Title :
Variable-width datapath for on-chip network static power reduction
Author :
Michelogiannakis, George ; Shalf, J.
Author_Institution :
Lawrence Berkeley Nat. Lab., Berkeley, CA, USA
Abstract :
With the tight power budgets in modern large-scale chips and the unpredictability of application traffic, on-chip network designers are faced with the dilemma of designing for worst-case traffic loads and incurring high static power overheads, or designing for average traffic and risk degrading performance. This paper proposes adaptive bandwidth networks (ABNs) which divide channels and switches into lanes such that the network provides just the bandwidth necessary in each hop. ABNs also activate virtual channels (VCs) individually and take advantage of drowsy SRAM cells to eliminate false VC activations. In addition, ABNs readily tolerate silicon defects with just the extra cost of detection. For application benchmarks, ABNs reduce total power consumption by up to 45% with comparable performance compared to single-lane power-gated networks, and up to 33% compared to multi-network designs.
Keywords :
SRAM chips; elemental semiconductors; low-power electronics; network-on-chip; silicon; Si; adaptive bandwidth networks; application traffic; average traffic; drowsy SRAM cells; false VC activation elimination; large-scale chips; on-chip network; power budgets; power consumption; risk degrading performance; silicon defects; static power overheads; static power reduction; variable-width datapath; virtual channels; worst-case traffic loads; Bandwidth; Benchmark testing; Clocks; Delays; Logic gates; Ports (Computers); Resource management;
Conference_Titel :
Networks-on-Chip (NoCS), 2014 Eighth IEEE/ACM International Symposium on
Conference_Location :
Ferrara
DOI :
10.1109/NOCS.2014.7008767
