HOG: Histogram of Goals for Human Pose Translation from Natural and Vision-based Visualizations


HOG: Histogram of Goals for Human Pose Translation from Natural and Vision-based Visualizations – While a great deal has been made of the fact that human gesture identification was a core goal of visual interfaces in recent centuries, it has been less explored due to lack of high-level semantic modeling for each gesture. In this paper, we address the problem of human gesture identification in text images. We present a method for the extraction of human gesture text via a visual dictionary. The word similarity map is presented to the visual dictionary, which is a sparse representation of human semantic semantic information. The proposed recognition method utilizes the deep convolutional neural network (CNN) to classify human gestures. Through this work we propose the deep CNN to recognize human gesture objects. Our method achieves recognition rate of up to 2.68% on the VisualFaces dataset, which is an impressive performance.

In this paper, we present a novel, scalable approach for extracting fuzzy representations from deep neural networks (DNNs), which can leverage state-of-the-art fuzzy feature extraction techniques to make their predictions in DNNs. In this work, we present a method that extracts fuzzy information from DNN features in order to achieve good accuracy. We train the fuzzy feature representation model to automatically infer the features of DNN features to be fuzzy. This algorithm makes use of the learned fuzzy feature representation model and discriminates the fuzzy features with a high probability. The performance of the fuzzy feature representation model has to be evaluated on real-world data from real-world object recognition and recognition tasks. The results show that the proposed method can be successfully used in practice for objects in both image and video.

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HOG: Histogram of Goals for Human Pose Translation from Natural and Vision-based Visualizations

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    Deep Learning Facial Typing Using Fuzzy Soft ThresholdsIn this paper, we present a novel, scalable approach for extracting fuzzy representations from deep neural networks (DNNs), which can leverage state-of-the-art fuzzy feature extraction techniques to make their predictions in DNNs. In this work, we present a method that extracts fuzzy information from DNN features in order to achieve good accuracy. We train the fuzzy feature representation model to automatically infer the features of DNN features to be fuzzy. This algorithm makes use of the learned fuzzy feature representation model and discriminates the fuzzy features with a high probability. The performance of the fuzzy feature representation model has to be evaluated on real-world data from real-world object recognition and recognition tasks. The results show that the proposed method can be successfully used in practice for objects in both image and video.


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