Discriminative latent variable models for visual recognition

Visual Recognition is a central problem in computer vision, and it has numerous potential applications in many dierent elds, such as robotics, human computer interaction, and entertainment. In this dissertation, we propose two discriminative latent variable models for handling challenging visual recognition problems. In particular, we use latent variables to capture and model various prior knowledge in the training data. In the rst model, we address the problem of recognizing human actions from still images. We jointly consider both poses and actions in a unied framework, and treat human poses as latent variables. The learning of this model follows the framework of latent SVM. Secondly, we propose another latent variable model to address the problem of automated tag learning on YouTube videos. In particular, we address the semantic variations (sub-tags) of the videos which have the same tag. In the model, each video is assumed to be associated with a sub-tag label, and we treat this sub-tag label as latent information. This model is trained using a latent learning framework based on LogitBoost, which jointly considers both the latent sub-tag label and the tag label. Moreover, we propose a novel discriminative latent learning framework, kernel latent SVM, which combines the benet of latent SVM and kernel methods. The framework of kernel latent SVM is general enough to be applied in many applications of visual recognition. It is also able to handle complex latent variables with interdependent structures using composite kernels

An Expressive Deep Model for Human Action Parsing from A Single Image

This paper aims at one newly raising task in vision and multimedia research: recognizing human actions from still images. Its main challenges lie in the large variations in human poses and appearances, as well as the lack of temporal motion information. Addressing these problems, we propose to develop an expressive deep model to naturally integrate human layout and surrounding contexts for higher level action understanding from still images. In particular, a Deep Belief Net is trained to fuse information from different noisy sources such as body part detection and object detection. To bridge the semantic gap, we used manually labeled data to greatly improve the effectiveness and efficiency of the pre-training and fine-tuning stages of the DBN training. The resulting framework is shown to be robust to sometimes unreliable inputs (e.g., imprecise detections of human parts and objects), and outperforms the state-of-the-art approaches.Comment: 6 pages, 8 figures, ICME 201

Expanded Parts Model for Semantic Description of Humans in Still Images

We introduce an Expanded Parts Model (EPM) for recognizing human attributes (e.g. young, short hair, wearing suit) and actions (e.g. running, jumping) in still images. An EPM is a collection of part templates which are learnt discriminatively to explain specific scale-space regions in the images (in human centric coordinates). This is in contrast to current models which consist of a relatively few (i.e. a mixture of) 'average' templates. EPM uses only a subset of the parts to score an image and scores the image sparsely in space, i.e. it ignores redundant and random background in an image. To learn our model, we propose an algorithm which automatically mines parts and learns corresponding discriminative templates together with their respective locations from a large number of candidate parts. We validate our method on three recent challenging datasets of human attributes and actions. We obtain convincing qualitative and state-of-the-art quantitative results on the three datasets.Comment: Accepted for publication in IEEE Transactions on Pattern Analysis and Machine Intelligence (TPAMI

Pose Embeddings: A Deep Architecture for Learning to Match Human Poses

We present a method for learning an embedding that places images of humans in similar poses nearby. This embedding can be used as a direct method of comparing images based on human pose, avoiding potential challenges of estimating body joint positions. Pose embedding learning is formulated under a triplet-based distance criterion. A deep architecture is used to allow learning of a representation capable of making distinctions between different poses. Experiments on human pose matching and retrieval from video data demonstrate the potential of the method