Efficient Quantum State Preparation with Walsh Series
Abstract
A new approximate Quantum State Preparation (QSP) method is introduced, called the Walsh Series Loader (WSL). The WSL approximates quantum states defined by real-valued functions of single real variables with a depth independent of the number of qubits. Two approaches are presented: the first one approximates the target quantum state by a Walsh Series truncated at order , where is the precision of the approximation in terms of infidelity. The circuit depth is also , the size is and only one ancilla qubit is needed. The second method represents accurately quantum states with sparse Walsh series. The WSL loads -sparse Walsh Series into -qubits with a depth doubly-sparse in and , the maximum number of bits with value in the binary decomposition of the Walsh function indices. The associated quantum circuit approximates the sparse Walsh Series up to an error with a depth , a size and one ancilla qubit. In both cases, the protocol is a Repeat-Until-Success (RUS) procedure with a probability of success , giving an averaged total time of for the WSL (resp. for the sparse WSL). Amplitude amplification can be used to reduce by a factor the total time dependency with but increases the size and depth of the associated quantum circuits, making them linearly dependent on . These protocols give overall efficient algorithms with no exponential scaling in any parameter. They can be generalized to any complex-valued, multi-variate, almost-everywhere-differentiable function. The Repeat-Until-Success Walsh Series Loader is so far the only method which prepares a quantum state with a circuit depth and an averaged total time independent of the number of qubits.
Cite
@article{arxiv.2307.08384,
title = {Efficient Quantum State Preparation with Walsh Series},
author = {Julien Zylberman and Fabrice Debbasch},
journal= {arXiv preprint arXiv:2307.08384},
year = {2023}
}