Size-dependent bending and buckling of two-dimensional functionally graded microplates, an artificial neural network approach

Abstract: The main goal of the present study is to focus on the application of artificial neural network (ANN) in predicting the bending and buckling behaviors of size-dependent small-scale micro-plates. To this end, the recently introduced thick microplates made of two-dimensional functionally graded materials (2D-FGM) with simply supported boundary conditions are considered. Adopting the modified couple stress and third-order shear deformation theories together with the Ritz method, the bending and buckling ANN models… Show more

“…Experimental and numerical results show that a uniform distribution of nanofibers leads to a moderate effect on the mechanical properties of the composite due to the creation of a weak interface between fiber and matrix [1,2]. To overcome this shortcoming, functionally graded (FG) patterns have been proposed for nanofiber distributions in the matrix [3,4]. Shen and Xiang [5] investigated the nonlinear vibration of FG CNTRC shells and studied the thermal effects.…”

Nonlocal strain gradient-based nonlinear vibration analysis of nonlinear FG three-phase HJCNT/MWCNT/epoxy composite microbeam resonators using a modified micromechanical model

“…Experimental and numerical results show that a uniform distribution of nanofibers leads to a moderate effect on the mechanical properties of the composite due to the creation of a weak interface between fiber and matrix [1,2]. To overcome this shortcoming, functionally graded (FG) patterns have been proposed for nanofiber distributions in the matrix [3,4]. Shen and Xiang [5] investigated the nonlinear vibration of FG CNTRC shells and studied the thermal effects.…”

Nonlocal strain gradient-based nonlinear vibration analysis of nonlinear FG three-phase HJCNT/MWCNT/epoxy composite microbeam resonators using a modified micromechanical model

A machine learning approach for buckling analysis of a bi-directional FG microbeam

Size-dependent vibration analysis of porous 3D-FG microshells in complex thermal environments using a neural network enhanced finite element model