English

MIRAGE: Quantum Circuit Decomposition and Routing Collaborative Design using Mirror Gates

Quantum Physics 2025-04-22 v3

Abstract

Building efficient large-scale quantum computers is a significant challenge due to limited qubit connectivities and noisy hardware operations. Transpilation is critical to ensure that quantum gates are on physically linked qubits, while minimizing SWAP\texttt{SWAP} gates and simultaneously finding efficient decomposition into native basis gates\textit{basis gates}. The goal of this multifaceted optimization step is typically to minimize circuit depth and to achieve the best possible execution fidelity. In this work, we propose MIRAGE\textit{MIRAGE}, a collaborative design and transpilation approach to minimize SWAP\texttt{SWAP} gates while improving decomposition using mirror gates\textit{mirror gates}. Mirror gates utilize the same underlying physical interactions, but when their outputs are reversed, they realize a different or mirrored\textit{mirrored} quantum operation. Given the recent attention to iSWAP\sqrt{\texttt{iSWAP}} as a powerful basis gate with decomposition advantages over CNOT\texttt{CNOT}, we show how systems that implement the iSWAP\texttt{iSWAP} family of gates can benefit from mirror gates. Further, MIRAGE\textit{MIRAGE} uses mirror gates to reduce routing pressure and reduce true circuit depth instead of just minimizing SWAP\texttt{SWAP}s. We explore the benefits of decomposition for iSWAP\sqrt{\texttt{iSWAP}} and iSWAP4\sqrt[4]{\texttt{iSWAP}} using mirror gates, including both expanding Haar coverage and conducting a detailed fault rate analysis trading off circuit depth against approximate gate decomposition. We also describe a novel greedy approach accepting mirror substitution at different aggression levels within MIRAGE. Finally, for iSWAP\texttt{iSWAP} systems that use square-lattice topologies, MIRAGE\textit{MIRAGE} provides an average of 29.6% reduction in circuit depth by eliminating an average of 59.9f% SWAP\texttt{SWAP} gates, which ultimately improves the practical applicability of our algorithm.

Keywords

Cite

@article{arxiv.2308.03874,
  title  = {MIRAGE: Quantum Circuit Decomposition and Routing Collaborative Design using Mirror Gates},
  author = {Evan McKinney and Michael Hatridge and Alex K. Jones},
  journal= {arXiv preprint arXiv:2308.03874},
  year   = {2025}
}

Comments

13 pages, 13 figures. This paper is under review for the IEEE and/or ACM

R2 v1 2026-06-28T11:50:19.082Z