Accelerated randomized benchmarking

Granade, Christopher; Ferrie, Christopher; Cory, David G.

doi:10.1088/1367-2630/17/1/013042

Cited by 50 publications

(78 citation statements)

References 59 publications

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“…For a = 0.04, the estimated [analytic] survival rates were 0.9977(16) [0.9977] for q f h = = = 0.01, 0.9978(15) [0.9977] for q f h = = = 0.5, 0.01, and 0.9975(6) [0.9974] for q f = = 0.5 and h = 0.2, where the uncertainties are the half-width of the 95% confidence intervals in the fit parameter obtained using Mathematica. For q = 0.12, the estimated [analytic] survival rates were 0.980(15) [0.978] for q f h = = = 0.01, 0.978(16) [0.978] for q f h = = = 0.5, 0.01, and 0.9975(8) [0.977] for q f = = 0.5 and h = 0.2.The fitted value of the coefficient A is consistent with the analytic value of 2/3 although the uncertainty in the estimate of the coefficients is on the order of 0.05, which is typical in RB experiments[21].…”

supporting

confidence: 64%

“…To maximize the variation in leakage rate over states (and consequently over random sequences), we model leakage using the unitary a « X 1 3 defined in equation (21). Coherent leakage can arise either naturally or be a residual effect of imperfectly storing a qubit in the leakage level, a technique used to protect certain states while performing an operation in various implementations, including ion traps [19,20].…”

Section: Numerical Simulationsmentioning

confidence: 99%

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Robust characterization of leakage errors

2016

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Leakage errors arise when the quantum state leaks out of some subspace of interest, for example, the two-level subspace of a multi-level system defining a computational 'qubit', the logical code space of a quantum error-correcting code, or a decoherence-free subspace. Leakage errors pose a distinct challenge to quantum control relative to the more well-studied decoherence errors and can be a limiting factor to achieving fault-tolerant quantum computation. Here we present a scalable and robust randomized benchmarking protocol for quickly estimating the leakage rate due to an arbitrary Markovian noise process on a larger system. We illustrate the reliability of the protocol through numerical simulations.An important error mechanism in many experimental implementations of quantum information is leakage, that is, transitions into and out of the Hilbert space under consideration (e.g., an electron excitation to another energy level). Subsequent transitions back into the Hilbert space introduce a memory effect, making leakage a fundamentally non-Markovian process. Such leakage errors can be a substantial obstacle to fault-tolerant computation [1-3].There are platform-dependent methods for characterizing leakage in many of the leading experimental approaches to quantum computation, such as ion trap qubits [4], superconducting qubits [5, 6] and quantum dots [7]. However, these approaches all have disadvantages such as being platform-dependent, scaling exponentially in the number of qubits, being sensitive to state-preparation and measurement errors (SPAM) or assuming a specific error model.Randomized benchmarking (RB) [8-10] has been specifically developed to avoid all of these pitfalls at the cost of obtaining only partial information-namely, the average gate fidelity-about the errors in the absence of leakage. In the presence of leakage, the standard fidelity decay curve in RB breaks down [11], although the RB protocol can be modified to account for leakage errors [12].We present a protocol that provides an estimate of the average leakage rate for coherent leakage over a given set of quantum gates. We consider computational and leakage spaces of arbitrary dimensions, so that our protocol can be applied to both physical and logical qudit systems. We demonstrate that our protocol produces reliable estimates of leakage rates through numerical simulations of our protocol for specific, adversarial, error models.Note that after the protocol below first appeared online, an alternative heuristic protocol was presented in [13]. While the heuristic protocol applies to specific experimental scenarios, the current protocol is both fully rigorous and expressed in terms of platform-independent experimental capabilities. Defining leakage ratesMany experimental implementations of logical d 1 -level qudits (typically = d 2 1 , giving a qubit) are embedded in a d-level quantum system by taking only the first d 1 levels ñ ¼ ñ | |d 1 , , 1 . Formally, we can consider a OPEN ACCESS RECEIVED

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supporting

confidence: 64%

Section: Numerical Simulationsmentioning

confidence: 99%

Robust characterization of leakage errors

2016

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“…Almost certainly some measurements are more informative than others. We expect that an adaptive testing strategy, in which the current model estimate is used to choose the most informative experiment to perform next, will significantly reduce the cost of QPI [44,45,76].…”

Section: Discussionmentioning

confidence: 99%

Quantum process identification: a method for characterizing non-markovian quantum dynamics

Bennink

Lougovski

2019

New J. Phys.

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Established methods for characterizing quantum information processes do not capture non-Markovian (history-dependent) behaviors that occur in real systems. These methods model a quantum process as a fixed map on the state space of a predefined system of interest. Such a map averages over the system's environment, which may retain some effect of its past interactions with the system and thus have a history-dependent influence on the system. Although the theory of non-Markovian quantum dynamics is currently an active area of research, a systematic characterization method based on a general representation of non-Markovian dynamics has been lacking. In this article we present a systematic method for experimentally characterizing the dynamics of open quantum systems. Our method, which we call quantum process identification (QPI), is based on a general theoretical framework which relates the (non-Markovian) evolution of a system over an extended period of time to a time-local (Markovian) process involving the system and an effective environment. In practical terms, QPI uses time-resolved tomographic measurements of a quantum system to construct a dynamical model with as many dynamical variables as are necessary to reproduce the evolution of the system. Through numerical simulations, we demonstrate that QPI can be used to characterize qubit operations with non-Markovian errors arising from realistic dynamics including control drift, coherent leakage, and coherent interaction with material impurities.

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“…Integrals over the posterior can then be approximated by using these samples, which allows quantities such as Ĥ to be efficiently estimated. SMC has seen use in a range of quantum information tasks, including state estimation [19], frequency and Hamiltonian learning [10], benchmarking quantum operations [27], and in characterizing superconducting device environments [11]. Similar methods have also been applied to quantum error correction [28].…”

Section: Bayesian Characterization and Sequential Monte Carlomentioning

confidence: 99%

Quantum bootstrapping via compressed quantum Hamiltonian learning

2015

Self Cite

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A major problem facing the development of quantum computers or large scale quantum simulators is that general methods for characterizing and controlling are intractable. We provide a new approach to this problem that uses small quantum simulators to efficiently characterize and learn control models for larger devices. Our protocol achieves this by using Bayesian inference in concert with Lieb-Robinson bounds and interactive quantum learning methods to achieve compressed simulations for characterization. We also show that the Lieb-Robinson velocity is epistemic for our protocol, meaning that information propagates at a rate that depends on the uncertainty in the system Hamiltonian. We illustrate the efficiency of our bootstrapping protocol by showing numerically that an 8 qubit Ising model simulator can be used to calibrate and control a 50 qubit Ising simulator while using only about 750 kilobits of experimental data. Finally, we provide upper bounds for the Fisher information that show that the number of experiments needed to characterize a system rapidly diverges as the duration of the experiments used in the characterization shrinks, which motivates the use of methods such as ours that do not require short evolution times. OPEN ACCESS RECEIVED

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Accelerated randomized benchmarking

Cited by 50 publications

References 59 publications

Robust characterization of leakage errors

Robust characterization of leakage errors

Quantum process identification: a method for characterizing non-markovian quantum dynamics

Quantum bootstrapping via compressed quantum Hamiltonian learning

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