Energy-delay efficient asynchronous-logic 16×16-bit pipelined multiplier based on Sense Amplifier-Based Pass Transistor Logic

We describe an asynchronous-logic (async) 16×16-bit pipelined multiplier based on our proposed Sense Amplifier-Based Pass Transistor Logic (SAPTL) with emphases on high energy-delay efficiency. The multiplier is targeted for an async multi-core System-On-Chip (SOC). This attribute is achieved by simplifying and optimizing the NMOS pass transistor stacks and decision-making C-element, therein to reduce the circuit area overheads and transistor switchings in SAPTL. Based on the simulations (@1V, 65nm CMOS process), the async 16×16-bit pipelined multiplier based on our proposed SAPTL approach features, on average, 31% shorter delay, 21% lower energy/operation achieving a total of 46% lower energy-delay product, and 16% lesser number of transistors when compared to the reported SAPTL approaches.

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