Machine Learning of Noise-Resilient Quantum Circuits
ORAL · Invited
Abstract
Noise mitigation and reduction will be crucial for obtaining useful answers from near-term quantum computers. We present a general framework based on machine learning for reducing the impact of quantum hardware noise on quantum circuits. Our method, called noise-aware circuit learning (NACL), applies to circuits designed to compute a unitary transformation, prepare a set of quantum states, or estimate an observable of a many-qubit state. Given a task and a device model that captures information about the noise and connectivity of qubits in a device, NACL outputs an optimized circuit to accomplish this task in the presence of noise. It does so by minimizing a task-specific cost function over circuit depths and circuit structures. To demonstrate NACL, we construct circuits resilient to a fine-grained noise model derived from gate set tomography on a superconducting-circuit quantum device, for applications including quantum state overlap, quantum Fourier transform, and W-state preparation.
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Publication: "Machine learning of noise-resilient quantum circuits", L. Cincio, K. Rudinger, M. Sarovar, P. J. Coles, PRX Quantum 2, 010324 (2021)
Presenters
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Lukasz Cincio
Los Alamos National Laboratory
Authors
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Lukasz Cincio
Los Alamos National Laboratory