Euler-Lagrange Elasticity: Differential Equations for Elasticity without Stress or Strain

Abstract

Differential equations to describe elasticity are derived without the use of stress or strain. The points within the body are the independent parameters instead of strain and surface forces replace stress tensors. These differential equations are a continuous analytical model that can then be solved using any of the standard techniques of differential equations. Although the equations do not require the definition stress or strain, these quantities can be calculated as dependent parameters. This approach to elasticity is simple, which avoids the need for multiple definitions of stress and strain, and provides a simple experimental procedure to find scalar representations of material properties in terms of the energy of deformation. The derived differential equations describe both infinitesimal and finite deformations.

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Hardy, H. (2013) Euler-Lagrange Elasticity: Differential Equations for Elasticity without Stress or Strain. Journal of Applied Mathematics and Physics, 1, 26-30. doi: 10.4236/jamp.2013.17004.

Conflicts of Interest

The authors declare no conflicts of interest.

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