An automated predecoder generator for arbitrary qLDPC codes cuts decoder utilization by up to 3963x and supports hardware scaling to tens or hundreds of thousands of logical qubits within power limits.
Decoder switching: Breaking the speed-accuracy tradeoff in real-time quantum error correction
4 Pith papers cite this work. Polarity classification is still indexing.
fields
quant-ph 4years
2026 4verdicts
UNVERDICTED 4representative citing papers
Adaptive window decoding with spatiotemporal complementary gap reduces average buffer size by 40% while maintaining logical error rate in quantum error correction simulations.
Adaptive-window decoding that shrinks or expands based on decoder confidence cuts reaction-time overhead in quantum error correction without raising logical error rates.
Circuit-level simulations show correlated MWPM decoding improves thresholds of bias-tailored compass codes under biased noise, with greater relative gains for asymmetric stabilizers.
citing papers explorer
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Mitigating Classical Resource Costs in Quantum Error Correction via Generalized qLDPC Predecoding
An automated predecoder generator for arbitrary qLDPC codes cuts decoder utilization by up to 3963x and supports hardware scaling to tens or hundreds of thousands of logical qubits within power limits.
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Adaptive Window Decoding based on Spatiotemporal Complementary Gap
Adaptive window decoding with spatiotemporal complementary gap reduces average buffer size by 40% while maintaining logical error rate in quantum error correction simulations.
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ADaPT: Adaptive-window Decoding for Practical fault-Tolerance
Adaptive-window decoding that shrinks or expands based on decoder confidence cuts reaction-time overhead in quantum error correction without raising logical error rates.
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Leveraging Correlated Decoding for Bias-Tailored Compass Codes
Circuit-level simulations show correlated MWPM decoding improves thresholds of bias-tailored compass codes under biased noise, with greater relative gains for asymmetric stabilizers.