Determining Point Process with Convolutional Kernel Networks Using the Dropout Method – Although there are many approaches to learning image models, most models focus on image labels for training purposes. In this paper, we propose to transfer learning of the image semantic labels to the training of the feature vectors into a novel learning framework, using the same label learning framework. We demonstrate several applications of our method using different data sets for different tasks: (i) a CNN with feature vectors of varying dimensionality, and (ii) a fully-convolutional network trained with a neural network. We compare our methods to the state-of-the-art image semantic labeling methods, including the recently proposed neural network or CNN learning in ImageNet and ResNet-15K and our method has outperformed them for both tasks. We conclude with a comparison of our network with many state-of-the-art CNN and ResNet-15K datasets.
In this paper, we develop a simple unsupervised framework for automatic classification based on the classification of high-dimensional features that is not constrained by the model parameters. Our method consists of a convolutional neural network and a recurrent encoder and decoder model. The recurrent encoder model is used for classification to maximize the sparse features and the dictionary decoder is learned to improve the sparse ones. The dictionary encoder model is used for classification by convolutional neural network (CNN) in order to estimate the sparse feature vector for each dimension of interest. A new CNN architecture is developed for the classification of high-dimensional features that is capable of learning the dictionary representations. Our method is tested with MNIST and CIFAR-10 datasets.
Towards a Machine Understanding Neuroscience: A Review
Determining Point Process with Convolutional Kernel Networks Using the Dropout Method
Highlighting spatiotemporal patterns in time series with CNNs
Robust Feature Selection with a Low Complexity LossIn this paper, we develop a simple unsupervised framework for automatic classification based on the classification of high-dimensional features that is not constrained by the model parameters. Our method consists of a convolutional neural network and a recurrent encoder and decoder model. The recurrent encoder model is used for classification to maximize the sparse features and the dictionary decoder is learned to improve the sparse ones. The dictionary encoder model is used for classification by convolutional neural network (CNN) in order to estimate the sparse feature vector for each dimension of interest. A new CNN architecture is developed for the classification of high-dimensional features that is capable of learning the dictionary representations. Our method is tested with MNIST and CIFAR-10 datasets.