Linearized gate set tomography scales error characterization to many qubits via sparse models, linear fitting, and shallow circuits, with simulations showing accuracy on 10-qubit systems including crosstalk.
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Cyclic control via parameter-space expansion restores controllability in fast CZ gates despite short-timescale distortions, cutting average coherent error from 0.27% to 0.12% in superconducting qubit experiments without extending gate duration.
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Scalable linearized gate set tomography
Linearized gate set tomography scales error characterization to many qubits via sparse models, linear fitting, and shallow circuits, with simulations showing accuracy on 10-qubit systems including crosstalk.
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Overcoming the Speed-Fidelity Trade-off in Fast CZ Gates via Cyclic Control
Cyclic control via parameter-space expansion restores controllability in fast CZ gates despite short-timescale distortions, cutting average coherent error from 0.27% to 0.12% in superconducting qubit experiments without extending gate duration.