Randomly Optimized Grid Graph for Low-Latency Interconnection Networks

In this work we present randomly optimized grid graphs that maximize the performance measure, such as diameter and average shortest path length (ASPL), with subject to limited edge length on a grid surface. We also provide theoretical lower bounds of the diameter and the ASPL, which prove optimality of our randomly optimized grid graphs. We further present a diagonal grid layout that significantly reduces the diameter compared to the conventional one under the edge-length limitation. We finally show their applications to three case studies of off-and on-chip interconnection networks. Our design efficiently improves their performance measures, such as end-to-end communication latency, network power consumption, cost, and execution time of parallel benchmarks.