Establishing a data-driven strength model for ??????-tin by performing symbolic regression using genetic programming

被引：6

作者：

Zapiain, David Montes de Oca ^{[1
]}

Lane, J. Matthew D. ^{[1
]}

Carroll, Jay D. ^{[1
]}

Casias, Zachary ^{[1
]}

Battaile, Corbett C. ^{[1
]}

Fensin, Saryu ^{[2
]}

Lim, Hojun ^{[1
]}

机构：

[1] Sandia Natl Labs, Albuquerque, NM 87185 USA

[2] Los Alamos Natl Lab, Los Alamos, NM 87545 USA

来源：

COMPUTATIONAL MATERIALS SCIENCE | 2023年 / 218卷

关键词：

Genetic programming; Tin; Strength; Symbolic regression; MODIFIED JOHNSON-COOK; MODIFIED ZERILLI-ARMSTRONG; HOT DEFORMATION-BEHAVIOR; CONSTITUTIVE MODELS; PLASTIC-DEFORMATION; STRAIN RATES; TEMPERATURE; PREDICT;

D O I：

10.1016/j.commatsci.2022.111967

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

Tin (Sn) exhibits complex deformation behavior characterized by significant dependence of strength on temperature and strain rate. This work develops a strength model for tin by using genetic programming to perform symbolic regression on a set of compression tests at various strain rates and temperatures. The strength model developed in this work showed increased accuracy compared to traditional strength models. Furthermore, the developed strength model adequately predicted independent experimental data (i.e., data that was not used to train the model). Results demonstrate that genetic programming successfully established a valid analytical function that adequately characterizes the temperature and strain rate dependent strength behavior of tin. Therefore, demonstrating that the developed framework provides robust and accurate formulations of strength models.

引用

页数：11

共 50 条

[31] Improving Generalization of Genetic Programming for Symbolic Regression With Angle-Driven Geometric Semantic Operators
Chen, Qi
Xue, Bing
Zhang, Mengjie
IEEE TRANSACTIONS ON EVOLUTIONARY COMPUTATION, 2019, 23 (03) : 488 - 502
[32] Improving Genetic Programming Based Symbolic Regression Using Deterministic Machine Learning
Icke, Ilknur
Bongard, Joshua C.
2013 IEEE CONGRESS ON EVOLUTIONARY COMPUTATION (CEC), 2013, : 1763 - 1770
[33] An Analysis of Exchanging Fitness Cases with Population Size in Symbolic Regression Genetic Programming with Respect to the Computational Model
Applegate, Douglas
Mayfield, Blayne
2013 IEEE CONGRESS ON EVOLUTIONARY COMPUTATION (CEC), 2013, : 3111 - 3116
[34] Multitree Genetic Programming With New Operators for Transfer Learning in Symbolic Regression With Incomplete Data
Al-Helali, Baligh
Chen, Qi
Xue, Bing
Zhang, Mengjie
IEEE TRANSACTIONS ON EVOLUTIONARY COMPUTATION, 2021, 25 (06) : 1049 - 1063
[35] Hessian Complexity Measure for Genetic Programming-Based Imputation Predictor Selection in Symbolic Regression with Incomplete Data
Al-Helali, Baligh
Chen, Qi
Xue, Bing
Zhang, Mengjie
GENETIC PROGRAMMING, EUROGP 2020, 2020, 12101 : 1 - 17
[36] Toward Physically Plausible Data-Driven Models: A Novel Neural Network Approach to Symbolic Regression
Kubalik, Jiri
Derner, Erik
Babuska, Robert
IEEE ACCESS, 2023, 11 : 61481 - 61501
[37] Data-Driven Non-Linear Current Controller Based on Deep Symbolic Regression for SPMSM
Usama, Muhammad
Lee, In-Young
SENSORS, 2022, 22 (21)
[38] Effects of reducing redundant parameters in parameter optimization for symbolic regression using genetic programming
Kronberger, Gabriel
de Franca, Fabricio Olivetti
JOURNAL OF SYMBOLIC COMPUTATION, 2025, 129
[39] Evolving Transparent Credit Risk Models: A Symbolic Regression Approach Using Genetic Programming
Sotiropoulos, Dionisios N.
Koronakos, Gregory
Solanakis, Spyridon V.
ELECTRONICS, 2024, 13 (21)
[40] Industrial strength genetic programming - Empirical modeling and symbolic regression via GP: Integrated methodologies, best practices, lessons learned
Kotanchek, M
Smits, G
Kordon, A
GENETIC PROGRAMMING THEORY AND PRACTICE, 2003, 6 : 239 - 255

← 1 2 3 4 5 →