English

Towards Demonstrating Fault Tolerance in Small Circuits Using Bacon-Shor Codes

Quantum Physics 2021-08-05 v1

Abstract

Quantum error correction is necessary to perform large-scale quantum computations in the presence of noise and decoherence. As a result, several aspects of quantum error correction have already been explored. These have been primarily studies of quantum memory[1, 2], an important first step towards quantum computation, where the objective is to increase the lifetime of the encoded quantum information. Additionally, several works have explored the implementation of logical gates[3-5]. In this work we study a next step - fault-tolerantly implementing quantum circuits. We choose the [[4,1,2]][[4, 1, 2]] Bacon-Shor subsystem code, which has a particularly simple error-detection circuit. Through both numerics and site-counting arguments, we compute pseudo-thresholds for the Pauli error rate pp in a depolarizing noise model, below which the encoded circuits outperform the unencoded circuits. These pseudo-threshold values are shown to be as high as p=3%p=3\% for short circuits, and p=0.6%p=0.6\% for circuits of moderate depth. Additionally, we see that multiple rounds of stabilizer measurements give an improvement over performing a single round at the end. This provides a concrete suggestion for a small-scale fault-tolerant demonstration of a quantum algorithm that could be accessible with existing hardware.

Keywords

Cite

@article{arxiv.2108.02079,
  title  = {Towards Demonstrating Fault Tolerance in Small Circuits Using Bacon-Shor Codes},
  author = {Ariel Shlosberg and Anthony M. Polloreno and Graeme Smith},
  journal= {arXiv preprint arXiv:2108.02079},
  year   = {2021}
}

Comments

7 pages, 4 figures

R2 v1 2026-06-24T04:49:37.150Z