Using island-style bi-directional intra-CLB routing in low-power FPGAs

Abstract

Increased clustering in Field Programmable Gate Arrays (FPGAs) has shifted a larger fraction of the overall routing load into the configurable logic blocks (CLBs), reducing usage of the costly global interconnect. However, increases in CLB size introduce additional overheads inside CLBs, which can limit the savings gained by minimizing the global interconnect use, motivating more efficient intra-CLB routing. This paper explores different topologies for the intra-CLB connectivity and identifies how the optimal local-CLB interconnect changes for different FPGA architecture and circuit parameters. This work compares area, delay, and energy for two intra-CLB topologies: multiplexer-based routing and island-style bi-directional routing, similar to the global FPGA interconnect, but used inside the CLB (which we call a mini-FPGA). The mini-FPGA style of local CLB interconnect prove to be favorable for minimum-energy operation, as they can reduce transistor count by as much as 62%, and consume as much as 77.9% less energy. Multipexer-based CLBs have performance benefits by reducing delays by almost 3×. Multiplexer-based CLBs can consume less energy at nominal voltages, but only if additional measures are taken to limit power consumption in the multiplexers. A 130-nm CMOS test chip confirms that simulation results track measured data for mini-FPGA CLBs.