Sequential decoding of the XYZ$^2$ hexagonal stabilizer code

TL;DR

This paper introduces a sequential decoding scheme for the XYZ$^2$ topological stabilizer code, demonstrating high error thresholds and effective correction of various noise models, advancing quantum error correction techniques.

Contribution

It presents a novel sequential decoding approach for the XYZ$^2$ code, leveraging its concatenated structure to improve error thresholds under different noise conditions.

Findings

Sequential matching decoder achieves 18.3% threshold for depolarizing noise.

Belief-matching decoder reaches 24.1% threshold for phase-biased noise.

Thresholds for measurement errors are 3.4% and 4.3% under different noise models.

Abstract

Quantum error correction requires accurate and efficient decoding to optimally suppress errors in the encoded information. For concatenated codes, where one code is embedded within another, optimal decoding can be achieved using a message-passing algorithm that sends conditional error probabilities from the lower-level code to a higher-level decoder. In this work, we study the XYZ$^2$ topological stabilizer code, defined on a honeycomb lattice, and use the fact that it can be viewed as a concatenation of a [[2, 1, 1]] phase-flip parity check code and the surface code with $YZZY$ stabilizers, to decode the syndrome information in two steps. We use this sequential decoding scheme to correct errors on data qubits, as well as measurement errors, under various biased error models using both a maximum-likelihood decoder (MLD) and more efficient matching-based decoders. For depolarizing noise we find that the sequential matching decoder gives a threshold of 18.3%, close to optimal, as a consequence of a favorable, effectively biased, error model on the upper-level YZZY code. For phase-biased noise on data qubits, at a bias $\eta = \frac{p_z}{p_x+p_y} = 10$, we find that a belief-matching-based decoder reaches thresholds of 24.1%, compared to 28.6% for the MLD. With measurement errors the thresholds are reduced to 3.4% and 4.3%, for depolarizing and biased noise respectively, using the belief-matching decoder. This demonstrates that the XYZ$^2$ code has thresholds that are competitive with other codes tailored to biased noise. The results also showcase two approaches to taking advantage of concatenated codes: 1) tailoring the upper-level code to the effective noise profile of the decoded lower-level code, and 2) making use of an upper-level decoder that can utilize the local information from the lower-level code.