Classical simulations of noisy variational quantum circuits

Enrico Fontana; Manuel S. Rudolph; Ross Duncan; Ivan Rungger; Cristina Cîrstoiu

doi:10.1038/S41534-024-00955-1

Classical simulations of noisy variational quantum circuits

Enrico Fontana^*, Manuel S. Rudolph, Ross Duncan, Ivan Rungger, Cristina Cîrstoiu

^*Corresponding author for this work

Computer And Information Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

Noise detrimentally affects quantum computations so that they not only become less accurate but also easier to simulate classically as systems scale up. We construct a classical simulation algorithm, lowesa (low weight efficient simulation algorithm), for estimating expectation values of noisy parameterised quantum circuits with a fixed observable. It combines previous results on spectral analysis of parameterised circuits with Pauli back-propagation and recent ideas for simulations of noisy random circuits. We show, under some conditions on the circuits and mild assumptions on noise, that lowesa gives an efficient, polynomial algorithm in the number of qubits
(and depth), with approximation error that vanishes exponentially in the physical error rate and a controllable cutoff parameter. This is valid for any expectation value that may be efficiently evaluated on a quantum computer. We discuss the practical limitations of the method for circuit classes with correlated parameters and its scaling with decreasing error rates.

Original language	English
Number of pages	20
Journal	npj Quantum Information
DOIs	https://doi.org/10.1038/S41534-024-00955-1
Publication status	Accepted/In press - 26 Dec 2024

Funding

We acknowledge support from Innovate UK Project No: 10001712. “Noise Analysis and Mitigation for Scalable Quantum Computation”. EF and IR acknowledge the support of the UK government department for Business, Energy and Industrial Strategy through the UK national quantum technologies programme. EF acknowledges the support of an industrial CASE (iCASE) studentship, funded by the UK Engineering and Physical Sciences Research Council (grant EP/T517665/1), in collaboration with the University of Strathclyde, the National Physical Laboratory, and Quantinuum.

Keywords

quantum hardware
classical computing
quantum circuits

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10.1038/S41534-024-00955-1Licence: CC BY 4.0

Cite this

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AU - Fontana, Enrico

AU - Rudolph, Manuel S.

AU - Duncan, Ross

AU - Rungger, Ivan

AU - Cîrstoiu, Cristina

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N2 - Noise detrimentally affects quantum computations so that they not only become less accurate but also easier to simulate classically as systems scale up. We construct a classical simulation algorithm, lowesa (low weight efficient simulation algorithm), for estimating expectation values of noisy parameterised quantum circuits with a fixed observable. It combines previous results on spectral analysis of parameterised circuits with Pauli back-propagation and recent ideas for simulations of noisy random circuits. We show, under some conditions on the circuits and mild assumptions on noise, that lowesa gives an efficient, polynomial algorithm in the number of qubits(and depth), with approximation error that vanishes exponentially in the physical error rate and a controllable cutoff parameter. This is valid for any expectation value that may be efficiently evaluated on a quantum computer. We discuss the practical limitations of the method for circuit classes with correlated parameters and its scaling with decreasing error rates.

AB - Noise detrimentally affects quantum computations so that they not only become less accurate but also easier to simulate classically as systems scale up. We construct a classical simulation algorithm, lowesa (low weight efficient simulation algorithm), for estimating expectation values of noisy parameterised quantum circuits with a fixed observable. It combines previous results on spectral analysis of parameterised circuits with Pauli back-propagation and recent ideas for simulations of noisy random circuits. We show, under some conditions on the circuits and mild assumptions on noise, that lowesa gives an efficient, polynomial algorithm in the number of qubits(and depth), with approximation error that vanishes exponentially in the physical error rate and a controllable cutoff parameter. This is valid for any expectation value that may be efficiently evaluated on a quantum computer. We discuss the practical limitations of the method for circuit classes with correlated parameters and its scaling with decreasing error rates.

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KW - classical computing

KW - quantum circuits

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Classical simulations of noisy variational quantum circuits

Abstract

Funding

Keywords

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Industrial Case Account - University of Strathclyde 2019 | Fontana, Enrico

Cite this

Classical simulations of noisy variational quantum circuits

Abstract

Funding

Keywords

Access to Document

Other files and links

Embargoed Document

Fingerprint

Projects

Industrial Case Account - University of Strathclyde 2019 | Fontana, Enrico

Cite this