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Distributed Exact Quantum Amplitude Amplification Algorithm for Arbitrary Quantum States

Quantum Physics 2026-01-15 v1

Abstract

In the noisy intermediate-scale quantum (NISQ) era, distributed quantum computation has garnered considerable interest, as it overcomes the physical limitations of single-device architectures and enables scalable quantum information processing. In this study, we focus on the challenge of achieving exact amplitude amplification for quantum states with arbitrary amplitude distributions and subsequently propose a Distributed Exact Quantum Amplitude Amplification Algorithm (DEQAAA). Specifically, (1) it supports partitioning across any number of nodes tt within the range 2tn2 \leq t \leq n; (2) the maximum qubit count required for any single node is expressed as max(n0,n1,,nt1)\max \left(n_0,n_1,\dots,n_{t-1} \right) , where njn_j represents the number of qubits at the jj-th node, with j=0t1nj=n\sum_{j=0}^{t-1} n_j =n; (3) it can realize exact amplitude amplification for multiple targets of a quantum state with arbitrary amplitude distributions; (4) we verify the effectiveness of DEQAAA by resolving a specific exact amplitude amplification task involving two targets (8 and 14 in decimal) via MindSpore Quantum, a quantum simulation software, with tests conducted on 4-qubit, 6-qubit, 8-qubit and 10-qubit systems. Notably, through the decomposition of Cn1PSC^{n-1}PS gates, DEQAAA demonstrates remarkable advantages in both quantum gate count and circuit depth as the qubit number scales, thereby boosting its noise resilience. In the 10-qubit scenario, for instance, it achieves a reduction of over 97%97\% in both indicators compared to QAAA and EQAAA, underscoring its outstanding resource-saving performance.

Keywords

Cite

@article{arxiv.2601.09128,
  title  = {Distributed Exact Quantum Amplitude Amplification Algorithm for Arbitrary Quantum States},
  author = {Xu Zhou and Wenxuan Tao and Keren Li and Shenggen Zheng},
  journal= {arXiv preprint arXiv:2601.09128},
  year   = {2026}
}

Comments

42 pages, 27 figures, comments are welcome

R2 v1 2026-07-01T09:03:46.138Z