Related papers: Error rate reduction of single-qubit gates via noise-aware decomposition into native gates

Error rate reduction of single-qubit gates via noise-aware decomposition into native gates

URL: http://arxiv.org/abs/2104.07038v2
Date: Thu, 5 May 2022 18:52:21 GMT
Title: Error rate reduction of single-qubit gates via noise-aware decomposition into native gates
Authors: Thomas J. Maldonado, Johannes Flick, Stefan Krastanov, Alexey Galda
Abstract summary: knowledge of a qubit's initial quantum state and the standard parameters describing its decoherence can be leveraged to mitigate the noise present during the execution of a single-qubit gate. We demonstrate a reduction of the single-qubit error rate by $38%$, from $1.6 times 10 -3$ to $1.0 times 10 -3$, provided the initial state of the input qubit is known.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: In the current era of Noisy Intermediate-Scale Quantum (NISQ) technology, the practical use of quantum computers remains inhibited by our inability to aptly decouple qubits from their environment to mitigate computational errors. In this work, we introduce an approach by which knowledge of a qubit's initial quantum state and the standard parameters describing its decoherence can be leveraged to mitigate the noise present during the execution of a single-qubit gate. We benchmark our protocol using cloud-based access to IBM quantum processors. On ibmq_rome, we demonstrate a reduction of the single-qubit error rate by $38\%$, from $1.6 \times 10 ^{-3}$ to $1.0 \times 10 ^{-3}$, provided the initial state of the input qubit is known. On ibmq_bogota, we prove that our protocol will never decrease gate fidelity, provided the system's $T_1$ and $T_2$ times have not drifted above $100$ times their assumed values. The protocol can be used to reduce quantum state preparation errors, as well as to improve the fidelity of quantum circuits for which some knowledge of the qubits' intermediate states can be inferred. This work presents a pathway to using information about noise levels and quantum state distributions to significantly reduce error rates associated with quantum gates via optimized decomposition into native gates.

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