Litcius/Paper detail

Subsystem Codes with High Thresholds by Gauge Fixing and Reduced Qubit Overhead

Oscar Higgott, Nikolas P. Breuckmann

2021Physical Review X45 citationsDOIOpen Access PDF

Abstract

We introduce a technique that uses gauge fixing to significantly improve the quantum-error-correcting performance of subsystem codes. By changing the order in which check operators are measured, valuable additional information can be gained, and we introduce a new method for decoding which uses this information to improve performance. Applied to the subsystem toric code with three-qubit check operators, we increase the threshold under circuit-level depolarizing noise from 0.67% to 0.81%. The threshold increases further under a circuit-level noise model with small finite bias, up to 2.22% for infinite bias. Furthermore, we construct families of finite-rate subsystem low-density parity-check codes with threequbit check operators and optimal-depth parity-check measurement schedules. To the best of our knowledge, these finite-rate subsystem codes outperform all known codes at circuit-level depolarizing error rates as high as 0.2%, where they have a qubit overhead that is 4.3 lower than the most efficient version of the surface code and 5.1 lower than the subsystem toric code. Their threshold and pseudothreshold exceeds 0.42% for circuit-level depolarizing noise, increasing to 2.4% under infinite bias using gauge fixing.

Topics & Concepts

QubitOverhead (engineering)Computer scienceCode (set theory)Decoding methodsNoise (video)Construct (python library)AlgorithmGauge (firearms)Toric codeError detection and correctionTurbo codeTheoretical computer scienceOrder (exchange)Computer engineeringEncoding (memory)PhysicsCarry (investment)Quantum Computing Algorithms and ArchitectureQuantum Information and CryptographyCoding theory and cryptography