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Your search keyword '"Xiao, Brian"' showing total 8 results
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8 results on '"Xiao, Brian"'

1. Multi-task learning for molecular electronic structure approaching coupled-cluster accuracy

Author

Tang, Hao, Xiao, Brian, He, Wenhao, Subasic, Pero, Harutyunyan, Avetik R., Wang, Yao, Liu, Fang, Xu, Haowei, and Li, Ju

Subjects
Physics - Chemical Physics, Condensed Matter - Materials Science, Computer Science - Artificial Intelligence, Computer Science - Computational Engineering, Finance, and Science, Physics - Computational Physics
Abstract

Machine learning (ML) plays an important role in quantum chemistry, providing fast-to-evaluate predictive models for various properties of molecules. However, most existing ML models for molecular electronic properties use density functional theory (DFT) databases as ground truth in training, and their prediction accuracy cannot surpass that of DFT. In this work, we developed a unified ML method for electronic structures of organic molecules using the gold-standard CCSD(T) calculations as training data. Tested on hydrocarbon molecules, our model outperforms DFT with the widely-used hybrid and double hybrid functionals in computational costs and prediction accuracy of various quantum chemical properties. As case studies, we apply the model to aromatic compounds and semiconducting polymers on both ground state and excited state properties, demonstrating its accuracy and generalization capability to complex systems that are hard to calculate using CCSD(T)-level methods.

Published
2024

2. Neural-network preconditioners for solving the Dirac equation in lattice gauge theory

Author

Calì, Salvatore, Hackett, Daniel C., Lin, Yin, Shanahan, Phiala E., and Xiao, Brian

Subjects
High Energy Physics - Lattice, Computer Science - Machine Learning
Abstract

This work develops neural-network--based preconditioners to accelerate solution of the Wilson-Dirac normal equation in lattice quantum field theories. The approach is implemented for the two-flavor lattice Schwinger model near the critical point. In this system, neural-network preconditioners are found to accelerate the convergence of the conjugate gradient solver compared with the solution of unpreconditioned systems or those preconditioned with conventional approaches based on even-odd or incomplete Cholesky decompositions, as measured by reductions in the number of iterations and/or complex operations required for convergence. It is also shown that a preconditioner trained on ensembles with small lattice volumes can be used to construct preconditioners for ensembles with many times larger lattice volumes, with minimal degradation of performance. This volume-transferring technique amortizes the training cost and presents a pathway towards scaling such preconditioners to lattice field theory calculations with larger lattice volumes and in four dimensions., Comment: 11 pages, 6 figures, and 2 tables

Published
2022
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8. An improved error-diffusion approach for generating mesh models of images

Author

Michael D. Adams and Xiao (Brian) Ma

Subjects
Mathematical optimization, Delaunay triangulation, Computer science, Nonuniform sampling, Triangulation (social science), Image (mathematics), Error diffusion, Control and Systems Engineering, Mesh generation, Approximation error, Signal Processing, Computer Vision and Pattern Recognition, Electrical and Electronic Engineering, Algorithm, Software
Abstract

In earlier work, Yang et al. proposed a highly-effective technique for generating triangle-mesh models of images, known as the error diffusion (ED) method. Unfortunately, the ED method, which chooses triangulation connectivity via a Delaunay triangulation, typically yields triangulations in which many triangulation edges crosscut image edges, leading to increased approximation error. In this paper, we propose a computational framework for mesh generation that modifies the ED method to use data-dependent triangulations (DDTs) in conjunction with the Lawson local optimization procedure (LOP) and has several free parameters. Based on experimentation, we recommend two particular choices for these parameters, yielding two specific mesh-generation methods, known as MED1 and MED2, which make different tradeoffs between approximation quality and computational cost. Through the use of DDTs and the LOP, triangulation connectivity can be chosen optimally so as to minimize approximation error. As part of our work, two novel optimality criteria for the LOP are proposed, both of which are shown to outperform other well known criteria from the literature. Through experimental results, our MED1 and MED2 methods are shown to yield image approximations of substantially higher quality than those obtained with the ED method, at a relatively modest computational cost. HighlightsWe propose a mesh-generation framework for image representation.Our framework is based on the Yang-Wernick-Brankov error-diffusion (ED) method.We propose two mesh-generation methods derived from our framework.We show that the proposed methods perform much better than the ED method.

Published
2015
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