English

Quantum Depth in the Random Oracle Model

Quantum Physics 2023-07-11 v1 Computational Complexity Cryptography and Security

Abstract

We give a comprehensive characterization of the computational power of shallow quantum circuits combined with classical computation. Specifically, for classes of search problems, we show that the following statements hold, relative to a random oracle: (a) BPPQNCBPPBQP\mathsf{BPP}^{\mathsf{QNC}^{\mathsf{BPP}}} \neq \mathsf{BQP}. This refutes Jozsa's conjecture [QIP 05] in the random oracle model. As a result, this gives the first instantiatable separation between the classes by replacing the oracle with a cryptographic hash function, yielding a resolution to one of Aaronson's ten semi-grand challenges in quantum computing. (b) BPPQNCQNCBPP\mathsf{BPP}^{\mathsf{QNC}} \nsubseteq \mathsf{QNC}^{\mathsf{BPP}} and QNCBPPBPPQNC\mathsf{QNC}^{\mathsf{BPP}} \nsubseteq \mathsf{BPP}^{\mathsf{QNC}}. This shows that there is a subtle interplay between classical computation and shallow quantum computation. In fact, for the second separation, we establish that, for some problems, the ability to perform adaptive measurements in a single shallow quantum circuit, is more useful than the ability to perform polynomially many shallow quantum circuits without adaptive measurements. (c) There exists a 2-message proof of quantum depth protocol. Such a protocol allows a classical verifier to efficiently certify that a prover must be performing a computation of some minimum quantum depth. Our proof of quantum depth can be instantiated using the recent proof of quantumness construction by Yamakawa and Zhandry [STOC 22].

Keywords

Cite

@article{arxiv.2210.06454,
  title  = {Quantum Depth in the Random Oracle Model},
  author = {Atul Singh Arora and Andrea Coladangelo and Matthew Coudron and Alexandru Gheorghiu and Uttam Singh and Hendrik Waldner},
  journal= {arXiv preprint arXiv:2210.06454},
  year   = {2023}
}

Comments

104 pages (+ 9 page Appendix), 10 figures

R2 v1 2026-06-28T03:28:35.175Z