Toward speedup without quantum coherent access

TL;DR

This paper introduces a hybrid classical-quantum algorithm that leverages classical knowledge to efficiently encode matrices, enabling near-term feasible quantum solutions for various problems with potential exponential speedups.

Contribution

It proposes a novel hybrid approach combining classical pre-processing with quantum block encoding, reducing complexity and broadening practical applications of quantum algorithms.

Findings

Achieves logarithmic complexity in input dimension for classical and quantum procedures.

Provides exponential improvement for certain matrices and Hamiltonians over existing methods.

Enables end-to-end quantum data fitting with predictive capabilities.

Abstract

Along with the development of quantum technology, finding useful applications of quantum computers has been a central pursuit. Despite various quantum algorithms have been developed, many of them often require strong input assumptions, which is hardware demanding. In particular, recent advances on dequantization have revealed that the quantum advantage is more of a mere artifact of strong input assumptions. In this work, we propose a variant of these algorithms, leveraging both classical and quantum resources. Provided the classical knowledge (the entries) of the matrix/vector of interest, a classical procedure is used to pre-process this information. Then they are fed into a quantum circuit which is shown to be a block encoding of the matrix of interest. From this block-encoding, we show how to use it to tackle a wide range of problems, including principal component analysis, linear equation solving, Hamiltonian simulation, preparing ground state, and data fitting. We also analyze our protocol, showing that both the classical and quantum procedure can achieve logarithmic complexity in the input dimension, thus implying its potential for near term realization. We then discuss several implications and corollaries of our result. First,, our results suggest there are certain matrices/Hamiltonians where our method can provide exponential improvement compared to the existing ones with respect to the sparsity. Regarding dense linear systems, our method achieves exponential speed-up with respect to the inverse of error tolerance, compared to the best previously known quantum algorithm for dense systems. Last, and most importantly, regarding quantum data fitting, we show how the output of our quantum algorithms can be leveraged to predict unseen data. Thus, it provides an end-to-end application, which has been an open aspect of the previous quantum data fitting algorithm.