Developing and Analyzing the Defect-Based Surface Codes Using Optimization Algorithms

Developing and Analyzing the Defect-Based Surface Codes Using Optimization Algorithms

Fault tolerance is crucial for enabling large-scale quantum computations, with surface codes emerging as prominent error correction techniques due to their high error threshold and reliance on nearest-neighbor interactions. Despite the advantages of surface codes, they demand a substantial number of...

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Bibliographic Details
Main Authors: Samira Sayedsalehi, Nader Bagherzadeh, Alberto A. Del Barrio, Guillermo Botella, Ratko Pilipović
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Quantum Reports
Subjects:
genetic algorithms
logical error rates
logical qubits
quantum computing
quantum error correction
simulated annealing
Online Access:https://www.mdpi.com/2624-960X/7/2/25
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Summary:Fault tolerance is crucial for enabling large-scale quantum computations, with surface codes emerging as prominent error correction techniques due to their high error threshold and reliance on nearest-neighbor interactions. Despite the advantages of surface codes, they demand a substantial number of qubits to encode a single logical qubit, making them resource-intensive. Two primary approaches exist to encode multiple logical qubits: patch-based and defect-based. This study focuses on the latter approach, which involves creating holes in the surface code for logical qubit encoding. With the defect-based approach, we need to account for trade-offs between the number of logical qubits and the logical error rates, so we employ an optimization algorithm to evaluate the maximum number of logical qubits for a given error rate. Through a series of experiments, we assess the limitations of the defect-based approach and investigate the impact of various hole types on logical qubit encoding.
ISSN:2624-960X

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