Add to ORKGAbstract—This paper presents a novel Riemannian framework for shape analysis of parameterized surfaces. In particular, it provides efficient algorithms for computing geodesic paths which, in turn, are important for comparing, matching, and deforming surfaces. The novelty of this framework is that geodesics are invariant to the parameterizations of surfaces and other shape-preserving transformations of surfaces. The basic idea is to formulate a space of embedded surfaces (surfaces seen as embeddings of a unit sphere in R3) and impose a Riemannian metric on it in such a way that the re-parameterization group acts on this space by isometries. Under this framework, we solve two optimization problems. One, given any two surfaces at arbitrary rot...
We develop a computational model of shape that extends existing Riemannian models of curves to multi...
In elastic shape analysis, a representation of a shape is invariant to translation, scaling, rotatio...
Figure 1: Geodesic interpolation and extrapolation. The blue input poses of the elephant are geodesi...
International audienceThis paper describes a novel framework for computing geodesic paths in shape ...
We argue that full surface correspondence (registration) and optimal deformations (geodesics) are tw...
Abstract. In order to analyze shapes of continuous curves in R3, we parameterize them by arc-length ...
Abstract—In the framework of elastic shape analysis, a shape is invariant to scaling, translation, r...
Abstract. In order to analyze shapes of continuous curves in R3, we parameterize them by arc-length ...
We propose an efficient representation for studying shapes of closed curves in Rn. This paper combin...
We describe two Riemannian frameworks for statistical shape analysis of parameterized surfaces. Thes...
Abstract. This paper studies a specific metric on plane curves that has the property of being isomet...
Abstract—Current techniques for shape analysis tend to seek invariance to similarity transformations...
In this article, we introduce a family of elastic metrics on the space of parametrized surfaces in 3...
International audienceWe construct shape spaces of elastic spherical surfaces immersed in Euclidean ...
This paper illustrates and extends an efficient framework, called the square-root-elastic (SRE) fram...
We develop a computational model of shape that extends existing Riemannian models of curves to multi...
In elastic shape analysis, a representation of a shape is invariant to translation, scaling, rotatio...
Figure 1: Geodesic interpolation and extrapolation. The blue input poses of the elephant are geodesi...
International audienceThis paper describes a novel framework for computing geodesic paths in shape ...
We argue that full surface correspondence (registration) and optimal deformations (geodesics) are tw...
Abstract. In order to analyze shapes of continuous curves in R3, we parameterize them by arc-length ...
Abstract—In the framework of elastic shape analysis, a shape is invariant to scaling, translation, r...
Abstract. In order to analyze shapes of continuous curves in R3, we parameterize them by arc-length ...
We propose an efficient representation for studying shapes of closed curves in Rn. This paper combin...
We describe two Riemannian frameworks for statistical shape analysis of parameterized surfaces. Thes...
Abstract. This paper studies a specific metric on plane curves that has the property of being isomet...
Abstract—Current techniques for shape analysis tend to seek invariance to similarity transformations...
In this article, we introduce a family of elastic metrics on the space of parametrized surfaces in 3...
International audienceWe construct shape spaces of elastic spherical surfaces immersed in Euclidean ...
This paper illustrates and extends an efficient framework, called the square-root-elastic (SRE) fram...
We develop a computational model of shape that extends existing Riemannian models of curves to multi...
In elastic shape analysis, a representation of a shape is invariant to translation, scaling, rotatio...
Figure 1: Geodesic interpolation and extrapolation. The blue input poses of the elephant are geodesi...