English

Bounds on quantum evolution complexity via lattice cryptography

Quantum Physics 2022-10-12 v3 Data Structures and Algorithms High Energy Physics - Theory Optimization and Control Data Analysis, Statistics and Probability

Abstract

We address the difference between integrable and chaotic motion in quantum theory as manifested by the complexity of the corresponding evolution operators. Complexity is understood here as the shortest geodesic distance between the time-dependent evolution operator and the origin within the group of unitaries. (An appropriate `complexity metric' must be used that takes into account the relative difficulty of performing `nonlocal' operations that act on many degrees of freedom at once.) While simply formulated and geometrically attractive, this notion of complexity is numerically intractable save for toy models with Hilbert spaces of very low dimensions. To bypass this difficulty, we trade the exact definition in terms of geodesics for an upper bound on complexity, obtained by minimizing the distance over an explicitly prescribed infinite set of curves, rather than over all possible curves. Identifying this upper bound turns out equivalent to the closest vector problem (CVP) previously studied in integer optimization theory, in particular, in relation to lattice-based cryptography. Effective approximate algorithms are hence provided by the existing mathematical considerations, and they can be utilized in our analysis of the upper bounds on quantum evolution complexity. The resulting algorithmically implemented complexity bound systematically assigns lower values to integrable than to chaotic systems, as we demonstrate by explicit numerical work for Hilbert spaces of dimensions up to ~10^4.

Keywords

Cite

@article{arxiv.2202.13924,
  title  = {Bounds on quantum evolution complexity via lattice cryptography},
  author = {Ben Craps and Marine De Clerck and Oleg Evnin and Philip Hacker and Maxim Pavlov},
  journal= {arXiv preprint arXiv:2202.13924},
  year   = {2022}
}

Comments

v3: minor changes, figure and references added; The MATLAB code and data to reproduce numerical results are available at https://doi.org/10.5281/zenodo.6339975

R2 v1 2026-06-24T09:56:37.887Z