A high-performance VLSI array reconfiguration scheme based on network flow under row and column rerouting

Abstract

The reconfiguration algorithms have been extensively investigated to ensure the reliability and stability for the processor arrays with faults. It is important to reduce the power consumption, capacitance and communication costs in the processors by reducing the interconnection length of the VLSI array. This paper discusses the reconfiguration problem of the high-performance VLSI processor array under the row and column rerouting constraints. A novel method, making use the idea of network flow, is proposed in this paper. Firstly, a network flow model of the VLSI processor array is constructed, such that the high-performance VLSI target array can be obtained by utilizing the minimal cost flow algorithm. Secondly, we propose a new strategy for bottleneck row selection in the logical array using the minimum cut technique, which can find a more suitable bottleneck row. Finally, we conducted reliable experiments to clearly reveal the efficiency of the new rerouting scheme and algorithm in reducing the number of long interconnects. The experimental results show that, for a host array with size of 256×256, the number of long interconnects in the subarray can be reduced by up to 79.22% and 55.88% without performance penalty for random faults with density of 1% and 25% respectively, when compared with state-of-the-art. In addition, the proposed scheme improves existing algorithm in terms of subarray size. On a 256×256 host array with 25% faulty density, the average improvement in subarray size is up to 3.77% compared with state-of-the-art.