CLP-ZNE performs zero-noise extrapolation by averaging over cyclic permutations of circuit layouts, requiring O(n) executions for 1D connectivity and at most O(n^2) for arbitrary connectivity, and reduces errors by an order of magnitude in n=12 qubit benchmarks modeled on IBM Torino hardware.
Exponential error suppression for near- term quantum devices.Phys
2 Pith papers cite this work. Polarity classification is still indexing.
fields
quant-ph 2years
2025 2verdicts
UNVERDICTED 2representative citing papers
H-VEC converts any classical repetition code into a quantum error-correcting protocol by adding one qubit and post-processing to project noise onto correctable Y-errors, yielding exponential suppression under code-capacity noise and quadratic qubit savings in fault-tolerant lattice surgery.
citing papers explorer
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Zero-Noise Extrapolation via Cyclic Permutations of Quantum Circuit Layouts
CLP-ZNE performs zero-noise extrapolation by averaging over cyclic permutations of circuit layouts, requiring O(n) executions for 1D connectivity and at most O(n^2) for arbitrary connectivity, and reduces errors by an order of magnitude in n=12 qubit benchmarks modeled on IBM Torino hardware.
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Correcting quantum errors using a classical code and one additional qubit
H-VEC converts any classical repetition code into a quantum error-correcting protocol by adding one qubit and post-processing to project noise onto correctable Y-errors, yielding exponential suppression under code-capacity noise and quadratic qubit savings in fault-tolerant lattice surgery.