Quantum-Inspired Algorithms beyond Unitary Circuits: the Laplace Transform
Abstract
Quantum-inspired algorithms can deliver substantial speedups over classical state-of-the-art methods by executing quantum algorithms with tensor networks on conventional hardware. Unlike circuit models restricted to unitary gates, tensor networks naturally accommodate non-unitary maps. This flexibility lets us design quantum-inspired methods that start from a quantum algorithmic structure, yet go beyond unitarity to achieve speedups. Here we introduce a tensor-network approach to compute the discrete Laplace transform, a non-unitary, aperiodic transform (in contrast to the Fourier transform). We encode a length- signal on two paired -qubit registers and decompose the overall map into a non-unitary exponential Damping Transform followed by a Quantum Fourier Transform, both compressed in a single matrix-product operator. This decomposition admits strong MPO compression to low bond dimension resulting in significant acceleration. We demonstrate simulations up to input data points, with up to output data points, and quantify how bond dimension controls runtime and accuracy, including precise and efficient pole identification.
Cite
@article{arxiv.2601.17724,
title = {Quantum-Inspired Algorithms beyond Unitary Circuits: the Laplace Transform},
author = {Noufal Jaseem and Sergi Ramos-Calderer and Gauthameshwar S. and Dingzu Wang and José Ignacio Latorre and Dario Poletti},
journal= {arXiv preprint arXiv:2601.17724},
year = {2026}
}
Comments
9 pages