A simple and practical representation of compatibility condition derived using a \textbf{QR} decomposition of the deformation gradient
From MaRDI portal
Publication:2194395
DOI10.1007/S00707-020-02702-XzbMath1440.74005OpenAlexW3035475551MaRDI QIDQ2194395
Sandipan Paul, Alan David Freed
Publication date: 25 August 2020
Published in: Acta Mechanica (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/s00707-020-02702-x
Related Items (3)
A note on the derivation of quotient rules and their use in \textbf{QR} kinematics ⋮ Laplace stretch: Eulerian and Lagrangian formulations ⋮ Characterizing geometrically necessary dislocations using an elastic-plastic decomposition of Laplace stretch
Cites Work
- Unnamed Item
- Unnamed Item
- Logarithmic strain and its material derivative for a QR decomposition of the deformation gradient
- Intrinsic methods in elasticity: a mathematical survey
- Ordinary differential equations of non-linear elasticity. I: Foundations of the theories of non-linearly elastic rods and shells
- On compatibility conditions for the left Cauchy-Green deformation field in three dimensions
- On the use of convected coordinate systems in the mechanics of continuous media derived from a \(\mathbf{QR}\) factorization of \textsf{F}
- On the use of the upper triangular (or QR) decomposition for developing constitutive equations for Green-elastic materials
- Compatibility conditions for a left Cauchy-Green strain field
- A decomposition of Laplace stretch with applications in inelasticity
- On the determination of deformation from strain
- Compatibility equations of nonlinear elasticity for non-simply-connected bodies
- On some types of topological groups
- Differential Geometry and Kinematics of Continua
- Gram-Schmidt orthogonalization: 100 years and more
- The Rotation Associated with Large Strains
- Fourth-order tensors – tensor differentiation with applications to continuum mechanics. Part I: Classical tensor analysis
This page was built for publication: A simple and practical representation of compatibility condition derived using a \textbf{QR} decomposition of the deformation gradient
