Coherence in logical quantum channels

Iverson, Joseph; Preskill, John

doi:10.1088/1367-2630/ab8e5c

Cited by 45 publications

(36 citation statements)

References 38 publications

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“…This is consistent with coherent displacement causing a substantial amount of coherent gate error, as opposed to the purely stochastic error caused by thermal excitation. As quantum circuits amplify coherent gate error, it is especially damaging to long quantum algorithms that involve many gates [19]. As a result, the balance between coherent displacement and thermal excitation plays a critical role in the design of transport solutions that maximize circuit performance, including the choice of transport speeds.…”

Section: Ms-gate Errormentioning

confidence: 99%

Entangling-gate error from coherently displaced motional modes of trapped ions

Ruzic,

Barrick,

Hunker

et al. 2021

Preprint

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Entangling gates in trapped-ion quantum computing have primarily targeted stationary ions with initial motional distributions that are thermal and close to the ground state. However, future systems will likely incur significant non-thermal excitation due to, e.g., ion transport, longer operational times, and increased spatial extent of the trap array. In this paper, we analyze the impact of such coherent motional excitation on entanglinggate error by performing simulations of Mølmer-Sørenson (MS) gates on a pair of trapped-ion qubits with both thermal and coherent excitation present in a shared motional mode at the start of the gate. We discover that a small amount of coherent displacement dramatically erodes gate performance in the presence of experimental noise, and we demonstrate that applying only limited control over the phase of the displacement can suppress this error. We then use experimental data from transported ions to analyze the impact of coherent displacement on MS-gate error under realistic conditions.

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Section: Ms-gate Errormentioning

confidence: 99%

Entangling-gate error from coherently displaced motional modes of trapped ions

Ruzic,

Barrick,

Hunker

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…But to avoid the decoherence effect in qubits, low temperature is required to sustain the coherence property of qubits. Due to these engineering issues, it took nearly three decades to build a practical quantum computer [1][2][3][4][5]. Recently, Google has been able to simulate quantum chemistry reactions using only 12 hydrogen atoms representing 12 qubits of information in these quantum computers [1,6].…”

Section: Introductionmentioning

confidence: 99%

Chaos and complexity from quantum neural network. A study with diffusion metric in machine learning

Choudhury

Dutta

Ray

2021

J. High Energ. Phys.

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In this work, our prime objective is to study the phenomena of quantum chaos and complexity in the machine learning dynamics of Quantum Neural Network (QNN). A Parameterized Quantum Circuits (PQCs) in the hybrid quantum-classical framework is introduced as a universal function approximator to perform optimization with Stochastic Gradient Descent (SGD). We employ a statistical and differential geometric approach to study the learning theory of QNN. The evolution of parametrized unitary operators is correlated with the trajectory of parameters in the Diffusion metric. We establish the parametrized version of Quantum Complexity and Quantum Chaos in terms of physically relevant quantities, which are not only essential in determining the stability, but also essential in providing a very significant lower bound to the generalization capability of QNN. We explicitly prove that when the system executes limit cycles or oscillations in the phase space, the generalization capability of QNN is maximized. Finally, we have determined the generalization capability bound on the variance of parameters of the QNN in a steady state condition using Cauchy Schwartz Inequality.

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“…Secondly, RB gives average, coarse grained noise characterization that largely ignores the effect of errors that depend on circuit structures. Correlated, context or time dependent noise can have a more detrimental effect on the accumulation of errors in a circuit -features that may persist even when considering quantum error correction codes, that largely have been designed to exponentially suppress noise for specific models [16][17][18]. Therefore, detection and quantification of noise correlations in quantum devices not only impacts NISQ era devices [19] by improving circuit fidelities and error mitigation methods but goes beyond it in providing necessary tools to test physical assumptions of quantum error correction.…”

Section: Introductionmentioning

confidence: 99%

Estimation of correlations and non-separability in quantum channels via unitarity benchmarking

Girling,

Cirstoiu,

Jennings

2021

Preprint

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The ability to transfer coherent quantum information between systems is a fundamental component of quantum technologies and leads to coherent correlations within the global quantum process. However correlation structures in quantum channels are less studied than those in quantum states. Motivated by recent techniques in randomized benchmarking, we develop a range of results for efficient estimation of correlations within a bipartite quantum channel. We introduce sub-unitarity measures that are invariant under local changes of basis, generalize the unitarity of a channel, and allow for the analysis of coherent information exchange within channels. Using these, we show that unitarity is monogamous, and provide a novel information-disturbance relation. We then define a notion of correlated unitarity that quantifies the correlations within a given channel. Crucially, we show that this measure is strictly bounded on the set of separable channels and therefore provides a witness of non-separability. Finally, we describe how such measures for effective noise channels can be efficiently estimated within different randomized benchmarking protocols. We find that the correlated unitarity can be estimated in a SPAM-robust manner for any separable quantum channel, and show that a benchmarking/tomography protocol with mid-circuit resets can reliably witness nonseparability for sufficiently small reset errors. The tools we develop provide information beyond that obtained via simultaneous randomized benchmarking and so could find application in the analysis of cross-talk and coherent errors in quantum devices.

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Coherence in logical quantum channels

Cited by 45 publications

References 38 publications

Entangling-gate error from coherently displaced motional modes of trapped ions

Entangling-gate error from coherently displaced motional modes of trapped ions

Chaos and complexity from quantum neural network. A study with diffusion metric in machine learning

Estimation of correlations and non-separability in quantum channels via unitarity benchmarking

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