@Article{icces.2023.09689,
AUTHOR = {Mingjing Li, Leiting Dong, Satya N. Atluri},
TITLE = {Fragile Points Method for Modeling Complex Structural Failure},
JOURNAL = {The International Conference on Computational \& Experimental Engineering and Sciences},
VOLUME = {27},
YEAR = {2023},
NUMBER = {4},
PAGES = {1--2},
URL = {http://www.techscience.com/icces/v27n4/55208},
ISSN = {1933-2815},
ABSTRACT = {The Fragile Points Method (FPM) is a discontinuous meshless method based on the Galerkin weak form [1]. 
In the FPM, the problem domain is discretized by spatial points and subdomains, and the displacement trial 
function of each subdomain is derived based on the points within the support domain. For this reason, the 
FPM doesn’t suffer from the mesh distortion and is suitable to model complex structural deformations. 
Furthermore, similar to the discontinuous Galerkin finite element method, the displacement trial functions 
used in the FPM is piece-wise continuous, and the numerical flux is introduced across each interior interface 
to guarantee the consistency of the method. For this reason, it is convenient to explicitly introduce crack 
across any interior interface in an FPM model, and this method is suitable to model complex structural 
failure [2]. It is also worth mentioning that, the FPM is stable since its formulations is based on Galerkin 
weak form, and simple polynomial trial functions can be used in the FPM since the displacement is not 
strongly enforced to be continuous between subdomains. The authors’ group has already derived the static 
and dynamic weak form formulations of the FPM, proposed an interface debonding model based on the 
numerical flux, and implemented an implicit static and an explicit dynamic FPM code. This presentation 
starts with an introduction on the theory and implementation of the FPM. Then the FPM results on three 
structural failure examples are discussed including the fracture of U-notched specimens with brittle 
materials [3], the coupled inter- and intra-ply damage of composite laminates, and the dynamic fracture of 
brittle materials. The examples show that the proposed FPM approaches are able to reliably predict static 
and dynamic fracture behaviors, and this method has potential to serve as a powerful tool for modeling 
complex structural failure in engineering fields.},
DOI = {10.32604/icces.2023.09689}
}