Energy-Efficient High-Speed dynamic logic-based One-Trit multiplier in CNTFET technology

Abstract

The appeal of portable electronics, embedded systems, and other smart devices has been steadily growing over time. The multi-valued logic (MVL) was primarily introduced to handle the interconnect issues in binary logic. The use of ternary logic reduces the circuit complexity, power consumption in interconnects, and total chip area. The carbon nanotube field-effect transistor (CNTFET) offers some significant features like low leakage power, equal hole and electron mobility, and modulation in threshold voltage by adjusting the diameter of the carbon nanotube (CNT). In this paper, a clocked dynamic and pass transistor logic-based ternary 1-trit multiplier circuit with only 28 transistors has been proposed. The proposed logic avoids the conventional approach of using logic gates, encoder/decoder, and multiplexers, which reduces the total device count to implement the multiplier. The reduced transistor count offers a reduction in power consumption, delay, power-delay-product (PDP), and energy-delay-product (EDP) in comparison to other state-of-the-art designs. Stanford 32-nm CNTFET model file and Synopsis HSPICE simulator have been used to carry out the simulations at a supply of 0.9 V. The proposed circuit shows a 34.16 %, 66.44 %, and 82.80 % reduction in power, PDP, and EDP as compared to the lowest power, delay, and PDP of the designs under consideration. The performance of the multiplier is evaluated under different temperatures, supply voltages, loads, and oxide thickness.