3D Human Pose and Shape Estimation Based on Parametric Model and Deep Learning

3D human body reconstruction from monocular images has wide applications in our life, such as movie, animation, Virtual/Augmented Reality, medical research and so on. Due to the high freedom of human body in real scene and the ambiguity of inferring 3D objects from 2D images, it is a challenging task to accurately recover 3D human body models from images. In this thesis, we explore the methods for estimating 3D human body models from images based on parametric model and deep learning.In the first part, the coarse 3D human body models are estimated automatically from multi-view images based on a parametric human body model called SMPL model. Two routes are exploited for estimating the pose and shape parameters of the SMPL model to obtain the 3D models: (1) Optimization based methods; and (2) Deep learning based methods. For the optimization based methods, we propose the novel energy functions based on some prior information including the 2D joint points and silhouettes. Through minimizing the energy functions, the SMPL model is fitted to the prior information, and then, the coarse 3D human body is obtained. In addition to the traditional optimization based methods, a deep learning based method is also proposed in the following work to regress the pose and shape parameters of the SMPL model. A novel architecture is proposed to put the optimization into a training loop of convolutional neural network (CNN) to form a self-supervision structure based on the multi-view images. The proposed methods are evaluated on both synthetic and real datasets to demonstrate that they can obtain better estimation of the pose and shape of 3D human body than previous approaches.In the second part, the problem is shifted to the detailed 3D human body reconstruction from multi-view images. Instead of using the SMPL model, implicit function is utilized to represent 3D models because implicit representation can generate continuous surface and has better flexibility for arbitrary topology. Firstly, a multi-scale features based method is proposed to learn the implicit representation for 3D models through multi-stage hourglass networks from multi-view images. Furthermore, a coarse-to-fine method is proposed to refine the 3D models from multi-view images through learning the voxel super-resolution. In this method, the coarse 3D models are estimated firstly by the learned implicit function based on multi-scale features from multi-view images. Afterwards, by voxelizing the coarse 3D models to low resolution voxel grids, voxel super-resolution is learned through a multi-stage 3D CNN for feature extraction from low resolution voxel grids and fully connected neural network for predicting the implicit function. Voxel super-resolution is able to remove the false reconstruction and preserve the surface details. The proposed methods are evaluated on both real and synthetic datasets in which our method can estimate 3D model with higher accuracy and better surface quality than some previous methods

Diverse Priors for Deep Reinforcement Learning

In Reinforcement Learning (RL), agents aim at maximizing cumulative rewards in a given environment. During the learning process, RL agents face the dilemma of exploitation and exploration: leveraging existing knowledge to acquire rewards or seeking potentially higher ones. Using uncertainty as a guiding principle provides an active and effective approach to solving this dilemma and ensemble-based methods are one of the prominent avenues for quantifying uncertainty. Nevertheless, conventional ensemble-based uncertainty estimation lacks an explicit prior, deviating from Bayesian principles. Besides, this method requires diversity among members to generate less biased uncertainty estimation results. To address the above problems, previous research has incorporated random functions as priors. Building upon these foundational efforts, our work introduces an innovative approach with delicately designed prior NNs, which can incorporate maximal diversity in the initial value functions of RL. Our method has demonstrated superior performance compared with the random prior approaches in solving classic control problems and general exploration tasks, significantly improving sample efficiency.Comment: 8 pages, 4 figure

A novel joint points and silhouette-based method to estimate 3D human pose and shape

This paper presents a novel method for 3D human pose and shape estimation from images with sparse views, using joint points and silhouettes, based on a parametric model. Firstly, the parametric model is fitted to the joint points estimated by deep learning-based human pose estimation. Then, we extract the correspondence between the parametric model of pose fitting and silhouettes on 2D and 3D space. A novel energy function based on the correspondence is built and minimized to fit parametric model to the silhouettes. Our approach uses sufficient shape information because the energy function of silhouettes is built from both 2D and 3D space. This also means that our method only needs images from sparse views, which balances data used and the required prior information. Results on synthetic data and real data demonstrate the competitive performance of our approach on pose and shape estimation of the human body.Comment: Accepted to ICPR 2020 3DHU worksho

Concurrent Active Learning in Autonomous Airborne Source Search: Dual Control for Exploration and Exploitation

In this paper, a concurrent learning framework is developed for source search in an unknown environment using autonomous platforms equipped with onboard sensors. Distinct from the existing solutions that require significant computational power for Bayesian estimation and path planning, the proposed solution is computationally affordable for onboard processors. A new concept of concurrent learning using multiple parallel estimators is proposed to learn the operational environment and quantify estimation uncertainty. The search agent is empowered with dual capability of exploiting current estimated parameters to track the source and probing the environment to reduce the impacts of uncertainty, namely Concurrent Learning based Dual Control for Exploration and Exploitation (CL-DCEE). In this setting, the control action not only minimises the tracking error between future agent's position and estimated source location, but also the uncertainty of predicted estimation. More importantly, the rigorous proven properties such as the convergence of CL-DCEE algorithm are established under mild assumptions on noises, and the impact of noises on the search performance is examined. Simulation results are provided to validate the effectiveness of the proposed CL-DCEE algorithm. Compared with the information-theoretic approach, CL-DCEE not only guarantees convergence, but produces better search performance and consumes much less computational time

Model-Free Output Feedback Path Following Control for Autonomous Vehicle With Prescribed Performance Independent of Initial Conditions

Time-delay control (TDC) is widely recognized as a robust and straightforward model-free control approach for complex systems. However, the transient performance and settling time are often given less consideration in most TDC-based controllers. In this article, we propose an integrated control protocol that combines fixed-time prescribed performance control with time-delay estimation techniques for autonomous ground vehicles. The proposed control paradigm offers the advantages of being model-free while ensuring that the preview error converges to a neighborhood of zero within a fixed time, adhering to predefined constraint functions. To overcome the limitations of commonly used exponential decay boundaries, a prescribed performance function that remains independent of the initial conditions is employed. Furthermore, a high-order model-free fixed-time differentiator is constructed to observe the high-order dynamics of the preview error, which are essential for estimating unknown model dynamics. Finally, the simulations and practical experiments have been conducted to demonstrate the superiority of our proposed control protocol