AUTHOR=Piras Paolo , Profico Antonio , Pandolfi Luca , Raia Pasquale , Di Vincenzo Fabio , Mondanaro Alessandro , Castiglione Silvia , Varano Valerio 

TITLE=Current Options for Visualization of Local Deformation in Modern Shape Analysis Applied to Paleobiological Case Studies

JOURNAL=Frontiers in Earth Science

VOLUME=Volume 8 - 2020

YEAR=2020

URL=https://www.frontiersin.org/journals/earth-science/articles/10.3389/feart.2020.00066

DOI=10.3389/feart.2020.00066

ISSN=2296-6463

ABSTRACT=In modern shape analysis deformation is quantified in different ways depending on algorithms used and on the scale at which it is evaluated. While global affine and non-affine deformation components can be decoupled and computed using a variety of methods, the very local deformation can be considered, infinitesimally, as an affine deformation. The deformation gradient tensor F can be computed locally using a direct calculation by exploiting triangulation or tetrahedralization structures or by evaluating locally the first derivative of an appropriate interpolation function mapping the global deformation from the undeformed to the deformed state. A suitable function is represented by the Thin Plate Spline (TPS) that separates affine from non affine deformation components. F, also known as Jacobian, encodes both the locally affine deformation and local rotation. This implies that it should be used for visualizing Primary Strain Directions (PSD) and deformation ellipses and ellipsoids on the target configuration. Using C=FTF allows, instead, to compute PSD and to visualize them on the source configuration. Moreover, C allows the computation of the strain energy that can be evaluated and mapped locally at any point of a body using an interpolation function. In addition, it is possible, by exploiting the second order Jacobian, to calculate the amount of the non affine deformation in the neighborhood of the evaluation point by computing the body bending energy enclosed in the deformation. In this contribution, we present i) the main computational methods for evaluating local deformation metrics, ii) a number of different strategies to visualize them on both undeformed and deformed configurations and iii) the potential pitfalls in ignoring the actual three-dimensional nature of F when it is evaluated along a surface identified by a triangulation in three dimensions.