In deformable registration, the geometric framework - large deformation diffeomorphic metric mapping or LDDMM, in short - has inspired numerous techniques for comparing, deforming, averaging and analyzing shapes or images. Grounded in flows, which are akin to the equations of motion used in fluid dynamics, LDDMM algorithms solve the flow equation in the space of plausible deformations, i.e. diffeomorphisms. In this work, we make use of deep residual neural networks to solve the non-stationary ODE (flow equation) based on a Euler's discretization scheme. The central idea is to represent time-dependent velocity fields as fully connected ReLU neural networks (building blocks) and derive optimal weights by minimizing a regularized loss function. Computing minimizing paths between deformations, thus between shapes, turns to find optimal network parameters by back-propagating over the intermediate building blocks. Geometrically, at each time step, ResNet-LDDMM searches for an optimal partition of the space into multiple polytopes, and then computes optimal velocity vectors as affine transformations on each of these polytopes. As a result, different parts of the shape, even if they are close (such as two fingers of a hand), can be made to belong to different polytopes, and therefore be moved in different directions without costing too much energy. Importantly, we show how diffeomorphic transformations, or more precisely bilipshitz transformations, are predicted by our algorithm. We illustrate these ideas on diverse registration problems of 3D shapes under complex topology-preserving transformations. We thus provide essential foundations for more advanced shape variability analysis under a novel joint geometric-neural networks Riemannian-like framework, i.e. ResNet-LDDMM.
翻译:在变形登记中,几何框架 — 巨大的变形变异性伸缩度图或LDDMM, 简言之, 催化了许多比较、变形、平均和分析形状或图像的技术。 以流为基点, 与流体动态中使用的运动方程式相似, LDDMM 算法解决了表面变形空间的流方程, 即二度变形。 在这项工作中, 我们利用深层残余神经网络网络, 解决以 Euler 离散方案为基础的非静止的变异( 流方程式 ) 。 中心理念是代表完全连接的 ReLU 神经网络( 构建区块) 的基于时间的变异速度字段, 并通过尽量减少正常化损失功能获得最佳的权重。 计算变异形之间的路径, 也就是通过对中间建筑区块进行回换, 以找到最佳的网络参数。 我们的几何步骤, RENet- LDDMMM 搜索, 通过对空间进行最佳的分解, 然后对基于多个多面的变形的变形, 等的变形结构进行更精确的变形分析, 。