Error mitigation with Clifford quantum-circuit data
ORAL
Abstract
Achieving near-term quantum advantage will require accurate estimation of quantum observables despite significant hardware noise. For this purpose, we propose a novel, scalable error-mitigation method that applies to gate-based quantum computers [1]. The method generates training data {Xinoisy, Xiexact } via quantum circuits composed largely of Clifford gates, which can be efficiently simulated classically, where Xinoisy and Xiexact are noisy and noiseless observables respectively. Fitting a linear ansatz to this data then allows for the prediction of noise-free observables for arbitrary circuits. We analyze the performance of our method versus the number of qubits, circuit depth, and number of non-Clifford gates. We obtain an order-of-magnitude error reduction for a ground-state energy problem on 16 qubits in an IBMQ quantum computer and on a 64-qubit noisy simulator.
[1] P. Czarnik, A. Arrasmith, P. J. Coles, L. Cincio, arXiv:2005.10189.
[1] P. Czarnik, A. Arrasmith, P. J. Coles, L. Cincio, arXiv:2005.10189.
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Presenters
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Piotr Czarnik
Los Alamos National Laboratory
Authors
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Piotr Czarnik
Los Alamos National Laboratory
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Andrew Arrasmith
Los Alamos National Laboratory
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Patrick Coles
Los Alamos National Laboratory
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Lukasz Cincio
Los Alamos National Laboratory, T-Division, Los Alamos National Laboratory