It seems to be a pearl of conventional wisdom that parameter learning in deep sum-product networks is surprisingly fast compared to shallow mixture models. This paper examines the effects of overparameterization in sum-product networks on the speed of parameter optimisation. Using theoretical analysis and empirical experiments, we show that deep sum-product networks exhibit an implicit acceleration compared to their shallow counterpart. In fact, gradient-based optimisation in deep tree-structured sum-product networks is equal to gradient ascend with adaptive and time-varying learning rates and additional momentum terms
The sum-product network (SPN) is a recently-proposed deep model consisting of a network of sum and p...
The sum-product network (SPN) is a recently-proposed deep model consisting of a network of sum and p...
Sum-Product Networks (SPNs) and their credal counterparts are machine learning models that combine g...
We investigate the representational power of sum-product networks (computation networks analogous to...
Conventional wisdom in deep learning states that increasing depth improves expressiveness but compli...
Sum-product networks allow to model complex variable interactions while still granting efficient inf...
The need for feasible inference in Probabilistic Graphical Models (PGMs) has lead to tractable model...
In several domains obtaining class annotations is expensive while at the same time unlabelled data a...
The remarkable practical success of deep learning has revealed some major surprises from a theoretic...
Sum-product networks (SPNs) constitute an emerging class of neural networks with clear probabilistic...
Methods to speed up learning in back propagation and to optimize the network architecture have been ...
© 2020 National Academy of Sciences. All rights reserved. While deep learning is successful in a num...
© 5th International Conference on Learning Representations, ICLR 2017 - Workshop Track Proceedings. ...
Sum-product networks (SPNs) are expressive probabilistic models with a rich set of exact and efficie...
A main puzzle of deep networks revolves around the absence of overfitting despite overparametrizatio...
The sum-product network (SPN) is a recently-proposed deep model consisting of a network of sum and p...
The sum-product network (SPN) is a recently-proposed deep model consisting of a network of sum and p...
Sum-Product Networks (SPNs) and their credal counterparts are machine learning models that combine g...
We investigate the representational power of sum-product networks (computation networks analogous to...
Conventional wisdom in deep learning states that increasing depth improves expressiveness but compli...
Sum-product networks allow to model complex variable interactions while still granting efficient inf...
The need for feasible inference in Probabilistic Graphical Models (PGMs) has lead to tractable model...
In several domains obtaining class annotations is expensive while at the same time unlabelled data a...
The remarkable practical success of deep learning has revealed some major surprises from a theoretic...
Sum-product networks (SPNs) constitute an emerging class of neural networks with clear probabilistic...
Methods to speed up learning in back propagation and to optimize the network architecture have been ...
© 2020 National Academy of Sciences. All rights reserved. While deep learning is successful in a num...
© 5th International Conference on Learning Representations, ICLR 2017 - Workshop Track Proceedings. ...
Sum-product networks (SPNs) are expressive probabilistic models with a rich set of exact and efficie...
A main puzzle of deep networks revolves around the absence of overfitting despite overparametrizatio...
The sum-product network (SPN) is a recently-proposed deep model consisting of a network of sum and p...
The sum-product network (SPN) is a recently-proposed deep model consisting of a network of sum and p...
Sum-Product Networks (SPNs) and their credal counterparts are machine learning models that combine g...