Litcius/Paper detail

Reducing the Depth of Linear Reversible Quantum Circuits

Timothée Goubault de Brugière, Marc Baboulin, Benoît Valiron, Simon Martiel, Cyril Allouche

2021IEEE Transactions on Quantum Engineering35 citationsDOIOpen Access PDF

Abstract

In quantum computing the decoherence time of the qubits determines the computation time available, and this time is very limited when using current hardware. In this article, we minimize the execution time (the depth) for a class of circuits referred to as linear reversible circuits, which has many applications in quantum computing (e.g., stabilizer circuits, “CNOT+T” circuits, etc.). We propose a practical formulation of a divide-and-conquer algorithm that produces quantum circuits that are twice as shallow as those produced by existing algorithms. We improve the theoretical upper bound of the depth in the worst case for some range of qubits. We also propose greedy algorithms based on cost minimization to find more optimal circuits for small or simple operators. Overall, we manage to consistently reduce the total depth of a class of reversible functions, with up to 92% savings in an ancilla-free case and up to 99% when ancillary qubits are available.

Topics & Concepts

Quantum computerElectronic circuitQubitComputer scienceQuantum decoherenceQuantumControlled NOT gateAlgorithmQuantum error correctionQuantum mechanicsPhysicsQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum-Dot Cellular Automata