Combining Dynamical Decoupling with Fault-Tolerant Quantum Computation

Abstract

We study how dynamical decoupling (DD) pulse sequences can improve the reliability of quantum computers. We prove upper bounds on the accuracy of DD-protected quantum gates and derive sufficient conditions for DD-protected gates to outperform unprotected gates. Under suitable conditions, fault-tolerant quantum circuits constructed from DD-protected gates can tolerate stronger noise, and have a lower overhead cost, than fault-tolerant circuits constructed from unprotected gates. Our accuracy estimates depend on the dynamics of the bath that couples to the quantum computer, and can be expressed either in terms of the operator norm of the bath's Hamiltonian or in terms of the power spectrum of bath correlations; we explain in particular how the performance of recursively generated concatenated pulse sequences can be analyzed from either viewpoint. Our results apply to Hamiltonian noise models with limited spatial correlations.

Open PDF

Document Details

Document Type
Technical Report
Publication Date
Nov 17, 2009
Accession Number
ADA531446

Entities

People

  • Daniel A. Lidar
  • Hui Khoon Ng
  • John Preskill

Organizations

  • University of Southern California

Tags

Communities of Interest

  • C4I
  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Computations
  • Computer Programs
  • Computers
  • Data Science
  • Decoupling
  • Differential Equations
  • Equations
  • Frequency
  • Information Science
  • Lepidoptera
  • Quantum Circuits
  • Quantum Computers
  • Quantum Computing
  • Quantum Information
  • Quantum Information Science
  • Quantum Memories
  • Sequences

Fields of Study

  • Physics

Readers

  • Computer Programming and Software Development.
  • Inertial Navigation Systems.
  • Quantum spin resonance or Electron Paramagnetic Resonance spectroscopy.

Technology Areas

  • Quantum Computing