Interaction graph-based characterization of quantum benchmarks for improving quantum circuit mapping techniques

• URL: http://arxiv.org/abs/2212.06640v3
• Date: Mon, 8 Jan 2024 20:44:47 GMT
• Title: Interaction graph-based characterization of quantum benchmarks for improving quantum circuit mapping techniques
• Authors: Medina Bandi\'c, Carmen G. Almudever, Sebastian Feld
• Abstract summary: We propose to extend the characterization of quantum circuits by including qubit interaction graph properties. Our study reveals a correlation between interaction graph-based parameters and mapping performance metrics for various existing configurations of quantum devices.
• Score: 1.351147045576948
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: To execute quantum circuits on a quantum processor, they must be modified to meet the physical constraints of the quantum device. This process, called quantum circuit mapping, results in a gate/circuit depth overhead that depends on both the circuit properties and the hardware constraints, being the limited qubit connectivity a crucial restriction. In this paper, we propose to extend the characterization of quantum circuits by including qubit interaction graph properties using graph theory-based metrics in addition to previously used circuit-describing parameters. This approach allows for in-depth analysis and clustering of quantum circuits and a comparison of performance when run on different quantum processors, aiding in developing better mapping techniques. Our study reveals a correlation between interaction graph-based parameters and mapping performance metrics for various existing configurations of quantum devices. We also provide a comprehensive collection of quantum circuits and algorithms for benchmarking future compilation techniques and quantum devices.

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