A co-design method for frequency allocation and noise-aware transpilation in tunable-coupler quantum systems yields 8.9% lower log-infidelity cost and 6.8% shorter circuits than SABRE on SNAIL architectures.
Title resolution pending
2 Pith papers cite this work. Polarity classification is still indexing.
2
Pith papers citing it
fields
quant-ph 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
A driven-dissipative model for qudit-resonator systems is used to derive expressions for quantum/tunneling capacitances and Sisyphus/Hermes resistances that change when the two subsystems influence each other dynamically.
citing papers explorer
-
Fidelity-Aware Frequency Allocation and Transpilation Co-Design for Tunable Coupler Quantum Systems
A co-design method for frequency allocation and noise-aware transpilation in tunable-coupler quantum systems yields 8.9% lower log-infidelity cost and 6.8% shorter circuits than SABRE on SNAIL architectures.
-
Reflections on Quantum Reflectometry: Quantum and Tunneling capacitances as well as Sisyphus and Hermes resistances
A driven-dissipative model for qudit-resonator systems is used to derive expressions for quantum/tunneling capacitances and Sisyphus/Hermes resistances that change when the two subsystems influence each other dynamically.