Finding quantum partial assignments by search-to-decision reductions
Abstract
In computer science, many search problems are reducible to decision problems, which implies that finding a solution is as hard as deciding whether a solution exists. A quantum analogue of search-to-decision reductions would be to ask whether a quantum algorithm with access to a oracle can construct witnesses as quantum states. By a result from Irani, Natarajan, Nirkhe, Rao, and Yuen (CCC '22), it is known that this does not hold relative to a quantum oracle, unlike the cases of , , and where search-to-decision relativizes. We prove that if one is not interested in the quantum witness as a quantum state but only in terms of its partial assignments, i.e. the reduced density matrices, then there exists a classical polynomial-time algorithm with access to a oracle that outputs approximations of the density matrices of a near-optimal quantum witness, for any desired constant locality and inverse polynomial error. Our construction is based on a circuit-to-Hamiltonian mapping that approximately preserves near-optimal witnesses and a new -complete problem, Low-energy Density Matrix Verification, which is called by the oracle to adaptively construct approximately consistent density matrices of a low-energy state.
Cite
@article{arxiv.2408.03986,
title = {Finding quantum partial assignments by search-to-decision reductions},
author = {Jordi Weggemans},
journal= {arXiv preprint arXiv:2408.03986},
year = {2025}
}
Comments
24 pages, V2: uses mixed state CLDM and minor changes