1,462 research outputs found
A Survey on Bayesian Deep Learning
A comprehensive artificial intelligence system needs to not only perceive the
environment with different `senses' (e.g., seeing and hearing) but also infer
the world's conditional (or even causal) relations and corresponding
uncertainty. The past decade has seen major advances in many perception tasks
such as visual object recognition and speech recognition using deep learning
models. For higher-level inference, however, probabilistic graphical models
with their Bayesian nature are still more powerful and flexible. In recent
years, Bayesian deep learning has emerged as a unified probabilistic framework
to tightly integrate deep learning and Bayesian models. In this general
framework, the perception of text or images using deep learning can boost the
performance of higher-level inference and in turn, the feedback from the
inference process is able to enhance the perception of text or images. This
survey provides a comprehensive introduction to Bayesian deep learning and
reviews its recent applications on recommender systems, topic models, control,
etc. Besides, we also discuss the relationship and differences between Bayesian
deep learning and other related topics such as Bayesian treatment of neural
networks.Comment: To appear in ACM Computing Surveys (CSUR) 202
Neural Likelihoods via Cumulative Distribution Functions
We leverage neural networks as universal approximators of monotonic functions
to build a parameterization of conditional cumulative distribution functions
(CDFs). By the application of automatic differentiation with respect to
response variables and then to parameters of this CDF representation, we are
able to build black box CDF and density estimators. A suite of families is
introduced as alternative constructions for the multivariate case. At one
extreme, the simplest construction is a competitive density estimator against
state-of-the-art deep learning methods, although it does not provide an easily
computable representation of multivariate CDFs. At the other extreme, we have a
flexible construction from which multivariate CDF evaluations and
marginalizations can be obtained by a simple forward pass in a deep neural net,
but where the computation of the likelihood scales exponentially with
dimensionality. Alternatives in between the extremes are discussed. We evaluate
the different representations empirically on a variety of tasks involving tail
area probabilities, tail dependence and (partial) density estimation.Comment: 10 page
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