Learning to Localize and Align Fine-Grained Actions to Sparse Instructions

Automatic generation of textual video descriptions that are time-aligned with video content is a long-standing goal in computer vision. The task is challenging due to the difficulty of bridging the semantic gap between the visual and natural language domains. This paper addresses the task of automatically generating an alignment between a set of instructions and a first person video demonstrating an activity. The sparse descriptions and ambiguity of written instructions create significant alignment challenges. The key to our approach is the use of egocentric cues to generate a concise set of action proposals, which are then matched to recipe steps using object recognition and computational linguistic techniques. We obtain promising results on both the Extended GTEA Gaze+ dataset and the Bristol Egocentric Object Interactions Dataset

The Evolution of First Person Vision Methods: A Survey

The emergence of new wearable technologies such as action cameras and smart-glasses has increased the interest of computer vision scientists in the First Person perspective. Nowadays, this field is attracting attention and investments of companies aiming to develop commercial devices with First Person Vision recording capabilities. Due to this interest, an increasing demand of methods to process these videos, possibly in real-time, is expected. Current approaches present a particular combinations of different image features and quantitative methods to accomplish specific objectives like object detection, activity recognition, user machine interaction and so on. This paper summarizes the evolution of the state of the art in First Person Vision video analysis between 1997 and 2014, highlighting, among others, most commonly used features, methods, challenges and opportunities within the field.Comment: First Person Vision, Egocentric Vision, Wearable Devices, Smart Glasses, Computer Vision, Video Analytics, Human-machine Interactio

Forecasting Human-Object Interaction: Joint Prediction of Motor Attention and Actions in First Person Video

We address the challenging task of anticipating human-object interaction in first person videos. Most existing methods ignore how the camera wearer interacts with the objects, or simply consider body motion as a separate modality. In contrast, we observe that the international hand movement reveals critical information about the future activity. Motivated by this, we adopt intentional hand movement as a future representation and propose a novel deep network that jointly models and predicts the egocentric hand motion, interaction hotspots and future action. Specifically, we consider the future hand motion as the motor attention, and model this attention using latent variables in our deep model. The predicted motor attention is further used to characterise the discriminative spatial-temporal visual features for predicting actions and interaction hotspots. We present extensive experiments demonstrating the benefit of the proposed joint model. Importantly, our model produces new state-of-the-art results for action anticipation on both EGTEA Gaze+ and the EPIC-Kitchens datasets. Our project page is available at https://aptx4869lm.github.io/ForecastingHOI

HUMAN ACTIVITY RECOGNITION FROM EGOCENTRIC VIDEOS AND ROBUSTNESS ANALYSIS OF DEEP NEURAL NETWORKS

In recent years, there has been significant amount of research work on human activity classification relying either on Inertial Measurement Unit (IMU) data or data from static cameras providing a third-person view. There has been relatively less work using wearable cameras, providing egocentric view, which is a first-person view providing the view of the environment as seen by the wearer. Using only IMU data limits the variety and complexity of the activities that can be detected. Deep machine learning has achieved great success in image and video processing in recent years. Neural network based models provide improved accuracy in multiple fields in computer vision. However, there has been relatively less work focusing on designing specific models to improve the performance of egocentric image/video tasks. As deep neural networks keep improving the accuracy in computer vision tasks, the robustness and resilience of the networks should be improved as well to make it possible to be applied in safety-crucial areas such as autonomous driving. Motivated by these considerations, in the first part of the thesis, the problem of human activity detection and classification from egocentric cameras is addressed. First, anew method is presented to count the number of footsteps and compute the total traveled distance by using the data from the IMU sensors and camera of a smart phone. By incorporating data from multiple sensor modalities, and calculating the length of each step, instead of using preset stride lengths and assuming equal-length steps, the proposed method provides much higher accuracy compared to commercially available step counting apps. After the application of footstep counting, more complicated human activities, such as steps of preparing a recipe and sitting on a sofa, are taken into consideration. Multiple classification methods, non-deep learning and deep-learning-based, are presented, which employ both ego-centric camera and IMU data. Then, a Genetic Algorithm-based approach is employed to set the parameters of an activity classification network autonomously and performance is compared with empirically-set parameters. Then, a new framework is introduced to reduce the computational cost of human temporal activity recognition from egocentric videos while maintaining the accuracy at a comparable level. The actor-critic model of reinforcement learning is applied to optical flow data to locate a bounding box around region of interest, which is then used for clipping a sub-image from a video frame. A shallow and deeper 3D convolutional neural network is designed to process the original image and the clipped image region, respectively.Next, a systematic method is introduced that autonomously and simultaneously optimizes multiple parameters of any deep neural network by using a bi-generative adversarial network (Bi-GAN) guiding a genetic algorithm(GA). The proposed Bi-GAN allows the autonomous exploitation and choice of the number of neurons for the fully-connected layers, and number of filters for the convolutional layers, from a large range of values. The Bi-GAN involves two generators, and two different models compete and improve each other progressively with a GAN-based strategy to optimize the networks during a GA evolution.In this analysis, three different neural network layers and datasets are taken into consideration: First, 3D convolutional layers for ModelNet40 dataset. We applied the proposed approach on a 3D convolutional network by using the ModelNet40 dataset. ModelNet is a dataset of 3D point clouds. The goal is to perform shape classification over 40shape classes. LSTM layers for UCI HAR dataset. UCI HAR dataset is composed of InertialMeasurement Unit (IMU) data captured during activities of standing, sitting, laying, walking, walking upstairs and walking downstairs. These activities were performed by 30 subjects, and the 3-axial linear acceleration and 3-axial angular velocity were collected at a constant rate of 50Hz. 2D convolutional layers for Chars74k Dataset. Chars74k dataset contains 64 classes(0-9, A-Z, a-z), 7705 characters obtained from natural images, 3410 hand-drawn characters using a tablet PC and 62992 synthesised characters from computer fonts giving a total of over 74K images. In the final part of the thesis, network robustness and resilience for neural network models is investigated from adversarial examples (AEs) and automatic driving conditions. The transferability of adversarial examples across a wide range of real-world computer vision tasks, including image classification, explicit content detection, optical character recognition(OCR), and object detection are investigated. It represents the cybercriminal’s situation where an ensemble of different detection mechanisms need to be evaded all at once.Novel dispersion Reduction(DR) attack is designed, which is a practical attack that overcomes existing attacks’ limitation of requiring task-specific loss functions by targeting on the “dispersion” of internal feature map. In the autonomous driving scenario, the adversarial machine learning attacks against the complete visual perception pipeline in autonomous driving is studied. A novel attack technique, tracker hijacking, that can effectively fool Multi-Object Tracking (MOT) using AEs on object detection is presented. Using this technique, successful AEs on as few as one single frame can move an existing object in to or out of the headway of an autonomous vehicle to cause potential safety hazards

Hierarchical Hidden Markov Model in Detecting Activities of Daily Living in Wearable Videos for Studies of Dementia

International audienceThis paper presents a method for indexing activities of daily living in videos obtained from wearable cameras. In the context of dementia diagnosis by doctors, the videos are recorded at patients' houses and later visualized by the medical practitioners. The videos may last up to two hours, therefore a tool for an efficient navigation in terms of activities of interest is crucial for the doctors. The specific recording mode provides video data which are really difficult, being a single sequence shot where strong motion and sharp lighting changes often appear. Our work introduces an automatic motion based segmentation of the video and a video structuring approach in terms of activities by a hierarchical two-level Hidden Markov Model. We define our description space over motion and visual characteristics of video and audio channels. Experiments on real data obtained from the recording at home of several patients show the difficulty of the task and the promising results of our approach