English

Efficient circuits for leaf-separable state preparation

Quantum Physics 2025-11-17 v1

Abstract

Efficient state preparation is a challenging and important problem in quantum computing. In this work, we present a recursive state preparation algorithm that combines logarithmic-depth Dicke state circuits with Hamming weight encoders for efficiently preparing ``leaf-separable" quantum states. The algorithm is built on binary partition trees, generalized weight distribution blocks (gWDBs), and leaf-level encoders. We evaluate the performance of the algorithm by numerically simulating it on randomly generated target states with between 4 and 15 qubits. Compared to general state preparation approaches which require O(2n)O(2^n) CX gates, our algorithm achieves a circuit depth of O(klognk+2k)O(k\log\frac{n}{k} + 2^k) and uses O(n(k+2k))O(n(k+2^k)) two-qubit gates, where k<nk < n denotes the subtree size. We also compare implementations of the algorithm with and without the use of ancilla qubits, providing a detailed analysis of the trade-offs in circuit depth and two-qubit gate counts. These results contribute to scalable state preparation for quantum algorithms that require structured inputs such as Dicke or near-Dicke states.

Keywords

Cite

@article{arxiv.2511.11227,
  title  = {Efficient circuits for leaf-separable state preparation},
  author = {Sunil Vittal and Anthony Wilkie and Nika Rastegari and Mostafa Atallah and Rebekah Herrman},
  journal= {arXiv preprint arXiv:2511.11227},
  year   = {2025}
}
R2 v1 2026-07-01T07:37:22.507Z