TRMAC: A Time-Reversal-based MAC Protocol for Wireless Networks within Computing Packages

TL;DR

TRMAC is a novel on-chip wireless MAC protocol that uses Time Reversal to enable multiple parallel transmissions over a shared channel, improving scalability and efficiency in high-core-count systems.

Contribution

This paper introduces TRMAC, a cross-layer MAC protocol leveraging Time Reversal for on-chip wireless communication, eliminating the need for complex resource allocation.

Findings

TRMAC achieves high throughput comparable to multi-channel protocols.

It demonstrates low latency and scalability across hundreds of cores.

Simulation results show effective spatial reuse with a single frequency channel.

Abstract

As chiplet-based integration and many-core architectures become the norm in high-performance computing, on-chip wireless communication has emerged as a compelling alternative to traditional interconnects. However, scalable Medium Access Control (MAC) remains a fundamental challenge, particularly under dense traffic and limited spectral resources. This paper presents TRMAC, a novel cross-layer MAC protocol that exploits the spatial focusing capability of Time Reversal (TR) to enable multiple parallel transmissions over a shared frequency channel. By leveraging the quasi-deterministic nature of on-chip wireless channels, TRMAC pre-characterizes channel impulse responses to coordinate access using energy-based thresholds, eliminating the need for orthogonal resource allocation or centralized arbitration. Through detailed physical-layer simulation and system-level evaluation on diverse traffic, TRMAC demonstrates comparable or superior performance to existing multi-channel MAC protocols, achieving low latency, high throughput, and strong scalability across hundreds of cores. TRMAC provides a low-complexity, high-efficiency solution for future Wireless Networks-on-Chip (WNoCs), particularly in chiplet-based systems where spatial reuse and modularity are critical. With simulations we prove that TRMAC can be utilized for parallel transmissions with a single frequency channel with a similar throughput and latency as in using multiple frequency bands omitting the need for complex transceivers. This work establishes a new design direction for MAC protocols that are tightly integrated with the underlying channel physics to meet the demands of next-generation computing platforms.