New exact and numerical solutions of the (convection–)diffusion kernels on SE(3)

Portegies, JM Jorg; Duits, Remco

doi:10.1016/j.difgeo.2017.06.004

Cited by 7 publications

(41 citation statements)

References 42 publications

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“…Furthermore, modifications of our total variation seminorm that take into account the coupling of positions and orientations according to the physical interpretation of ODFs in DW-MRI could close the gap to state-of-the-art approaches such as [28,63].…”

Section: Discussionmentioning

confidence: 99%

“…This approach has been used to enhance the quality of CSD as a prior in a variational formulation [67] or in a post-processing step [64] that also includes additional angular regularization. Due to the linearity of the underlying linear PDE, convolution-based explicit solution formulas are available [28,63]. Implemented efficiently [55,54], they outperform our more computationally demanding model, which is not tied to the specific application of DW-MRI, but allows arbitrary metric spaces.…”

Section: Regularization Of Dw-mri By Linear Diffusionmentioning

confidence: 99%

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Measure-Valued Variational Models with Applications to Diffusion-Weighted Imaging

Vogt

Lellmann

2018

J Math Imaging Vis

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We develop a general mathematical framework for variational problems where the unknown function takes values in the space of probability measures on some metric space. We study weak and strong topologies and define a total variation seminorm for functions taking values in a Banach space. The seminorm penalizes jumps and is rotationally invariant under certain conditions. We prove existence of a minimizer for a class of variational problems based on this formulation of total variation, and provide an example where uniqueness fails to hold. Employing the Kantorovich-Rubinstein transport norm from the theory of optimal transport, we propose a variational approach for the restoration of orientation distribution function (ODF)-valued images, as commonly used in Diffusion MRI. We demonstrate that the approach is numerically feasible on several data sets.

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Section: Discussionmentioning

confidence: 99%

Section: Regularization Of Dw-mri By Linear Diffusionmentioning

confidence: 99%

Measure-Valued Variational Models with Applications to Diffusion-Weighted Imaging

Vogt

Lellmann

2018

J Math Imaging Vis

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“…For {a, b} = {0, 1} we have a Total Variation Flow (TVF) [8]. For {a, b} = {0, 0} we obtain a linear diffusion for which exact smooth solutions exist [27]. Remark 1.…”

Section: Total-roto Translation Variation Mean Curvature Flows On Mmentioning

confidence: 99%

Total Variation and Mean Curvature PDEs on the Space of Positions and Orientations

Duits

St-Onge²,

Portegies

et al. 2019

Lecture Notes in Computer Science

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Total variation regularization and total variation flows (TVF) have been widely applied for image enhancement and denoising. To include a generic preservation of crossing curvilinear structures in TVF we lift images to the homogeneous space M = R d S d−1 of positions and orientations as a Lie group quotient in SE(d). For d = 2 this is called 'total roto-translation variation' by Chambolle & Pock. We extend this to d = 3, by a PDE-approach with a limiting procedure for which we prove convergence. We also include a Mean Curvature Flow (MCF) in our PDE model on M. This was first proposed for d = 2 by Citti et al. and we extend this to d = 3. Furthermore, for d = 2 we take advantage of locally optimal differential frames in invertible orientation scores (OS). We apply our TVF and MCF in the denoising/enhancement of crossing fiber bundles in DW-MRI. In comparison to data-driven diffusions, we see a better preservation of bundle boundaries and angular sharpness in fiber orientation densities at crossings. We support this by error comparisons on a noisy DW-MRI phantom. We also apply our TVF and MCF in enhancement of crossing elongated structures in 2D images via OS, and compare the results to nonlinear diffusions (CED-OS) via OS.

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“…We reason that the Folland-Kaplan-Korányi provides an accurate approximation to the fundamental solution on SE(n) as well, as it provides the exact fundamental solution on the Heisenberg type approximation (SE(n)) 0 . As such, we provide an approach to approximating the heat kernel and fundamental solution of the sub-Laplacian on SE(n), as an alternative to the works [22,47,12].…”

Section: Nilpotent Approximationmentioning

confidence: 99%

“…Also here, the Folland-Kaplan-Korányi-type norm can be used to approximate the fundamental solutions of the sub-Laplacian on SE(3). The norm ||c|| ξ,ζ with ζ = 1 was for example used in [23] approximations of the heat kernel and the fundamental solution on SE(3), of which only recently exact solutions were found in [47]. In the context of this paper, we can approximate the exact solutions of the sub-Laplacian on SE(3) by c 2−Q 1,16 , with homogeneous dimensions Q = 9, as the exact solution of the sub-Laplacian on the approximation group (SE(3)) 0 .…”

Section: A Nilpotent Approximation (Se(3)) 0 Of Se(3) and The Approximentioning

confidence: 99%

Nilpotent Approximations of Sub-Riemannian Distances for Fast Perceptual Grouping of Blood Vessels in 2D and 3D

2018

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We propose an efficient approach for the grouping of local orientations (points on vessels) via nilpotent approximations of sub-Riemannian distances in the 2D and 3D roto-translation groups SE(2) and SE(3). In our distance approximations we consider homogeneous norms on nilpotent groups that locally approximate SE(n), and which are obtained via the exponential and logarithmic map on SE(n). In a qualitative validation we show that the norms provide accurate approximations of the true sub-Riemannian distances, and we discuss their relations to the fundamental solution of the sub-Laplacian on SE(n). The quantitative experiments further confirm the accuracy of the approximations. Quantitative results are obtained by evaluating perceptual grouping performance of retinal blood vessels in 2D images and curves in challenging 3D synthetic volumes. The results show that (1) sub-Riemannian geometry is essential in achieving top performance and (2) grouping via the fast analytic approximations performs almost equally, or better, than data-adaptive fast marching approaches on R n and SE(n).

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New exact and numerical solutions of the (convection–)diffusion kernels on SE(3)

Cited by 7 publications

References 42 publications

Measure-Valued Variational Models with Applications to Diffusion-Weighted Imaging

Measure-Valued Variational Models with Applications to Diffusion-Weighted Imaging

Total Variation and Mean Curvature PDEs on the Space of Positions and Orientations

Nilpotent Approximations of Sub-Riemannian Distances for Fast Perceptual Grouping of Blood Vessels in 2D and 3D

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