Quantum machine learning with subspace states
Abstract
We introduce a new approach for quantum linear algebra based on quantum subspace states and present three new quantum machine learning algorithms. The first is a quantum determinant sampling algorithm that samples from the distribution for using gates and with circuit depth . The state of art classical algorithm for the task requires operations \cite{derezinski2019minimax}. The second is a quantum singular value estimation algorithm for compound matrices , the speedup for this algorithm is potentially exponential. It decomposes a dimensional vector of order- correlations into a linear combination of subspace states corresponding to -tuples of singular vectors of . The third algorithm reduces exponentially the depth of circuits used in quantum topological data analysis from to . Our basic tool are quantum subspace states, defined as for matrices such that , that encode -dimensional subspaces of . We develop two efficient state preparation techniques, the first using Givens circuits uses the representation of a subspace as a sequence of Givens rotations, while the second uses efficient implementations of unitaries with depth circuits that we term Clifford loaders.
Cite
@article{arxiv.2202.00054,
title = {Quantum machine learning with subspace states},
author = {Iordanis Kerenidis and Anupam Prakash},
journal= {arXiv preprint arXiv:2202.00054},
year = {2022}
}