A new measurement schedule turns the heavy-hex subsystem code into the dynamic compass code, which demonstrates a threshold for stability and supports fault-tolerant lattice surgery.
Title resolution pending
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
fields
quant-ph 3verdicts
UNVERDICTED 3representative citing papers
Dynamic compass code on heavy-hex lattice yields competitive threshold and experimental 38.3% logical error rate improvement for distance-5 via ACES noise characterization and leakage-aware post-selection.
Soft decoding with analog measurement data raises repetition-code thresholds by 25% and reduces error rates up to 30x on superconducting qubits, with one byte per shot sufficient for near-optimal performance.
citing papers explorer
-
Low-valency scalable quantum error correction with a dynamic compass code
A new measurement schedule turns the heavy-hex subsystem code into the dynamic compass code, which demonstrates a threshold for stability and supports fault-tolerant lattice surgery.
-
Scalable quantum error correction tailored for a heavy-hex qubit array
Dynamic compass code on heavy-hex lattice yields competitive threshold and experimental 38.3% logical error rate improvement for distance-5 via ACES noise characterization and leakage-aware post-selection.
-
Soft information decoding with superconducting qubits
Soft decoding with analog measurement data raises repetition-code thresholds by 25% and reduces error rates up to 30x on superconducting qubits, with one byte per shot sufficient for near-optimal performance.