Inverse Problems Over Probability Measure Space
Abstract
Define a forward problem as y = G\#x, where the probability distribution x is mapped to another distribution y using the forward operator G. In this work, we investigate the corresponding inverse problem: Given y, how to find x? Depending on whether G is overdetermined or underdetermined, the solution can have drastically different behavior. In the overdetermined case, we formulate a variational problem _x D( G\#x, y), and find that different choices of the metric D significantly affect the quality of the reconstruction. When D is set to be the Wasserstein distance, the reconstruction is the marginal distribution, while setting D to be a φ-divergence reconstructs the conditional distribution. In the underdetermined case, we formulate the constrained optimization \ G\#x=y\ E[x]. The choice of E also significantly impacts the construction: setting E to be the entropy gives us the piecewise constant reconstruction, while setting E to be the second moment, we recover the classical least-norm solution. We also examine the formulation with regularization: _x D( G\#x, y) + α R[x], and find that the entropy-entropy pair leads to a regularized solution that is defined in a piecewise manner, whereas the W2-W2 pair leads to a least-norm solution where W2 is the 2-Wasserstein metric.
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