A High-Speed Low-Energy One-Trit Ternary Multiplier Circuit Design in CNTFET Technology

Abstract

Contemporary system-on-chip-based applications are battery-powered. To increase the operation time, they need various low-power/energy circuits. Carbon nanotube field-effect transistor (CNTFET) is a potential alternative to complementary metal-oxide-semiconductor for power/energy-efficient circuits implementation due to offering high performance. Another way to reduce power/energy consumption in a circuit is to use multiple-valued logic, especially ternary logic, which has three logical states. This paper presents a novel 1-trit ternary multiplier circuit with 23 transistors based on only unary operators of the ternary logic system and the dual-supply voltages technique. The proposed design does not use the ternary decoder/encoder, logic gates, cascading transmission gates, and ternary multiplexer to reduce the transistors count, delay, power, and energy. The Stanford CNTFET model in the 32 nm technology node is used to simulate the proposed design. The delay, power, and delay-power-product (PDP) of the proposed design at 0.9 V are 0.026 ns, 0.139 μW, and 3.614 aJ, respectively. It offers improvements between 50% and 61.19% in delay and between 52.72% and 59.75% in PDP compared to previously published multiplier circuits, which are based on the dual-supply voltages and use 23 transistors. These improvements make the proposed design a good candidate for the design of the next generation of multiplier circuits in arithmetic blocks.