Adaptive feed-forward circuits outperform non-adaptive parallel schemes in mitigating error from noisy two-outcome qubit measurements, with advantage appearing at three uses and growing unbounded with more uses.
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First experimental realization of LEO-based adiabatic speedup on superconducting quantum processors, with enhanced fidelity using ideal pulses but limited gains from noise-model optimization.
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Reducing measurement error with adaptivity
Adaptive feed-forward circuits outperform non-adaptive parallel schemes in mitigating error from noisy two-outcome qubit measurements, with advantage appearing at three uses and growing unbounded with more uses.
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Realizing leakage elimination operator-based adiabatic speedup on a superconducting quantum processor
First experimental realization of LEO-based adiabatic speedup on superconducting quantum processors, with enhanced fidelity using ideal pulses but limited gains from noise-model optimization.