English

Towards Optimal Circuit Size for Sparse Quantum State Preparation

Quantum Physics 2024-04-10 v2

Abstract

Compared to general quantum states, the sparse states arise more frequently in the field of quantum computation. In this work, we consider the preparation for nn-qubit sparse quantum states with ss non-zero amplitudes and propose two algorithms. The first algorithm uses O(ns/logn+n)O(ns/\log n + n) gates, improving upon previous methods by O(logn)O(\log n). We further establish a matching lower bound for any algorithm which is not amplitude-aware and employs at most poly(n)\operatorname{poly}(n) ancillary qubits. The second algorithm is tailored for binary strings that exhibit a short Hamiltonian path. An application is the preparation of U(1)U(1)-invariant state with kk down-spins in a chain of length nn, including Bethe states, for which our algorithm constructs a circuit of size O((nk)logn)O\left(\binom{n}{k}\log n\right). This surpasses previous results by O(n/logn)O(n/\log n) and is close to the lower bound O((nk))O\left(\binom{n}{k}\right). Both the two algorithms shrink the existing gap theoretically and provide increasing advantages numerically.

Keywords

Cite

@article{arxiv.2404.05147,
  title  = {Towards Optimal Circuit Size for Sparse Quantum State Preparation},
  author = {Rui Mao and Guojing Tian and Xiaoming Sun},
  journal= {arXiv preprint arXiv:2404.05147},
  year   = {2024}
}
R2 v1 2026-06-28T15:46:53.940Z