Green's-Function Spherical Neural Operators for Biological Heterogeneity
This work addresses the problem of handling biological heterogeneity in spherical data for researchers in fields like medical imaging and computational biology, representing a novel method for a known bottleneck.
The paper tackled the challenge of modeling real-world heterogeneity in spherical deep learning while retaining geometric inductive biases, and introduced the Green's-Function Spherical Neural Operator (GSNO) that demonstrated superiority in tasks like diffusion MRI fiber prediction and cortical parcellation.
Spherical deep learning has been widely applied to a broad range of real-world problems. Existing approaches often face challenges in balancing strong spherical geometric inductive biases with the need to model real-world heterogeneity. To solve this while retaining spherical geometry, we first introduce a designable Green's function framework (DGF) to provide new spherical operator solution strategy: Design systematic Green's functions under rotational group. Based on DGF, to model biological heterogeneity, we propose Green's-Function Spherical Neural Operator (GSNO) fusing 3 operator solutions: (1) Equivariant Solution derived from Equivariant Green's Function for symmetry-consistent modeling; (2) Invariant Solution derived from Invariant Green's Function to eliminate nuisance heterogeneity, e.g., consistent background field; (3) Anisotropic Solution derived from Anisotropic Green's Function to model anisotropic systems, especially fibers with preferred direction. Therefore, the resulting model, GSNO can adapt to real-world heterogeneous systems with nuisance variability and anisotropy while retaining spectral efficiency. Evaluations on spherical MNIST, Shallow Water Equation, diffusion MRI fiber prediction, cortical parcellation and molecule structure modeling demonstrate the superiority of GSNO.