English

Classically Time-Controlled Quantum Automata: Definition and Properties

Formal Languages and Automata Theory 2025-09-25 v10 Computational Complexity Quantum Physics

Abstract

In this paper, we introduce classically time-controlled quantum automata or CTQA, which is a reasonable modification of Moore-Crutchfield quantum finite automata that uses time-dependent evolution and a "scheduler" defining how long each Hamiltonian will run. Surprisingly enough, time-dependent evolution provides a significant change in the computational power of quantum automata with respect to a discrete quantum model. Indeed, we show that if a scheduler is not computationally restricted, then a CTQA could even decide the Halting problem. In order to unearth the computational capabilities of CTQAs we study the case of a computationally restricted scheduler. In particular, we showed that depending on the type of restriction imposed on the scheduler, a CTQA can (i) recognize non-regular languages with cut-point, even in the presence of Karp-Lipton advice, and (ii) recognize non-regular promise languages with bounded-error. Furthermore, we study the cutpoint-union of cutpoint languages by introducing a new model of Moore-Crutchfield quantum finite automata with a rotating tape head. CTQA presents itself as a new model of computation that provides a different approach to a formal study of "classical control, quantum data" schemes in quantum computing.

Keywords

Cite

@article{arxiv.1807.05385,
  title  = {Classically Time-Controlled Quantum Automata: Definition and Properties},
  author = {Alejandro Díaz-Caro and Marcos Villagra},
  journal= {arXiv preprint arXiv:1807.05385},
  year   = {2025}
}

Comments

Long revisited version of LNCS 11324:266-278, 2018 (TPNC 2018)

R2 v1 2026-06-23T03:01:22.806Z