Reversible Synthesis of Symmetric Functions with a Simple Regular Structure and Easy Testability

Abstract

In this article, we introduce a novel method of synthesizing symmetric Boolean functions with reversible logic gates. In contrast to earlier approaches, the proposed technique deploys a simple, regular, and cascaded structure consisting of an array of Peres and CNOT gates, which results in significant reduction with respect to the quantum cost. However, the number of circuit inputs may increase slightly when such cascades are used. In order to reduce their number, we next propose a postsynthesis optimization phase that allows judicious reuse of circuit lines. In addition to offering a cost-effective synthesis methodology, the proposed reversible logic structure supports elegant testability properties. With respect to all single or partial missing gate faults (SMGFs and PMGFs), or repeated gate faults (RGFs) in such an n -input circuit module, we show that it admits a universal test set of constant cardinality (=3) for any value of n . Thus, considering both the cost and testability issues, this approach provides a superior option for synthesizing symmetric functions compared to existing designs.