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Quantum-Inspired Algorithms beyond Unitary Circuits: the Laplace Transform

Quantum Physics 2026-03-19 v2 Mathematical Physics math.MP Data Analysis, Statistics and Probability

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-NN signal on two paired nn-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 N=230N=2^{30} input data points, with up to 2602^{60} output data points, and quantify how bond dimension controls runtime and accuracy, including precise and efficient pole identification.

Keywords

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

R2 v1 2026-07-01T09:18:59.287Z