Logarithmic-Depth Quantum Circuits for Hamming Weight Projections
Abstract
A pure state of fixed Hamming weight is a superposition of computational basis states such that each bitstring in the superposition has the same number of ones. Given a Hilbert space of the form , or an -qubit system, the identity operator can be decomposed as a sum of projectors onto subspaces of fixed Hamming weight. In this work, we propose several quantum algorithms that realize a coherent Hamming weight projective measurement on an input pure state, meaning that the post-measurement state of the algorithm is the projection of the input state onto the corresponding subspace of fixed Hamming weight. We analyze a depth-width trade-off for the corresponding quantum circuits, allowing for a depth reduction of the circuits at the cost of more control qubits. For an -qubit input, the depth-optimal algorithm uses control qubits and the corresponding circuit has depth , assuming that we have the ability to perform qubit resets. Furthermore, the proposed algorithm construction uses only one- and two-qubit gates.
Cite
@article{arxiv.2404.07151,
title = {Logarithmic-Depth Quantum Circuits for Hamming Weight Projections},
author = {Soorya Rethinasamy and Margarite L. LaBorde and Mark M. Wilde},
journal= {arXiv preprint arXiv:2404.07151},
year = {2025}
}
Comments
17 pages, 14 figures; see independent and concurrent work of Zi, Nie, Sun at arXiv:2404.06052 and Piroli, Styliaris, Cirac at arXiv:2403.07604. Accepted for publication in Physical Review A