Geometric Learning with Positively Decomposable Kernels
- URL: http://arxiv.org/abs/2310.13821v2
- Date: Tue, 30 Jul 2024 02:20:15 GMT
- Title: Geometric Learning with Positively Decomposable Kernels
- Authors: Nathael Da Costa, Cyrus Mostajeran, Juan-Pablo Ortega, Salem Said,
- Abstract summary: We propose the use of reproducing kernel Krein space (RKKS) based methods, which require only kernels that admit a positive decomposition.
We show that one does not need to access this decomposition in order to learn in RKKS.
- Score: 6.5497574505866885
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Kernel methods are powerful tools in machine learning. Classical kernel methods are based on positive-definite kernels, which map data spaces into reproducing kernel Hilbert spaces (RKHS). For non-Euclidean data spaces, positive-definite kernels are difficult to come by. In this case, we propose the use of reproducing kernel Krein space (RKKS) based methods, which require only kernels that admit a positive decomposition. We show that one does not need to access this decomposition in order to learn in RKKS. We then investigate the conditions under which a kernel is positively decomposable. We show that invariant kernels admit a positive decomposition on homogeneous spaces under tractable regularity assumptions. This makes them much easier to construct than positive-definite kernels, providing a route for learning with kernels for non-Euclidean data. By the same token, this provides theoretical foundations for RKKS-based methods in general.
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