Finite Element Method

Related lectures (32)

Page 1 of 4

Introduces the basics of finite element modeling for dynamics and discusses the Newmark method for time integration.

Covers the derivation of the equation of motion, interpolation, Newton's equation, and energy conservation in finite element modeling.

Covers the analysis of trusses, defining node positions, connectivity matrices, and stiffness matrices.

Covers advanced numerical analysis topics including deep neural networks and optimization methods.

Covers the isoparametric formulation of the Quad4 planar element and stiffness matrix calculation.

Covers gradient line search methods and optimization techniques with an emphasis on Wolfe conditions and positive definiteness.

Covers the fundamentals of finite element analysis, including traction and interpolation functions.

Covers data manipulation and exploration using Python with a focus on visualization techniques.

Covers the fundamentals of finite element analysis and the application of constitutive laws.

Covers optimization methods without constraints, including gradient and line search in the quadratic case.