proximal deep structured model
Proximal Deep Structured Models
Many problems in real-world applications involve predicting continuous-valued random variables that are statistically related. In this paper, we propose a powerful deep structured model that is able to learn complex non-linear functions which encode the dependencies between continuous output variables. We show that inference in our model using proximal methods can be efficiently solved as a feed-foward pass of a special type of deep recurrent neural network. We demonstrate the effectiveness of our approach in the tasks of image denoising, depth refinement and optical flow estimation.
Reviews: Proximal Deep Structured Models
The paper makes a nice conceptual step of embedding proximal optimization algorithms in a deep neural network framework as an RNN. This conceptual move is new as far as I know. It is illuminating for me and I believe it will be found useful in further work. The immediate benefits are nice but not too significant: the new view enables a natural GPU implementation of proximal optimization methods, and bring small (close to insignificant) empirical result improvements. The week side of the paper is presentation quality: Some notation is used without definitions, central concepts (like the dual function) are used without definition, which makes the paper hard to read for people not very familiar with proximal methods.
Proximal Deep Structured Models
Many problems in real-world applications involve predicting continuous-valued random variables that are statistically related. In this paper, we propose a powerful deep structured model that is able to learn complex non-linear functions which encode the dependencies between continuous output variables. We show that inference in our model using proximal methods can be efficiently solved as a feedfoward pass of a special type of deep recurrent neural network. We demonstrate the effectiveness of our approach in the tasks of image denoising, depth refinement and optical flow estimation.
Proximal Deep Structured Models
Wang, Shenlong, Fidler, Sanja, Urtasun, Raquel
Many problems in real-world applications involve predicting continuous-valued random variables that are statistically related. In this paper, we propose a powerful deep structured model that is able to learn complex non-linear functions which encode the dependencies between continuous output variables. We show that inference in our model using proximal methods can be efficiently solved as a feed-foward pass of a special type of deep recurrent neural network. We demonstrate the effectiveness of our approach in the tasks of image denoising, depth refinement and optical flow estimation. Papers published at the Neural Information Processing Systems Conference.
Proximal Deep Structured Models
Wang, Shenlong, Fidler, Sanja, Urtasun, Raquel
Many problems in real-world applications involve predicting continuous-valued random variables that are statistically related. In this paper, we propose a powerful deep structured model that is able to learn complex non-linear functions which encode the dependencies between continuous output variables. We show that inference in our model using proximal methods can be efficiently solved as a feed-foward pass of a special type of deep recurrent neural network. We demonstrate the effectiveness of our approach in the tasks of image denoising, depth refinement and optical flow estimation.