Optimal control with flag qubits
Abstract
High-fidelity quantum operations are the cornerstone of fault-tolerant quantum computation. In open quantum systems, traditional optimal control only passively resists decoherence, leaving environment-induced uncertainty as a fundamental performance bottleneck. To overcome this, we propose a new optimal control framework with flag ancillas and the Flag-GRAPE algorithm, which can actively tailor the system's noise structure. Through embedding post-selection directly into the objective function, Flag-GRAPE correlates decoherence errors with the ancilla's unexpected state. Subsequent measurement and post-selection effectively expel this uncertainty, circumventing the fidelity bounds of traditional control. Numerical simulations in a superconducting quantum circuit demonstrate a reduction in infidelity compared to traditional closed-system pulses and also show that such enhancement is robust across broad noise regimes. Furthermore, by actively converting unstructured decoherence into heralded erasure errors, Flag-GRAPE is inherently compatible with quantum error correction. We demonstrate this by initializing a logical cat-code state, showing that the combination between Flag-GRAPE and QEC yields immediate state preparation enhancements. This new framework can reduce hardware overhead for fault-tolerant architectures and open up a practical path toward logical state preparation gain in near-term experiments.
Cite
@article{arxiv.2603.12162,
title = {Optimal control with flag qubits},
author = {Liang-Xu Xie and Lui Zuccherelli de Paula and Weizhou Cai and Qing-Xuan Jie and Luyan Sun and Chang-Ling Zou and Guang-Can Guo and Zi-Jie Chen and Xu-Bo Zou},
journal= {arXiv preprint arXiv:2603.12162},
year = {2026}
}
Comments
8 pages, 4 figures