English

Time-optimal multi-qubit gates: Complexity, efficient heuristic and gate-time bounds

Quantum Physics 2024-03-13 v2

Abstract

Multi-qubit entangling interactions arise naturally in several quantum computing platforms and promise advantages over traditional two-qubit gates. In particular, a fixed multi-qubit Ising-type interaction together with single-qubit X-gates can be used to synthesize global ZZ-gates (GZZ gates). In this work, we first show that the synthesis of such quantum gates that are time-optimal is NP-hard. Second, we provide explicit constructions of special time-optimal multi-qubit gates. They have constant gate times and can be implemented with linearly many X-gate layers. Third, we develop a heuristic algorithm with polynomial runtime for synthesizing fast multi-qubit gates. Fourth, we derive lower and upper bounds on the optimal GZZ gate-time. Based on explicit constructions of GZZ gates and numerical studies, we conjecture that any GZZ gate can be executed in a time O(n) for n qubits. Our heuristic synthesis algorithm leads to GZZ gate-times with a similar scaling, which is optimal in this sense. We expect that our efficient synthesis of fast multi-qubit gates allows for faster and, hence, also more error-robust execution of quantum algorithms.

Keywords

Cite

@article{arxiv.2307.11160,
  title  = {Time-optimal multi-qubit gates: Complexity, efficient heuristic and gate-time bounds},
  author = {Pascal Baßler and Markus Heinrich and Martin Kliesch},
  journal= {arXiv preprint arXiv:2307.11160},
  year   = {2024}
}

Comments

19+4 pages, 2 figures

R2 v1 2026-06-28T11:36:21.944Z