TY - GEN
T1 - Cycle-Aware Parallel Optimization for Mitigating ZZ Crosstalk on Quantum Hardware
AU - Zhong, Jiayi
AU - Deng, Yuxin
N1 - Publisher Copyright:
© 2025 Copyright held by the owner/author(s).
PY - 2025/12/20
Y1 - 2025/12/20
N2 - ZZ crosstalk and decoherence hinder superconducting quantum computing. Mitigation strategies often require sequential gate execution, which restricts parallelism. We reformulate ZZ crosstalk mitigation as a parallel task scheduling problem by integrating quantum cycles and qubit interference. We then propose CYCO, a CYcle-aware ZZ Crosstalk Optimization algorithm, which uses a timing-based greedy strategy to schedule gates through cycles within quantum circuits. A novel data structure called Time and Distance Dependency Graph (TDDG) is designed to model gate dependencies and physical qubit distances. Based on TDDG, barrier punching is introduced to eliminate redundant synchronization barriers by merging independent gate groups, improving gate concurrency per cycle. Simulations show a reduction of up to 37.44% in quantum program cycle (14.19% on average) on 53- to 127-qubit NISQ devices, with up to 1.6 × higher parallelism than state-of-the-art methods. Real-device experiments demonstrate significant acceleration in quantum computing while maintaining fidelity.
AB - ZZ crosstalk and decoherence hinder superconducting quantum computing. Mitigation strategies often require sequential gate execution, which restricts parallelism. We reformulate ZZ crosstalk mitigation as a parallel task scheduling problem by integrating quantum cycles and qubit interference. We then propose CYCO, a CYcle-aware ZZ Crosstalk Optimization algorithm, which uses a timing-based greedy strategy to schedule gates through cycles within quantum circuits. A novel data structure called Time and Distance Dependency Graph (TDDG) is designed to model gate dependencies and physical qubit distances. Based on TDDG, barrier punching is introduced to eliminate redundant synchronization barriers by merging independent gate groups, improving gate concurrency per cycle. Simulations show a reduction of up to 37.44% in quantum program cycle (14.19% on average) on 53- to 127-qubit NISQ devices, with up to 1.6 × higher parallelism than state-of-the-art methods. Real-device experiments demonstrate significant acceleration in quantum computing while maintaining fidelity.
KW - Crosstalk Mitigation
KW - Quantum Computing
KW - Superconducting Quantum Computer
UR - https://www.scopus.com/pages/publications/105026449026
U2 - 10.1145/3754598.3754622
DO - 10.1145/3754598.3754622
M3 - 会议稿件
AN - SCOPUS:105026449026
T3 - 54th International Conference on Parallel Processing, ICPP 2025 - Main Conference Proceedings
SP - 648
EP - 657
BT - 54th International Conference on Parallel Processing, ICPP 2025 - Main Conference Proceedings
PB - Association for Computing Machinery, Inc
T2 - 54th International Conference on Parallel Processing, ICPP 2025
Y2 - 8 September 2025 through 11 September 2025
ER -