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Binary Optimal Control Of Single-Flux-Quantum Pulse Sequences

Quantum Physics 2022-08-24 v3 Numerical Analysis Dynamical Systems Numerical Analysis Optimization and Control

Abstract

We introduce a binary, relaxed gradient, trust-region method for optimizing pulse sequences for single flux quanta (SFQ) control of a quantum computer. The pulse sequences are optimized with the goal of realizing unitary gate transformations. Each pulse has a fixed amplitude and duration. We model this process as an binary optimal control problem, constrained by Schr\"{o}dinger's equation, where the binary variables indicate whether each pulse is on or off. We introduce a first-order trust-region method, which takes advantage of a relaxed gradient to determine an optimal pulse sequence that minimizes the gate infidelity, while also suppressing leakage to higher energy levels. The proposed algorithm has a computational complexity of O(plog(p){\cal O}(p\log(p), where pp is the number of pulses in the sequence. We present numerical results for the H and X gates, where the optimized pulse sequences give gate fidelity's better than 99.9%99.9\%, in 25\approx 25 trust-region iterations.

Keywords

Cite

@article{arxiv.2106.10329,
  title  = {Binary Optimal Control Of Single-Flux-Quantum Pulse Sequences},
  author = {Ryan H. Vogt and N. Anders Petersson},
  journal= {arXiv preprint arXiv:2106.10329},
  year   = {2022}
}
R2 v1 2026-06-24T03:22:32.165Z