English

Spectral density estimation with the Gaussian Integral Transform

Quantum Physics 2020-08-19 v2 Nuclear Theory

Abstract

The spectral density operator ρ^(ω)=δ(ωH^)\hat{\rho}(\omega)=\delta(\omega-\hat{H}) plays a central role in linear response theory as its expectation value, the dynamical response function, can be used to compute scattering cross-sections. In this work, we describe a near optimal quantum algorithm providing an approximation to the spectral density with energy resolution Δ\Delta and error ϵ\epsilon using O(log(1/ϵ)(log(1/Δ)+log(1/ϵ))/Δ)\mathcal{O}\left(\sqrt{\log\left(1/\epsilon\right)\left(\log\left(1/\Delta\right)+\log\left(1/\epsilon\right)\right)}/\Delta\right) operations. This is achieved without using expensive approximations to the time-evolution operator but exploiting instead qubitization to implement an approximate Gaussian Integral Transform (GIT) of the spectral density. We also describe appropriate error metrics to assess the quality of spectral function approximations more generally.

Keywords

Cite

@article{arxiv.2004.04889,
  title  = {Spectral density estimation with the Gaussian Integral Transform},
  author = {Alessandro Roggero},
  journal= {arXiv preprint arXiv:2004.04889},
  year   = {2020}
}

Comments

12 pages - published version

R2 v1 2026-06-23T14:46:31.380Z