Related papers: Coherent errors in stabilizer codes caused by quasistatic phase damping

Coherent errors in stabilizer codes caused by quasistatic phase damping

URL: http://arxiv.org/abs/2401.04530v3
Date: Thu, 18 Jul 2024 07:09:57 GMT
Title: Coherent errors in stabilizer codes caused by quasistatic phase damping
Authors: Dávid Pataki, Áron Márton, János K. Asbóth, András Pályi,
Abstract summary: We introduce quasistatic phase damping, a more subtle error model which describes the effect of Larmor frequency fluctuations due to 1/f noise. We provide numerical evidence for an error threshold, in the presence of quasistatic phase damping and readout errors. We discuss the implications of our results for spin qubits and superconducting qubits.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Quantum error correction is a key challenge for the development of practical quantum computers, a direction in which significant experimental progress has been made in recent years. In solid-state qubits, one of the leading information loss mechanisms is dephasing, usually modelled by phase flip errors. Here, we introduce quasistatic phase damping, a more subtle error model which describes the effect of Larmor frequency fluctuations due to 1/f noise. We show how this model is different from a simple phase flip error model, in terms of multi-cycle error correction. Considering the surface code, we provide numerical evidence for an error threshold, in the presence of quasistatic phase damping and readout errors. We discuss the implications of our results for spin qubits and superconducting qubits.

Related papers

Perturbative stability and error correction thresholds of quantum codes [0.029541734875307393]
Topologically-ordered phases are stable to local perturbations, and topological quantum error-correcting codes enjoy thresholds to local errors. We construct classical statistical mechanics models for decoding general CSS codes and classical linear codes. For CSS codes satisfying the LDPC condition and with a sufficiently large code distance, we prove the existence of a low temperature ordered phase.
arXiv Detail & Related papers (2024-06-22T06:46:41Z)
Error-resilience Phase Transitions in Encoding-Decoding Quantum Circuits [0.0]
We investigate a class of encoding-decoding random circuits subject to local coherent and incoherent errors. We analytically demonstrate the existence of a phase transition from an error-protecting phase to an error-vulnerable phase.
arXiv Detail & Related papers (2023-08-11T18:00:02Z)
Quantum Effects on the Synchronization Dynamics of the Kuramoto Model [62.997667081978825]
We show that quantum fluctuations hinder the emergence of synchronization, albeit not entirely suppressing it. We derive an analytical expression for the critical coupling, highlighting its dependence on the model parameters.
arXiv Detail & Related papers (2023-06-16T16:41:16Z)
Simplest fidelity-estimation method for graph states with depolarizing noise [0.0]
We show that a single measurement is sufficient if the noise can be modeled as the phase-flip error. We also numerically evaluate our simplest method for noise models interpolating between the phase-flip and depolarizing noises.
arXiv Detail & Related papers (2023-04-21T13:46:41Z)
Lattice gauge theory and topological quantum error correction with quantum deviations in the state preparation and error detection [0.0]
We focus on the topological surface code, and study the case when the code suffers from both noise and coherent noise on the multi-qubit entanglement gates. We conclude that this type of unavoidable coherent errors could have a fatal impact on the error correction performance.
arXiv Detail & Related papers (2023-01-30T13:12:41Z)
Quantum error correction with dissipatively stabilized squeezed cat qubits [68.8204255655161]
We propose and analyze the error correction performance of a dissipatively stabilized squeezed cat qubit. We find that for moderate squeezing the bit-flip error rate gets significantly reduced in comparison with the ordinary cat qubit while leaving the phase flip rate unchanged.
arXiv Detail & Related papers (2022-10-24T16:02:20Z)
Measuring NISQ Gate-Based Qubit Stability Using a 1+1 Field Theory and Cycle Benchmarking [50.8020641352841]
We study coherent errors on a quantum hardware platform using a transverse field Ising model Hamiltonian as a sample user application. We identify inter-day and intra-day qubit calibration drift and the impacts of quantum circuit placement on groups of qubits in different physical locations on the processor. This paper also discusses how these measurements can provide a better understanding of these types of errors and how they may improve efforts to validate the accuracy of quantum computations.
arXiv Detail & Related papers (2022-01-08T23:12:55Z)
Performance of teleportation-based error correction circuits for bosonic codes with noisy measurements [58.720142291102135]
We analyze the error-correction capabilities of rotation-symmetric codes using a teleportation-based error-correction circuit. We find that with the currently achievable measurement efficiencies in microwave optics, bosonic rotation codes undergo a substantial decrease in their break-even potential.
arXiv Detail & Related papers (2021-08-02T16:12:13Z)
Fundamental thresholds of realistic quantum error correction circuits from classical spin models [0.0]
We use Monte-Carlo simulations to study the resulting phase diagram of the associated interacting spin model. The presented method provides an avenue to assess the fundamental thresholds of QEC codes and associated readout circuitry, independent of specific decoding strategies.
arXiv Detail & Related papers (2021-04-10T19:26:37Z)
Exponential suppression of bit or phase flip errors with repetitive error correction [56.362599585843085]
State-of-the-art quantum platforms typically have physical error rates near $10-3$. Quantum error correction (QEC) promises to bridge this divide by distributing quantum logical information across many physical qubits. We implement 1D repetition codes embedded in a 2D grid of superconducting qubits which demonstrate exponential suppression of bit or phase-flip errors.
arXiv Detail & Related papers (2021-02-11T17:11:20Z)
Crosstalk Suppression for Fault-tolerant Quantum Error Correction with Trapped Ions [62.997667081978825]
We present a study of crosstalk errors in a quantum-computing architecture based on a single string of ions confined by a radio-frequency trap, and manipulated by individually-addressed laser beams. This type of errors affects spectator qubits that, ideally, should remain unaltered during the application of single- and two-qubit quantum gates addressed at a different set of active qubits. We microscopically model crosstalk errors from first principles and present a detailed study showing the importance of using a coherent vs incoherent error modelling and, moreover, discuss strategies to actively suppress this crosstalk at the gate level.
arXiv Detail & Related papers (2020-12-21T14:20:40Z)

This list is automatically generated from the titles and abstracts of the papers in this site.