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Dense outputs from quantum simulations

Quantum Physics 2024-06-21 v2 Numerical Analysis Numerical Analysis

Abstract

The quantum dense output problem is the process of evaluating time-accumulated observables from time-dependent quantum dynamics using quantum computers. This problem arises frequently in applications such as quantum control and spectroscopic computation. We present a range of algorithms designed to operate on both early and fully fault-tolerant quantum platforms. These methodologies draw upon techniques like amplitude estimation, Hamiltonian simulation, quantum linear Ordinary Differential Equation (ODE) solvers, and quantum Carleman linearization. We provide a comprehensive complexity analysis with respect to the evolution time TT and error tolerance ϵ\epsilon. Our results demonstrate that the linearization approach can nearly achieve optimal complexity O(T/ϵ)\mathcal{O}(T/\epsilon) for a certain type of low-rank dense outputs. Moreover, we provide a linearization of the dense output problem that yields an exact and finite-dimensional closure which encompasses the original states. This formulation is related to the Koopman Invariant Subspace theory and may be of independent interest in nonlinear control and scientific machine learning.

Keywords

Cite

@article{arxiv.2307.14441,
  title  = {Dense outputs from quantum simulations},
  author = {Jin-Peng Liu and Lin Lin},
  journal= {arXiv preprint arXiv:2307.14441},
  year   = {2024}
}

Comments

30 pages. Accepted by Journal of Computational Physics

R2 v1 2026-06-28T11:41:06.012Z