Self-timed, minimum latency circuits for the internet of things

This work presents a design flow for asynchronous, self-timed dual-rail circuits which introduces a timing assumption in the return-to-spacer phase. The design flow enables power proportionality and is demonstrated through the design of a 32-bit ripple-carry adder and a 32-bit comparator for internet of things applications. The designs are synthesized to a 65 nm cell library with state-of-the-art transistor sizing for subthreshold. Simulation results show improved performance and energy per computation across operating conditions compared with single-rail equivalents. The design flow allows extension of the power proportional philosophy to a wider range of circuits.