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arxiv 1810.03256 v2 pith:LIBDRFR5 submitted 2018-10-08 stat.ML cs.LG

Deep Diffeomorphic Normalizing Flows

classification stat.ML cs.LG
keywords flowdensitydiffeomorphicestimationnetworkneuralnormalizingsmooth
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The Normalizing Flow (NF) models a general probability density by estimating an invertible transformation applied on samples drawn from a known distribution. We introduce a new type of NF, called Deep Diffeomorphic Normalizing Flow (DDNF). A diffeomorphic flow is an invertible function where both the function and its inverse are smooth. We construct the flow using an ordinary differential equation (ODE) governed by a time-varying smooth vector field. We use a neural network to parametrize the smooth vector field and a recursive neural network (RNN) for approximating the solution of the ODE. Each cell in the RNN is a residual network implementing one Euler integration step. The architecture of our flow enables efficient likelihood evaluation, straightforward flow inversion, and results in highly flexible density estimation. An end-to-end trained DDNF achieves competitive results with state-of-the-art methods on a suite of density estimation and variational inference tasks. Finally, our method brings concepts from Riemannian geometry that, we believe, can open a new research direction for neural density estimation.

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