A Factorization Identity for Twisted Multinomial Coefficients with Application to Pilot States in Hamiltonian Decoded Quantum Interferometry
Abstract
The -multinomial coefficient, a classical object in enumerative combinatorics, counts permutations of multisets weighted by the number of inversions, with a single deformation parameter . We introduce the twisted multinomial coefficient, in which each inversion between letters and carries a pair-dependent weight determined by a skew-symmetric matrix . In general, no closed-form evaluation is known. Our main result is that under a natural structural condition on - predecessor-uniformity ( for all ) - the twisted multinomial factorizes as a product of Gaussian (-deformed) binomials with site-dependent parameters: where . This extends the standard product formula for the -multinomial from a single parameter to independent parameters. The identity is purely combinatorial: it holds for arbitrary without any algebraic constraints. We were led to this identity by studying pilot state preparation in Hamiltonian Decoded Quantum Interferometry (HDQI), a recently proposed quantum algorithm for preparing Gibbs and ground states. As an application, we show that the factorization yields an exact matrix product state (MPS) of bond dimension for the expansion coefficients of in a twisted algebra. We further show that the same site matrices deliver an exact MPS of bond dimension for the expansion coefficients of , for any polynomial , via a polynomial-dependent right boundary vector.
Cite
@article{arxiv.2604.01022,
title = {A Factorization Identity for Twisted Multinomial Coefficients with Application to Pilot States in Hamiltonian Decoded Quantum Interferometry},
author = {Pawel Wocjan},
journal= {arXiv preprint arXiv:2604.01022},
year = {2026}
}
Comments
Improved presentation for general polynomials in v2