How many moments does MMD compare?
Abstract
We present a new way of study of Mercer kernels, by corresponding to a special kernel K a pseudo-differential operator p( x, D) such that F p( x, D) p( x, D) F-1 acts on smooth functions in the same way as an integral operator associated with K (where F is the Fourier transform). We show that kernels defined by pseudo-differential operators are able to approximate uniformly any continuous Mercer kernel on a compact set. The symbol p( x, y) encapsulates a lot of useful information about the structure of the Maximum Mean Discrepancy distance defined by the kernel K. We approximate p( x, y) with the sum of the first r terms of the Singular Value Decomposition of p, denoted by pr( x, y). If ordered singular values of the integral operator associated with p( x, y) die down rapidly, the MMD distance defined by the new symbol pr differs from the initial one only slightly. Moreover, the new MMD distance can be interpreted as an aggregated result of comparing r local moments of two probability distributions. The latter results holds under the condition that right singular vectors of the integral operator associated with p are uniformly bounded. But even if this is not satisfied we can still hold that the Hilbert-Schmidt distance between p and pr vanishes. Thus, we report an interesting phenomenon: the MMD distance measures the difference of two probability distributions with respect to a certain number of local moments, r, and this number r depends on the speed with which singular values of p die down.
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