NeurEPDiff: Neural Operators to Predict Geodesics in Deformation Spaces

Nian Wu, Miaomiao Zhang
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引用次数: 3

Abstract

This paper presents NeurEPDiff, a novel network to fast predict the geodesics in deformation spaces generated by a well known Euler-Poincar\'e differential equation (EPDiff). To achieve this, we develop a neural operator that for the first time learns the evolving trajectory of geodesic deformations parameterized in the tangent space of diffeomorphisms(a.k.a velocity fields). In contrast to previous methods that purely fit the training images, our proposed NeurEPDiff learns a nonlinear mapping function between the time-dependent velocity fields. A composition of integral operators and smooth activation functions is formulated in each layer of NeurEPDiff to effectively approximate such mappings. The fact that NeurEPDiff is able to rapidly provide the numerical solution of EPDiff (given any initial condition) results in a significantly reduced computational cost of geodesic shooting of diffeomorphisms in a high-dimensional image space. Additionally, the properties of discretiztion/resolution-invariant of NeurEPDiff make its performance generalizable to multiple image resolutions after being trained offline. We demonstrate the effectiveness of NeurEPDiff in registering two image datasets: 2D synthetic data and 3D brain resonance imaging (MRI). The registration accuracy and computational efficiency are compared with the state-of-the-art diffeomophic registration algorithms with geodesic shooting.
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预测变形空间测地线的神经算子
本文提出了一种新的神经网络NeurEPDiff,用于快速预测由欧拉-庞加莱微分方程(EPDiff)产生的变形空间中的测地线。为了实现这一点,我们开发了一个神经算子,该算子首次学习了在微分同态的切空间中参数化的测地线变形的演化轨迹。A速度场)。与以往单纯拟合训练图像的方法不同,我们提出的NeurEPDiff学习了随时间变化的速度场之间的非线性映射函数。在NeurEPDiff的每一层中建立了积分算子和光滑激活函数的组合,以有效地近似这种映射。NeurEPDiff能够快速提供EPDiff的数值解(给定任何初始条件),从而大大降低了高维图像空间中差分同态的测地拍摄的计算成本。此外,NeurEPDiff的离散化/分辨率不变性特性使其在离线训练后可以推广到多种图像分辨率。我们证明了NeurEPDiff在注册两个图像数据集方面的有效性:2D合成数据和3D脑磁共振成像(MRI)。并将其配准精度和计算效率与目前最先进的测地线射击差分配准算法进行了比较。
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