Quantum Subspace Correction for Constraints
Abstract
We demonstrate that it is possible to construct operators that stabilize the constraint-satisfying subspaces of computational problems in their Ising representations. We provide an explicit recipe to construct unitaries and associated measurements given a set of constraints. The stabilizer measurements allow the detection of constraint violations, and provide a route to recovery back into the constrained subspace. We call this technique ''quantum subspace correction". As an example, we explicitly investigate the stabilizers using the simplest local constraint subspace: Independent Set. We find an algorithm that is guaranteed to produce a perfect uniform or weighted distribution over all constraint-satisfying states when paired with a stopping condition: a quantum analogue of partial rejection sampling. The stopping condition can be modified for sub-graph approximations. We show that it can prepare exact Gibbs distributions on regular graphs below a critical hardness in sub-linear time. Finally, we look at a potential use of quantum subspace correction for fault-tolerant depth-reduction. In particular we investigate how the technique detects and recovers errors induced by Trotterization in preparing maximum independent set using an adiabatic state preparation algorithm.
Cite
@article{arxiv.2310.20191,
title = {Quantum Subspace Correction for Constraints},
author = {Kelly Ann Pawlak and Jeffrey M. Epstein and Daniel Crow and Srilekha Gandhari and Ming Li and Thomas C. Bohdanowicz and Jonathan King},
journal= {arXiv preprint arXiv:2310.20191},
year = {2024}
}
Comments
12 + 4 pages, 6 figures