Related papers: Segmented Composite Design of Robust Single-Qubit Quantum Gates

Segmented Composite Design of Robust Single-Qubit Quantum Gates

URL: http://arxiv.org/abs/2301.00253v2
Date: Sat, 21 Oct 2023 15:04:06 GMT
Title: Segmented Composite Design of Robust Single-Qubit Quantum Gates
Authors: Ido Kaplan, Muhammad Erew, Yonatan Piasetzky, Moshe Goldstein, Yaron Oz, Haim Suchowski
Abstract summary: We introduce an error mitigation scheme for robust single-qubit unitary gates based on composite segmented design. We show that the 3-segmented composite design for the fundamental single-qubits unitary operations reduces the error by an order of magnitude for a realistic distribution of errors.
Score: 0.9487097819140653
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: Error mitigation schemes and error-correcting codes have been the center of much effort in quantum information processing research over the last few decades. While most of the successful proposed schemes for error mitigation are perturbative in the noise and assume deterministic systematic errors, studies of the problem considering the full noise and errors distribution are still scarce. In this work, we introduce an error mitigation scheme for robust single-qubit unitary gates based on composite segmented design, which accounts for the full distribution of the physical noise and errors in the system. We provide two optimization approaches to construct these robust segmented gates: perturbative and non-perturbative, that addresses all orders of errors. We demonstrate our scheme in the photonics realm for the dual-rail directional couplers realization. We show that the 3-segmented composite design for the fundamental single-qubits unitary operations reduces the error by an order of magnitude for a realistic distribution of errors, and that the two approaches are compatible for small errors. This is shown to significantly reduce the overhead of modern error correction codes. Our methods are rather general and can be applied to other realizations of quantum information processing units.

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