Finite Element Applications

This is a hands-on textbook aimed at helping readers quickly master the Finite Element Modelling (FEM) process and start developing numerical solutions to real life problems

Cuts out a lot of the technical jargon associated with the FEM process, making the material accessible to both post-graduate students and graduate-level industry staff

Opens up the black box of finite element solver design - helping students learn the key steps required to develop their own finite element models and packages

Additional resources are published on the textbook's website, and include: user-defined material models (as Fortran codes), MATLAB scripts, model generation software, input files for case studies and their analysis

Written in an easy-to-follow style, focusing on helping students with developing their own FE models right from the first chapter

Autorentext

Dr. Michael Okereke is a Senior Lecturer in Engineering Mechanics at University of Greenwich, UK where he leads research in computational mechanics, impact engineering and constitutive model development for different engineering materials. He obtained his PhD from University of Oxford and has researched extensively on the impact behaviour and micromechanics of composite materials. He teaches both undergraduate and post-graduate engineering mechanics courses, with a specific focus on finite element modelling. He also collaborates with commercial organizations on use of computational mechanics to improve their product design, material modelling and manufacturing processes. Professor Simeon Keates is Deputy Pro Vice Chancellor of the Faculty of Engineering and Science at the University of Greenwich. He obtained his MA and PhD in Engineering from the University of Cambridge and continued his work there as an Industrial Research Fellow in the Engineering Design Centre.His research interests are primarily in design, simulation, optimisation and mathematical modeling.

Inhalt
Computational Mechanics.- A Brief Introduction to MATLAB.- Direct Stiffness Method.- Design of Simple Finite Element Modelling Solver.- Finite Element Modelling Principles.- Design of Virtual Domains.- Finite Element Meshes.- Boundary Conditions.- Material Response: Measures of Stress and Strain.- Material Response: Constitutive Models and their Implementation.- The Future of Finite Element Modelling.