Litcius/Paper detail

Millimeter Wave Channel Modeling via Generative Neural Networks

William Xia, Sundeep Rangan, Marco Mezzavilla, Angel Lozano, Giovanni Geraci, Vasilii Semkin, Giuseppe Loianno

202038 citationsDOI

Abstract

Statistical channel models are instrumental to design and evaluate wireless communication systems. In the millimeter wave bands, such models become acutely challenging; they must capture the delay, directions, and path gains, for each link and with high resolution. This paper presents a general modeling methodology based on training generative neural networks from data. The proposed generative model consists of a two-stage structure that first predicts the state of each link (line-of-sight, non-line-of-sight, or outage), and subsequently feeds this state into a conditional variational autoencoder that generates the path losses, delays, and angles of arrival and departure for all its propagation paths. Importantly, minimal prior assumptions are made, enabling the model to capture complex relationships within the data. The methodology is demonstrated for 28GHz air-to-ground channels in an urban environment, with training datasets produced by means of ray tracing.

Topics & Concepts

Computer scienceAutoencoderGenerative modelChannel (broadcasting)Artificial neural networkPath lossPath (computing)Extremely high frequencyNon-line-of-sight propagationGenerative grammarRay tracing (physics)Real-time computingArtificial intelligenceMachine learningWirelessTelecommunicationsComputer networkPhysicsQuantum mechanicsMillimeter-Wave Propagation and ModelingRadio Wave Propagation StudiesUAV Applications and Optimization