# A Model Order Reduction Algorithm for Estimating the Absorption Spectrum

**Authors:** Roel Van Beeumen, David B. Williams-Young, Joseph M. Kasper and, Chao Yang, Esmond G. Ng, Xiaosong Li

arXiv: 1704.05923 · 2019-03-21

## TL;DR

This paper introduces an adaptive model order reduction algorithm for efficiently estimating the absorption spectrum in electronic structure calculations, significantly reducing computational costs for dense spectral problems.

## Contribution

The paper presents a novel interpolation-based model order reduction method that automatically determines reduced model size for spectral estimation, improving efficiency over traditional approaches.

## Key findings

- Algorithm scales quadratically with problem size
- Model order increases logarithmically with problem dimension
- Effective in dense spectral regions like the oxygen K-edge

## Abstract

The ab initio description of the spectral interior of the absorption spectrum poses both a theoretical and computational challenge for modern electronic structure theory. Due to the often spectrally dense character of this domain in the quantum propagator's eigenspectrum for medium-to-large sized systems, traditional approaches based on the partial diagonalization of the propagator often encounter oscillatory and stagnating convergence. Electronic structure methods which solve the molecular response problem through the solution of spectrally shifted linear systems, such as the complex polarization propagator, offer an alternative approach which is agnostic to the underlying spectral density or domain location. This generality comes at a seemingly high computational cost associated with solving a large linear system for each spectral shift in some discretization of the spectral domain of interest. We present a novel, adaptive solution based on model order reduction techniques via interpolation. Model order reduction reduces the computational complexity of mathematical models and is ubiquitous in the simulation of dynamical systems. The efficiency and effectiveness of the proposed algorithm in the ab initio prediction of X-Ray absorption spectra is demonstrated using a test set of challenging water clusters which are spectrally dense in the neighborhood of the oxygen K-edge. Based on a single, user defined tolerance we automatically determine the order of the reduced models and approximate the absorption spectrum up to the given tolerance. We also illustrate that the automatically determined model order increases logarithmically with the problem dimension, compared to a linear increase of the number of eigenvalues within the energy window. Furthermore, we observed that the computational cost of the proposed algorithm only scales quadratically with respect to the problem dimension.

## Full text

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## Figures

20 figures with captions in the complete paper: https://tomesphere.com/paper/1704.05923/full.md

## References

66 references — full list in the complete paper: https://tomesphere.com/paper/1704.05923/full.md

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Source: https://tomesphere.com/paper/1704.05923