A Finite-Element Model for the Mechanical Analysis of Skeletal Muscles

Skeletal muscles are the primary unit for the movement of the human body, they serve as shock absorber and protect the skeleton system against external loads. By maintaining a certain force level, muscle show fatigue effects, expressed by a decrease of the retentive force. To incorporate such effect

## Abstract In the present paper a new approach for the modelling of fatigue effects in skeletal muscle is proposed. This concept is micromechanically motivated. It incorporates the intramuscular connective tissue (passive part of the material) which surrounds the contractile muscle fibres (active

Vibration analysis of high speed and light weight mechanism systems must consider the mechanisms as elastic bodies in order to accurately predict their performance of specified functions. A general model to describe the elastic motion of a mechanism can be properly established with the use of standa

## Abstract A thermal model based on explicit time integration is developed and implemented into the explicit finite element code DYNA3D to model simultaneous forming and quenching of thin‐walled structures. A staggered approach is used for coupling the thermal and mechanical analysis, wherein each

A formulation for ®nite element plane strain limit analysis of rigidly perfectly plastic solids governed by von Mises' plasticity condition is presented. The approach is based on the kinematic theorem of limit analysis formulated as a minimum problem for a convex and non-smooth dissipation functiona

We present a numerical algorithm for the determination of muscle response by the ÿnite element method. Hill's three-element model is used as a basis for our analysis. The model consists of one linear elastic element, coupled in parallel with one non-linear elastic element, and one non-linear contrac