Finite Element Analysis of Structures Through Unified Formulation

A coupled global-local shell model with continuous interlaminar shear stresses, Solid-shell approach based on first-order or higher-order plate and shell theories for the finite element analysis of thin to very thick structures, Large deflection of composite beams by finite elements with node-dependent kinematics, Stress singularities and transverse stresses near edges of doubly curved laminated shells using TSNDT and stress recovery scheme, Cross-sectional mapping for refined beam elements with applications to shell-like structures, Layerwise mixed elements with node-dependent kinematics for global-local stress analysis of multilayered plates using high-order Legendre expansions, A hierarchical generalized formulation for the large-displacement dynamic analysis of rotating plates, Hybrid-mixed ANS finite elements for stress analysis of laminated composite structures: sampling surfaces plate formulation, Higher order theory of micropolar plates and shells, Higher order couple stress theory of plates and shells, Geometrically conforming and directionally enriched finite element method for three dimensional slender members, An improved coupling of 3D state‐based peridynamics with high‐order 1D finite elements to reduce spurious effects at interfaces, Finite elements based on Jacobi shape functions for the analysis of beams, plates and shells, Node-dependent kinematic models applied to reinforced concrete structures, Stochastic characterization of multiscale material uncertainties on the fibre-matrix interface stress state of composite variable stiffness plates, Quasi‐static fracture analysis by coupled three‐dimensional peridynamics and high order one‐dimensional finite elements based on local elasticity, Methods and guidelines for the choice of shell theories, Finite element models with node-dependent kinematics based on Legendre polynomials for the global-local analysis of compact and thin walled beams, 2‐D Analytical solutions for the multisegmented panel subjected to arbitrary boundary condition, Vibration suppression of thick plates with attached piezoelectric patches using 1D Carrera Unified Formulation (CUF) based finite element models, A geometrically nonlinear analysis through hierarchical one-dimensional modelling of sandwich beam structures, Geometrically nonlinear analysis and vibration of in-plane-loaded variable angle tow composite plates and shells, Carrera unified formulation (CUF) for shells of revolution. I: Higher-order theory, Carrera unified formulation (CUF) for the shells of revolution. II: Navier close form solutions, The tale of shear coefficients in Timoshenko-Ehrenfest beam theory: 130 years of progress, Convergence behaviour of inverse differential quadrature method for analysis of beam and plate structures, Unified theory of structures based on micropolar elasticity, Finite beam elements based on Legendre polynomial expansions and node-dependent kinematics for the global-local analysis of composite structures, Higher Order Theory of Electro-Magneto-Elastic Plates and Shells, A cubic spline layerwise spectral finite element for robust stress predictions in laminated composite and sandwich strips, Locking-free curved elements with refined kinematics for the analysis of composite structures, Equivalent-single-layer discontinuous Galerkin methods for static analysis of multilayered shells, Manufacturable insight into modelling and design considerations in fibre-steered composite laminates: state of the art and perspective, Non-conventional 1D and 2D finite elements based on CUF for the analysis of non-orthogonal geometries, Classical, higher-order, zig-zag and variable kinematic shell elements for the analysis of composite multilayered structures, Contact analysis of laminated structures including transverse shear and stretching, Static and dynamic analysis of two-layer Timoshenko composite beams by weak-form quadrature element method, Nonlocal Theory of Plates and Shells Based on Legendre’s Polynomial Expansion, Layer-wise dynamic analysis of a beam with global and local viscoelastic contributions using an FE/Laplace transform approach, A simple higher-order beam model that is represented by two kinematic variables and three section constants