CP expressions offer practical deployment insights.

Abstract

Millimeter wave (mmWave) communications and reconfigurable intelligent surfaces (RIS) are two critical technologies for next-generation networks, especially in dense indoor environments. However, existing analyses often oversimplify the indoor environment by neglecting some of the key characteristics, such as height variations, boundary effects, blockage effects, and user spatial distributions. In this paper, we develop an improved stochastic geometry-based model for RIS-assisted mmWave communications in indoor scenarios like conference centers, hospitals, and shopping malls. The proposed model incorporates the height factor for all the nodes in the network (e.g., transmitters, users, RISs, and obstacles) and captures the user clustering behavior in these scenarios. In addition, the boundary effect is also being considered for line-of-sight (LOS) probability calculation. Analytical expressions for distance distributions, LOS probabilities, and the coverage probability (CP) are derived. The CP is then validated through Monte Carlo simulations. Our results reveal deployment insights by approximating and simplifying the derived CP expressions, showing how transmitter density, obstacle density, RIS density, and user cluster radius impact network coverage. Notably, we show that RISs significantly improve coverage when transmitters or transmit power are limited but offer marginal benefits when transmitter density is high. These findings provide practical guidelines for the design and deployment of RIS-assisted indoor mmWave networks.