A novel optimization method for reversible logic circuit minimization

Abstract

Programmable reversible logic is emerging as a prospective logic design style for implementation in modern nanotechnology and quantum computing with minimal impact on circuit heat generation. Recent advances in reversible logic using and quantum computer algorithms allow for improved computer architecture and arithmetic logic unit designs. We present an optimization method for reversible logic synthesis based on the Integrated Qubit (IQ) library. This method works in conjunction with existing methods to further improve quantum cost and delay of a synthesized reversible logic circuit. This algorithm runs in O(N) time, and reduces the quantum cost of synthesized circuit by up to 45 percent. In addition, the process of replacing the gates in the synthesized circuits with IQ gates uses a locally optimal technique whose major benefits include reduction of cost as well as delay.