Protocol learns single-qubit Z-twirled MCM instrument parameters from three repeated measurements on mixed input, yielding ~100x better Pauli-observable prediction than confusion-matrix models on IBM processors.
Characterizing quantum instruments: From nondemolition measurements to quantum error correction
2 Pith papers cite this work. Polarity classification is still indexing.
fields
quant-ph 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
A branch-resolved framework for characterizing feed-forward error in dynamic teleportation via classical Choi shadows is introduced, experimentally validated on two qubit layouts, and shown to reveal mitigation behaviors hidden by outcome averaging.
citing papers explorer
-
Learning Mid-circuit Measurement Backaction from Three Repeated Measurements
Protocol learns single-qubit Z-twirled MCM instrument parameters from three repeated measurements on mixed input, yielding ~100x better Pauli-observable prediction than confusion-matrix models on IBM processors.
-
Branch-Resolved Characterization of Feed-Forward Error in Dynamic Teleportation via Classical Choi Shadows
A branch-resolved framework for characterizing feed-forward error in dynamic teleportation via classical Choi shadows is introduced, experimentally validated on two qubit layouts, and shown to reveal mitigation behaviors hidden by outcome averaging.