Functional Currents: A New Mathematical Tool to Model and Analyse Functional Shapes

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Abstract

This paper introduces the concept of functional current as a mathematical framework to represent and treat functional shapes, i.e. submanifold-supported signals. It is motivated by the growing occurrence, in medical imaging and computational anatomy, of what can be described as geometrico-functional data, that is a data structure that involves a deformable shape (roughly a finite dimensional submanifold) together with a function defined on this shape taking values in another manifold. Whereas mathematical currents have already proved to be very efficient theoretically and numerically to model and process shapes as curves or surfaces, they are limited to the manipulation of purely geometrical objects. We show that the introduction of the concept of functional currents offers a genuine solution to the simultaneous processing of the geometric and signal information of any functional shape. We explain how functional currents can be equipped with a Hilbertian norm that successfully combines the geometrical and functional content of functional shapes under geometrical and functional perturbations, thus paving the way for various processing algorithms. We illustrate this potential on two problems: the redundancy reduction of functional shape representations through matching pursuit schemes on functional currents and the simultaneous geometric and functional registration of functional shapes under diffeomorphic transport.