English

Elementary Quantum Recursion Schemes That Capture Quantum Polylogarithmic Time Computability of Quantum Functions

Computational Complexity 2025-01-22 v3 Quantum Physics

Abstract

Quantum computing has been studied over the past four decades based on two computational models of quantum circuits and quantum Turing machines. To capture quantum polynomial-time computability, a new recursion-theoretic approach was taken lately by Yamakami [J. Symb. Logic 80, pp.~1546--1587, 2020] by way of recursion schematic definition, which constitutes six initial quantum functions and three construction schemes of composition, branching, and multi-qubit quantum recursion. By taking a similar approach, we look into quantum polylogarithmic-time computability and further explore the expressing power of elementary schemes designed for such quantum computation. In particular, we introduce an elementary form of the quantum recursion, called the fast quantum recursion, and formulate EQSEQS (elementary quantum schemes) of ``elementary'' quantum functions. This class EQSEQS captures exactly quantum polylogarithmic-time computability, which forms the complexity class BQPOLYLOGTIME. We also demonstrate the separation of BQPOLYLOGTIME from NLOGTIME and PPOLYLOGTIME. As a natural extension of EQSEQS, we further consider an algorithmic procedural scheme that implements the well-known divide-and-conquer strategy. This divide-and-conquer scheme helps compute the parity function but the scheme cannot be realized within our system EQSEQS.

Keywords

Cite

@article{arxiv.2311.15884,
  title  = {Elementary Quantum Recursion Schemes That Capture Quantum Polylogarithmic Time Computability of Quantum Functions},
  author = {Tomoyuki Yamakami},
  journal= {arXiv preprint arXiv:2311.15884},
  year   = {2025}
}

Comments

(A4, 10pt, 29 pages) This is a corrected and expanded version of the preliminary report that has appeared, under a different title, in the Proceedings of the 28th International Conference on Logic, Language, Information, and Computation (WoLLIC 2022), Ia\c{s}i, Romania, September 20--23, 2022, Lecture Notes in Computer Science, vol. 13468, pp. 88-104, Springer, 2022

R2 v1 2026-06-28T13:32:46.145Z