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Space-Bounded Unitary Quantum Computation with Postselection

Quantum Physics 2022-09-14 v2 Computational Complexity

Abstract

Space-bounded computation has been a central topic in classical and quantum complexity theory. In the quantum case, every elementary gate must be unitary. This restriction makes it unclear whether the power of space-bounded computation changes by allowing intermediate measurement. In the bounded error case, Fefferman and Remscrim [STOC 2021, pp.1343--1356] and Girish, Raz and Zhan~[ICALP 2021, pp.73:1--73:20] recently provided the break-through results that the power does not change. This paper shows that a similar result holds for space-bounded quantum computation with postselection. Namely, it is proved possible to eliminate intermediate postselections and measurements in the space-bounded quantum computation in the bounded-error setting. Our result strengthens the recent result by Le Gall, Nishimura and Yakaryilmaz~[TQC 2021, pp.10:1--10:17] that logarithmic-space bounded-error quantum computation with intermediate postselections and measurements is equivalent in computational power to logarithmic-space unbounded-error probabilistic computation. As an application, it is shown that bounded-error space-bounded one-clean qubit computation (DQC1) with postselection is equivalent in computational power to unbounded-error space-bounded probabilistic computation, and the computational supremacy of the bounded-error space-bounded DQC1 is interpreted in complexity-theoretic terms.

Keywords

Cite

@article{arxiv.2206.15122,
  title  = {Space-Bounded Unitary Quantum Computation with Postselection},
  author = {Seiichiro Tani},
  journal= {arXiv preprint arXiv:2206.15122},
  year   = {2022}
}

Comments

Full version of the MFCS 2022 paper. Typos fixed. Some minor clarifications and corrections

R2 v1 2026-06-24T12:09:21.939Z