Generalized-CVO: Fast and Correspondence-Free Point Cloud Registration in RKHS with Second Order Riemannian Optimization

We propose a fast and correspondence-free point cloud registration method that leverages local geometric surface structure and reproducing kernel Hilbert space (RKHS) embeddings. The proposed method represents point clouds as continuous functions with point-wise anisotropic kernels that encode local geometry. This formulation improves alignment along surface normals while relaxing alignment along tangential directions. To solve the resulting registration problem, we propose a second-order on-manifold optimization scheme with approximate Riemannian Hessians, achieving a speedup of up to 10x over the first-order methods used in prior correspondence-free RKHS-based methods. We demonstrate improved frame-to-frame LiDAR and RGB-D tracking accuracy across diverse indoor and outdoor datasets. On a LiDAR registration task in the driving domain, we achieve a reduction of $>55\%$ in both translational and rotational drift in challenging feature-sparse environments.