27 results
(View BibTeX file of all listed publications)
2024
Leveraging Unpaired Data for the Creation of Controllable Digital Humans
Max Planck Institute for Intelligent Systems and Eberhard Karls Universität Tübingen, September 2024 (phdthesis) To be published
Digital humans have grown increasingly popular, offering transformative potential across various fields such as education, entertainment, and healthcare. They enrich user experiences by providing immersive and personalized interactions. Enhancing these experiences involves making digital humans controllable, allowing for manipulation of aspects like pose and appearance, among others. Learning to create such controllable digital humans necessitates extensive data from diverse sources. This includes 2D human images alongside their corresponding 3D geometry and texture, 2D images showcasing similar appearances across a wide range of body poses, etc., for effective control over pose and appearance. However, the availability of such “paired data” is limited, making its collection both time-consuming and expensive. Despite these challenges, there is an abundance of unpaired 2D images with accessible, inexpensive labels—such as identity, type of clothing, appearance of clothing, etc. This thesis capitalizes on these affordable labels, employing informed observations from “unpaired data” to facilitate the learning of controllable digital humans through reconstruction, transposition, and generation processes. The presented methods—RingNet, SPICE, and SCULPT—each tackles different aspects of controllable digital human modeling. RingNet (Sanyal et al. [2019]) exploits the consistent facial geometry across different images of the same individual to estimate 3D face shapes and poses without 2D-to-3D supervision. This method illustrates how leveraging the inherent properties of unpaired images—such as identity consistency—can circumvent the need for expensive paired datasets. Similarly, SPICE (Sanyal et al. [2021]) employs a self-supervised learning framework that harnesses unpaired images to generate realistic transpositions of human poses by understanding the underlying 3D body structure and maintaining consistency in body shape and appearance features across different poses. Finally, SCULPT (Sanyal et al. [2024] generates clothed and textured 3D meshes by integrating insights from unpaired 2D images and medium-sized 3D scans. This process employs an unpaired learning approach, conditioning texture and geometry generation on attributes easily derived from data, like the type and appearance of clothing. In conclusion, this thesis highlights how unpaired data and innovative learning techniques can address the challenges of data scarcity and high costs in developing controllable digital humans by advancing reconstruction, transposition, and generation techniques.
Realistic Digital Human Characters: Challenges, Models and Algorithms
University of Tübingen, September 2024 (phdthesis)
Statistical models for the body, head, and hands are essential in various computer vision tasks. However, popular models like SMPL, MANO, and FLAME produce unrealistic deformations due to inherent flaws in their modeling assumptions and how they are trained, which have become standard practices in constructing models for the body and its parts. This dissertation addresses these limitations by proposing new modeling and training algorithms to improve the realism and generalization of current models. We introduce a new model, STAR (Sparse Trained Articulated Human Body Regressor), which learns a sparse representation of the human body deformations, significantly reducing the number of model parameters compared to models like SMPL. This approach ensures that deformations are spatially localized, leading to more realistic deformations. STAR also incorporates shape-dependent pose deformations, accounting for variations in body shape to enhance overall model accuracy and realism. Additionally, we present a novel federated training algorithm for developing a comprehensive suite of models for the body and its parts. We train an expressive body model, SUPR (Sparse Unified Part-Based Representation), on a federated dataset of full-body scans, including detailed scans of the head, hands, and feet. We then separate SUPR into a full suite of state-of-the-art models for the head, hands, and foot. The new foot model captures complex foot deformations, addressing challenges related to foot shape, pose, and ground contact dynamics. The dissertation concludes by introducing AVATAR (Articulated Virtual Humans Trained By Bayesian Inference From a Single Scan), a novel, data-efficient training algorithm. AVATAR allows the creation of personalized, high-fidelity body models from a single scan by framing model construction as a Bayesian inference problem, thereby enabling training from small-scale datasets while reducing the risk of overfitting. These advancements push the state of the art in human body modeling and training techniques, making them more accessible for broader research and practical applications.
Modelling Dynamic 3D Human-Object Interactions: From Capture to Synthesis
University of Tübingen, July 2024 (phdthesis) To be published
Modeling digital humans that move and interact realistically with virtual 3D worlds has emerged as an essential research area recently, with significant applications in computer graphics, virtual and augmented reality, telepresence, the Metaverse, and assistive technologies. In particular, human-object interaction, encompassing full-body motion, hand-object grasping, and object manipulation, lies at the core of how humans execute tasks and represents the complex and diverse nature of human behavior. Therefore, accurate modeling of these interactions would enable us to simulate avatars to perform tasks, enhance animation realism, and develop applications that better perceive and respond to human behavior. Despite its importance, this remains a challenging problem, due to several factors such as the complexity of human motion, the variance of interaction based on the task, and the lack of rich datasets capturing the complexity of real-world interactions. Prior methods have made progress, but limitations persist as they often focus on individual aspects of interaction, such as body, hand, or object motion, without considering the holistic interplay among these components. This Ph.D. thesis addresses these challenges and contributes to the advancement of human-object interaction modeling through the development of novel datasets, methods, and algorithms.
Self- and Interpersonal Contact in 3D Human Mesh Reconstruction
University of Tübingen, Tübingen, 2024 (phdthesis)
The ability to perceive tactile stimuli is of substantial importance for human beings in establishing a connection with the surrounding world. Humans rely on the sense of touch to navigate their environment and to engage in interactions with both themselves and other people. The field of computer vision has made great progress in estimating a person’s body pose and shape from an image, however, the investigation of self- and interpersonal contact has received little attention despite its considerable significance. Estimating contact from images is a challenging endeavor because it necessitates methodologies capable of predicting the full 3D human body surface, i.e. an individual’s pose and shape. The limitations of current methods become evident when considering the two primary datasets and labels employed within the community to supervise the task of human pose and shape estimation. First, the widely used 2D joint locations lack crucial information for representing the entire 3D body surface. Second, in datasets of 3D human bodies, e.g. collected from motion capture systems or body scanners, contact is usually avoided, since it naturally leads to occlusion which complicates data cleaning and can break the data processing pipelines.
In this thesis, we first address the problem of estimating contact that humans make with themselves from RGB images. To do this, we introduce two novel methods that we use to create new datasets tailored for the task of human mesh estimation for poses with self-contact. We create (1) 3DCP, a dataset of 3D body scan and motion capture data of humans in poses with self-contact and (2) MTP, a dataset of images taken in the wild with accurate 3D reference data using pose mimicking. Next, we observe that 2D joint locations can be readily labeled at scale given an image, however, an equivalent label for self-contact does not exist. Consequently, we introduce (3) distrecte self-contact (DSC) annotations indicating the pairwise contact of discrete regions on the human body. We annotate three existing image datasets with discrete self-contact and use these labels during mesh optimization to bring body parts supposed to touch into contact. Then we train TUCH, a human mesh regressor, on our new datasets. When evaluated on the task of human body pose and shape estimation on public benchmarks, our results show that knowing about self-contact not only improves mesh estimates for poses with self-contact, but also for poses without self-contact.
Next, we study contact humans make with other individuals during close social interaction. Reconstructing these interactions in 3D is a significant challenge due to the mutual occlusion. Furthermore, the existing datasets of images taken in the wild with ground-truth contact labels are of insufficient size to facilitate the training of a robust human mesh regressor. In this work, we employ a generative model, BUDDI, to learn the joint distribution of 3D pose and shape of two individuals during their interaction and use this model as prior during an optimization routine. To construct training data we leverage pre-existing datasets, i.e. motion capture data and Flickr images with discrete contact annotations. Similar to discrete self-contact labels, we utilize discrete human- human contact to jointly fit two meshes to detected 2D joint locations. The majority of methods for generating 3D humans focus on the motion of a single person and operate on 3D joint locations. While these methods can effectively generate motion, their representation of 3D humans is not sufficient for physical contact since they do not model the body surface. Our approach, in contrast, acts on the pose and shape parameters of a human body model, which enables us to sample 3D meshes of two people. We further demonstrate how the knowledge of human proxemics, incorporated in our model, can be used to guide an optimization routine. For this, in each optimization iteration, BUDDI takes the current mesh and proposes a refinement that we subsequently consider in the objective function. This procedure enables us to go beyond state of the art by forgoing ground-truth discrete human-human contact labels during optimization.
Self- and interpersonal contact happen on the surface of the human body, however, the majority of existing art tends to predict bodies with similar, “average” body shape. This is due to a lack of training data of paired images taken in the wild and ground- truth 3D body shape and because 2D joint locations are not sufficient to explain body shape. The most apparent solution would be to collect body scans of people together with their photos. This is, however, a time-consuming and cost-intensive process that lacks scalability. Instead, we leverage the vocabulary humans use to describe body shape. First, we ask annotators to label how much a word like “tall” or “long legs” applies to a human body. We gather these ratings for rendered meshes of various body shapes, for which we have ground-truth body model shape parameters, and for images collected from model agency websites. Using this data, we learn a shape-to-attribute (A2S) model that predicts body shape ratings from body shape parameters. Then we train a human mesh regressor, SHAPY, on the model agency images wherein we supervise body shape via attribute annotations using A2S. Since no suitable test set of diverse 3D ground-truth body shape with images taken in natural settings exists, we introduce Human Bodies in the Wild (HBW). This novel dataset contains photographs of individuals together with their body scan. Our model predicts more realistic body shapes from an image and quantitatively improves body shape estimation on this new benchmark.
In summary, we present novel datasets, optimization methods, a generative model, and regressors to advance the field of 3D human pose and shape estimation. Taken together, these methods open up ways to obtain more accurate and realistic 3D mesh estimates from images with multiple people in self- and mutual contact poses and with diverse body shapes. This line of research also enables generative approaches to create more natural, human-like avatars. We believe that knowing about self- and human-human contact through computer vision has wide-ranging implications in other fields as for example robotics, fitness, or behavioral science.
Natural Language Control for 3D Human Motion Synthesis
LIGM, Ecole des Ponts, Univ Gustave Eiffel, CNRS, 2024 (phdthesis)
3D human motions are at the core of many applications in the film industry,
healthcare, augmented reality, virtual reality and video games. However, these
applications often rely on expensive and time-consuming motion capture data.
The goal of this thesis is to explore generative models as an alternative
route to obtain 3D human motions. More specifically, our aim is to allow a
natural language interface as a means to control the generation process. To
this end, we develop a series of models that synthesize realistic and diverse
motions following the semantic inputs.
In our first contribution, described in Chapter 3, we address the challenge
of generating human motion sequences conditioned on specific action categories.
We introduce ACTOR, a conditional variational autoencoder (VAE) that learns an
action-aware latent representation for human motions. We show significant gains
over existing methods thanks to our new Transformer-based VAE formulation,
encoding and decoding SMPL pose sequences through a single motion-level
embedding.
In our second contribution, described in Chapter 4, we go beyond categorical
actions, and dive into the task of synthesizing diverse 3D human motions
from textual descriptions allowing a larger vocabulary and potentially more
fine-grained control. Our work stands out from previous research by not
deterministically generating a single motion sequence, but by synthesizing
multiple, varied sequences from a given text. We propose TEMOS, building on
our VAE-based ACTOR architecture, but this time integrating a pretrained text
encoder to handle large-vocabulary natural language inputs.
In our third contribution, described in Chapter 5, we address the adjacent
task of text-to-3D human motion retrieval, where the goal is to search in a
motion collection by querying via text. We introduce a simple yet effective
approach, named TMR, building on our earlier model TEMOS, by integrating a
contrastive loss to enhance the structure of the cross-modal latent space. Our
findings emphasize the importance of retaining the motion generation loss in
conjunction with contrastive training for improved results. We establish a new
evaluation benchmark and conduct analyses on several protocols.
In our fourth contribution, described in Chapter 6, we introduce a new
problem termed as “multi-track timeline control” for text-driven 3D human
motion synthesis. Instead of a single textual prompt, users can organize multiple
prompts in temporal intervals that may overlap. We introduce STMC, a test-time
denoising method that can be integrated with any pre-trained motion diffusion
model. Our evaluations demonstrate that our method generates motions that
closely match the semantic and temporal aspects of the input timelines.
In summary, our contributions in this thesis are as follows: (i) we develop a
generative variational autoencoder, ACTOR, for action-conditioned generation of
human motion sequences, (ii) we introduce TEMOS, a text-conditioned generative
model that synthesizes diverse human motions from textual descriptions, (iii)
we present TMR, a new approach for text-to-3D human motion retrieval, (iv) we
propose STMC, a method for timeline control in text-driven motion synthesis,
enabling the generation of detailed and complex motions.
2022
Reconstructing Expressive 3D Humans from RGB Images
ETH Zurich, Max Planck Institute for Intelligent Systems and ETH Zurich, December 2022 (phdthesis)
To interact with our environment, we need to adapt our body posture
and grasp objects with our hands. During a conversation our facial expressions
and hand gestures convey important non-verbal cues about our
emotional state and intentions towards our fellow speakers. Thus, modeling
and capturing 3D full-body shape and pose, hand articulation and facial
expressions are necessary to create realistic human avatars for augmented
and virtual reality. This is a complex task, due to the large number of
degrees of freedom for articulation, body shape variance, occlusions from
objects and self-occlusions from body parts, e.g. crossing our hands, and
subject appearance. The community has thus far relied on expensive and
cumbersome equipment, such as multi-view cameras or motion capture
markers, to capture the 3D human body. While this approach is effective,
it is limited to a small number of subjects and indoor scenarios. Using
monocular RGB cameras would greatly simplify the avatar creation process,
thanks to their lower cost and ease of use. These advantages come at a price
though, since RGB capture methods need to deal with occlusions, perspective
ambiguity and large variations in subject appearance, in addition to
all the challenges posed by full-body capture. In an attempt to simplify the
problem, researchers generally adopt a divide-and-conquer strategy, estimating
the body, face and hands with distinct methods using part-specific
datasets and benchmarks. However, the hands and face constrain the body
and vice-versa, e.g. the position of the wrist depends on the elbow, shoulder,
etc.; the divide-and-conquer approach can not utilize this constraint.
In this thesis, we aim to reconstruct the full 3D human body, using only
readily accessible monocular RGB images. In a first step, we introduce a
parametric 3D body model, called SMPL-X, that can represent full-body
shape and pose, hand articulation and facial expression. Next, we present
an iterative optimization method, named SMPLify-X, that fits SMPL-X to
2D image keypoints. While SMPLify-X can produce plausible results if
the 2D observations are sufficiently reliable, it is slow and susceptible
to initialization. To overcome these limitations, we introduce ExPose, a
neural network regressor, that predicts SMPL-X parameters from an image
using body-driven attention, i.e. by zooming in on the hands and face,
after predicting the body. From the zoomed-in part images, dedicated
part networks predict the hand and face parameters. ExPose combines
the independent body, hand, and face estimates by trusting them equally.
This approach though does not fully exploit the correlation between parts
and fails in the presence of challenges such as occlusion or motion blur.
Thus, we need a better mechanism to aggregate information from the full
body and part images. PIXIE uses neural networks called moderators that
learn to fuse information from these two image sets before predicting the
final part parameters. Overall, the addition of the hands and face leads to
noticeably more natural and expressive reconstructions.
Creating high fidelity avatars from RGB images requires accurate estimation
of 3D body shape. Although existing methods are effective at
predicting body pose, they struggle with body shape. We identify the lack
of proper training data as the cause. To overcome this obstacle, we propose
to collect internet images from fashion models websites, together with
anthropometric measurements. At the same time, we ask human annotators
to rate images and meshes according to a pre-defined set of linguistic attributes.
We then define mappings between measurements, linguistic shape
attributes and 3D body shape. Equipped with these mappings, we train a
neural network regressor, SHAPY, that predicts accurate 3D body shapes
from a single RGB image. We observe that existing 3D shape benchmarks
lack subject variety and/or ground-truth shape. Thus, we introduce a new
benchmark, Human Bodies in the Wild (HBW), which contains images of
humans and their corresponding 3D ground-truth body shape. SHAPY
shows how we can overcome the lack of in-the-wild images with 3D shape
annotations through easy-to-obtain anthropometric measurements and linguistic
shape attributes.
Regressors that estimate 3D model parameters are robust and accurate,
but often fail to tightly fit the observations. Optimization-based approaches
tightly fit the data, by minimizing an energy function composed of a data
term that penalizes deviations from the observations and priors that encode
our knowledge of the problem. Finding the balance between these terms
and implementing a performant version of the solver is a time-consuming
and non-trivial task. Machine-learned continuous optimizers combine the
benefits of both regression and optimization approaches. They learn the
priors directly from data, avoiding the need for hand-crafted heuristics and
loss term balancing, and benefit from optimized neural network frameworks
for fast inference. Inspired from the classic Levenberg-Marquardt
algorithm, we propose a neural optimizer that outperforms classic optimization,
regression and hybrid optimization-regression approaches. Our
proposed update rule uses a weighted combination of gradient descent
and a network-predicted update. To show the versatility of the proposed
method, we apply it on three other problems, namely full body estimation
from (i) 2D keypoints, (ii) head and hand location from a head-mounted
device and (iii) face tracking from dense 2D landmarks. Our method can
easily be applied to new model fitting problems and offers a competitive
alternative to well-tuned traditional model fitting pipelines, both in terms
of accuracy and speed.
To summarize, we propose a new and richer representation of the human
body, SMPL-X, that is able to jointly model the 3D human body pose
and shape, facial expressions and hand articulation. We propose methods,
SMPLify-X, ExPose and PIXIE that estimate SMPL-X parameters from
monocular RGB images, progressively improving the accuracy and realism
of the predictions. To further improve reconstruction fidelity, we demonstrate
how we can use easy-to-collect internet data and human annotations
to overcome the lack of 3D shape data and train a model, SHAPY, that
predicts accurate 3D body shape from a single RGB image. Finally, we
propose a flexible learnable update rule for parametric human model fitting
that outperforms both classic optimization and neural network approaches.
This approach is easily applicable to a variety of problems, unlocking new
applications in AR/VR scenarios.
2019
Towards Geometric Understanding of Motion
University of Tübingen, December 2019 (phdthesis)
The motion of the world is inherently dependent on the spatial structure of the world and its geometry. Therefore, classical optical flow methods try to model this geometry to solve for the motion. However, recent deep learning methods take a completely different approach. They try to predict optical flow by learning from labelled data. Although deep networks have shown state-of-the-art performance on classification problems in computer vision, they have not been as effective in solving optical flow. The key reason is that deep learning methods do not explicitly model the structure of the world in a neural network, and instead expect the network to learn about the structure from data. We hypothesize that it is difficult for a network to learn about motion without any constraint on the structure of the world. Therefore, we explore several approaches to explicitly model the geometry of the world and its spatial structure in deep neural networks.
The spatial structure in images can be captured by representing it at multiple scales. To represent multiple scales of images in deep neural nets, we introduce a Spatial Pyramid Network (SpyNet). Such a network can leverage global information for estimating large motions and local information for estimating small motions. We show that SpyNet significantly improves over previous optical flow networks while also being the smallest and fastest neural network for motion estimation. SPyNet achieves a 97% reduction in model parameters over previous methods and is more accurate.
The spatial structure of the world extends to people and their motion. Humans have a very well-defined structure, and this information is useful in estimating optical flow for humans. To leverage this information, we create a synthetic dataset for human optical flow using a statistical human body model and motion capture sequences. We use this dataset to train deep networks and see significant improvement in the ability of the networks to estimate human optical flow.
The structure and geometry of the world affects the motion. Therefore, learning about the structure of the scene together with the motion can benefit both problems. To facilitate this, we introduce Competitive Collaboration, where several neural networks are constrained by geometry and can jointly learn about structure and motion in the scene without any labels. To this end, we show that jointly learning single view depth prediction, camera motion, optical flow and motion segmentation using Competitive Collaboration achieves state-of-the-art results among unsupervised approaches.
Our findings provide support for our hypothesis that explicit constraints on structure and geometry of the world lead to better methods for motion estimation.
2018
Model-based Optical Flow: Layers, Learning, and Geometry
Tuebingen University, April 2018 (phdthesis)
The estimation of motion in video sequences establishes temporal correspondences between pixels and surfaces and allows reasoning about a scene using multiple frames. Despite being a focus of research for over three decades, computing motion, or optical flow, remains challenging due to a number of difficulties, including the treatment of motion discontinuities and occluded regions, and the integration of information from more than two frames. One reason for these issues is that most optical flow algorithms only reason about the motion of pixels on the image plane, while not taking the image formation pipeline or the 3D structure of the world into account. One approach to address this uses layered models, which represent the occlusion structure of a scene and provide an approximation to the geometry. The goal of this dissertation is to show ways to inject additional knowledge about the scene into layered methods, making them more robust, faster, and more accurate. First, this thesis demonstrates the modeling power of layers using the example of motion blur in videos, which is caused by fast motion relative to the exposure time of the camera. Layers segment the scene into regions that move coherently while preserving their occlusion relationships. The motion of each layer therefore directly determines its motion blur. At the same time, the layered model captures complex blur overlap effects at motion discontinuities. Using layers, we can thus formulate a generative model for blurred video sequences, and use this model to simultaneously deblur a video and compute accurate optical flow for highly dynamic scenes containing motion blur. Next, we consider the representation of the motion within layers. Since, in a layered model, important motion discontinuities are captured by the segmentation into layers, the flow within each layer varies smoothly and can be approximated using a low dimensional subspace. We show how this subspace can be learned from training data using principal component analysis (PCA), and that flow estimation using this subspace is computationally efficient. The combination of the layered model and the low-dimensional subspace gives the best of both worlds, sharp motion discontinuities from the layers and computational efficiency from the subspace. Lastly, we show how layered methods can be dramatically improved using simple semantics. Instead of treating all layers equally, a semantic segmentation divides the scene into its static parts and moving objects. Static parts of the scene constitute a large majority of what is shown in typical video sequences; yet, in such regions optical flow is fully constrained by the depth structure of the scene and the camera motion. After segmenting out moving objects, we consider only static regions, and explicitly reason about the structure of the scene and the camera motion, yielding much better optical flow estimates. Furthermore, computing the structure of the scene allows to better combine information from multiple frames, resulting in high accuracies even in occluded regions. For moving regions, we compute the flow using a generic optical flow method, and combine it with the flow computed for the static regions to obtain a full optical flow field. By combining layered models of the scene with reasoning about the dynamic behavior of the real, three-dimensional world, the methods presented herein push the envelope of optical flow computation in terms of robustness, speed, and accuracy, giving state-of-the-art results on benchmarks and pointing to important future research directions for the estimation of motion in natural scenes.
Combining Data-Driven 2D and 3D Human Appearance Models
Eberhard Karls Universität Tübingen, 2018 (phdthesis)
Detailed 2D and 3D body estimation of humans has many applications in our everyday life: interaction with machines, virtual try-on of fashion or product adjustments based on a body size estimate are just some examples. Two key components of such systems are: (1) detailed pose and shape estimation and (2) generation of images. Ideally, they should use 2D images as input signal so that they can be applied easily and on arbitrary digital images. Due to the high complexity of human appearance and the depth ambiguities in 2D space, data driven models are the tool at hand to design such methods. In this work, we consider two aspects of such systems: in the first part, we propose general optimization and implementation techniques for machine learning models and make them available in the form of software packages. In the second part, we present in multiple steps, how the detailed analysis and generation of human appearance based on digital 2D images can be realized. We work with two machine learning methods: Decision Forests and Artificial Neural Networks. The contribution of this thesis to the theory of Decision Forests consists of the introduction of a generalized entropy function that is efficient to evaluate and tunable to specific tasks and allows us to establish relations to frequently used heuristics. For both, Decision Forests and Neural Networks, we present methods for implementation and a software package. Existing methods for 3D body estimation from images usually estimate the 14 most important, pose defining points in 2D and convert them to a 3D `skeleton'. In this work we show that a carefully crafted energy function is sufficient to recover a full 3D body shape automatically from the keypoints. In this way, we devise the first fully automatic method estimating 3D body pose and shape from a 2D image. While this method successfully recovers a coarse 3D pose and shape, it is still a challenge to recover details such as body part rotations. However, for more detailed models, it would be necessary to annotate data with a very rich set of cues. This approach does not scale to large datasets, since the effort per image as well as the required quality could not be reached due to how hard it is to estimate the position of keypoints on the body surface. To solve this problem, we develop a method that can alternate between optimizing the 2D and 3D models, improving them iteratively. The labeling effort for humans remains low. At the same time, we create 2D models reasoning about factors more items than existing methods and we extend the 3D pose and body shape estimation to rotation and body extent. To generate images of people, existing methods usually work with 3D models that are hard to adjust and to use. In contrast, we develop a method that builds on the possibilities for automatic 3D body estimation: we use it to create a dataset of 3D bodies together with 2D clothes and cloth segments. With this information, we develop a data driven model directly producing 2D images of people. Only the broad interplay of 2D and 3D body and appearance models in different forms makes it possible to achieve a high level of detail for analysis and generation of human appearance. The developed techniques can in principle also be used for the analysis and generation of images of other creatures and objects.
2017
Human Shape Estimation using Statistical Body Models
University of Tübingen, May 2017 (phdthesis)
Human body estimation methods transform real-world observations into predictions about human body state. These estimation methods benefit a variety of health, entertainment, clothing, and ergonomics applications. State may include pose, overall body shape, and appearance.
Body state estimation is underconstrained by observations; ambiguity presents itself both in the form of missing data within observations, and also in the form of unknown correspondences between observations. We address this challenge with the use of a statistical body model: a data-driven virtual human. This helps resolve ambiguity in two ways. First, it fills in missing data, meaning that incomplete observations still result in complete shape estimates. Second, the model provides a statistically-motivated penalty for unlikely states, which enables more plausible body shape estimates.
Body state inference requires more than a body model; we therefore build obser- vation models whose output is compared with real observations. In this thesis, body state is estimated from three types of observations: 3D motion capture markers, depth and color images, and high-resolution 3D scans. In each case, a forward process is proposed which simulates observations. By comparing observations to the results of the forward process, state can be adjusted to minimize the difference between simulated and observed data. We use gradient-based methods because they are critical to the precise estimation of state with a large number of parameters.
The contributions of this work include three parts. First, we propose a method for the estimation of body shape, nonrigid deformation, and pose from 3D markers. Second, we present a concise approach to differentiating through the rendering process, with application to body shape estimation. And finally, we present a statistical body model trained from human body scans, with state-of-the-art fidelity, good runtime performance, and compatibility with existing animation packages.
Learning Inference Models for Computer Vision
MPI for Intelligent Systems and University of Tübingen, 2017 (phdthesis)
Computer vision can be understood as the ability to perform 'inference' on image data. Breakthroughs in computer vision technology are often marked by advances in inference techniques, as even the model design is often dictated by the complexity of inference in them. This thesis proposes learning based inference schemes and demonstrates applications in computer vision. We propose techniques for inference in both generative and discriminative computer vision models.
Despite their intuitive appeal, the use of generative models in vision is hampered by the difficulty of posterior inference, which is often too complex or too slow to be practical. We propose techniques for improving inference in two widely used techniques: Markov Chain Monte Carlo (MCMC) sampling and message-passing inference. Our inference strategy is to learn separate discriminative models that assist Bayesian inference in a generative model. Experiments on a range of generative vision models show that the proposed techniques accelerate the inference process and/or converge to better solutions.
A main complication in the design of discriminative models is the inclusion of prior knowledge in a principled way. For better inference in discriminative models, we propose techniques that modify the original model itself, as inference is simple evaluation of the model. We concentrate on convolutional neural network (CNN) models and propose a generalization of standard spatial convolutions, which are the basic building blocks of CNN architectures, to bilateral convolutions. First, we generalize the existing use of bilateral filters and then propose new neural network architectures with learnable
bilateral filters, which we call `Bilateral Neural Networks'. We show how the bilateral filtering modules can be used for modifying existing CNN architectures for better image segmentation and propose a neural network approach for temporal information propagation in videos. Experiments demonstrate the potential of the proposed bilateral networks on a wide range of vision tasks and datasets.
In summary, we propose learning based techniques for better inference in several computer vision models ranging from inverse graphics to freely parameterized neural networks. In generative vision models, our inference techniques alleviate some of the crucial hurdles in Bayesian posterior inference, paving new ways for the use of model based machine learning in vision. In discriminative CNN models, the proposed filter generalizations aid in the design of new neural network architectures that can handle sparse high-dimensional data as well as provide a way for incorporating prior knowledge into CNNs.
Capturing Hand-Object Interaction and Reconstruction of Manipulated Objects
University of Bonn, 2017 (phdthesis)
Hand motion capture with an RGB-D sensor gained recently a lot of research attention, however, even most recent approaches focus on the case of a single isolated hand.
We focus instead on hands that interact with other hands or with a rigid or articulated object.
Our framework successfully captures motion in such scenarios by combining a generative model with discriminatively trained salient points, collision detection and physics simulation to achieve a low tracking error with physically plausible poses.
All components are unified in a single objective function that can be optimized with standard optimization techniques.
We initially assume a-priori knowledge of the object's shape and skeleton.
In case of unknown object shape there are existing 3d reconstruction methods that capitalize on distinctive geometric or texture features.
These methods though fail for textureless and highly symmetric objects like household articles, mechanical parts or toys.
We show that extracting 3d hand motion for in-hand scanning effectively facilitates the reconstruction of such objects and we fuse the rich additional information of hands into a 3d reconstruction pipeline.
Finally, although shape reconstruction is enough for rigid objects, there is a lack of tools that build rigged models of articulated objects that deform realistically using RGB-D data.
We propose a method that creates a fully rigged model consisting of a watertight mesh, embedded skeleton and skinning weights by employing a combination of deformable mesh tracking, motion segmentation based on spectral clustering and skeletonization based on mean curvature flow.
2016
Non-parametric Models for Structured Data and Applications to Human Bodies and Natural Scenes
ETH Zurich, July 2016 (phdthesis)
The purpose of this thesis is the study of non-parametric models for structured data and their fields of application in computer vision. We aim at the development of context-sensitive architectures which are both expressive and efficient. Our focus is on directed graphical models, in particular Bayesian networks, where we combine the flexibility of non-parametric local distributions with the efficiency of a global topology with bounded treewidth. A bound on the treewidth is obtained by either constraining the maximum indegree of the underlying graph structure or by introducing determinism. The non-parametric distributions in the nodes of the graph are given by decision trees or kernel density estimators.
The information flow implied by specific network topologies, especially the resultant (conditional) independencies, allows for a natural integration and control of contextual information. We distinguish between three different types of context: static, dynamic, and semantic. In four different approaches we propose models which exhibit varying combinations of these contextual properties and allow modeling of structured data in space, time, and hierarchies derived thereof. The generative character of the presented models enables a direct synthesis of plausible hypotheses.
Extensive experiments validate the developed models in two application scenarios which are of particular interest in computer vision: human bodies and natural scenes. In the practical sections of this work we discuss both areas from different angles and show applications of our models to human pose, motion, and segmentation as well as object categorization and localization. Here, we benefit from the availability of modern datasets of unprecedented size and diversity. Comparisons to traditional approaches and state-of-the-art research on the basis of well-established evaluation criteria allows the objective assessment of our contributions.
2015
Proceedings of the 37th German Conference on Pattern Recognition
Gall, J., Gehler, P., Leibe, B.
Springer, German Conference on Pattern Recognition, October 2015 (proceedings)
Shape Models of the Human Body for Distributed Inference
Brown University, May 2015 (phdthesis)
In this thesis we address the problem of building shape models of the human body,
in 2D and 3D, which are realistic and efficient to use. We focus our efforts on the
human body, which is highly articulated and has interesting shape variations, but
the approaches we present here can be applied to generic deformable and articulated
objects. To address efficiency, we constrain our models to be part-based and have a
tree-structured representation with pairwise relationships between connected parts.
This allows the application of methods for distributed inference based on message
passing. To address realism, we exploit recent advances in computer graphics that
represent the human body with statistical shape models learned from 3D scans.
We introduce two articulated body models, a 2D model, named Deformable Structures
(DS), which is a contour-based model parameterized for 2D pose and projected
shape, and a 3D model, named Stitchable Puppet (SP), which is a mesh-based model
parameterized for 3D pose, pose-dependent deformations and intrinsic body shape.
We have successfully applied the models to interesting and challenging problems in
computer vision and computer graphics, namely pose estimation from static images,
pose estimation from video sequences, pose and shape estimation from 3D scan data.
This advances the state of the art in human pose and shape estimation and suggests
that carefully de
ned realistic models can be important for computer vision.
More work at the intersection of vision and graphics is thus encouraged.
From Scans to Models: Registration of 3D Human Shapes Exploiting Texture Information
University of Padova, March 2015 (phdthesis)
New scanning technologies are increasing the importance of 3D mesh data, and of algorithms that can reliably register meshes obtained from multiple scans. Surface registration is important e.g. for building full 3D models from partial scans, identifying and tracking objects in a 3D scene, creating statistical shape models.
Human body registration is particularly important for many applications, ranging from biomedicine and robotics to the production of movies and video games; but obtaining accurate and reliable registrations is challenging, given the articulated, non-rigidly deformable structure of the human body.
In this thesis, we tackle the problem of 3D human body registration.
We start by analyzing the current state of the art, and find that: a) most registration techniques rely only on geometric information, which is ambiguous on flat surface areas; b) there is a lack of adequate datasets and benchmarks in the field. We address both issues.
Our contribution is threefold. First, we present a model-based registration technique for human meshes that combines geometry and surface texture information to provide highly accurate mesh-to-mesh correspondences. Our approach estimates scene lighting and surface albedo, and uses the albedo to construct a high-resolution textured 3D body model that is brought into registration with multi-camera image data using a robust matching term.
Second, by leveraging our technique, we present FAUST (Fine Alignment Using Scan Texture), a novel dataset collecting 300 high-resolution scans of 10 people in a wide range of poses. FAUST is the first dataset providing both real scans and automatically computed, reliable "ground-truth" correspondences between them.
Third, we explore possible uses of our approach in dermatology. By combining our registration technique with a melanocytic lesion segmentation algorithm, we propose a system that automatically detects new or evolving lesions over almost the entire body surface, thus helping dermatologists identify potential melanomas.
We conclude this thesis investigating the benefits of using texture information to establish frame-to-frame correspondences in dynamic monocular sequences captured with consumer depth cameras. We outline a novel approach to reconstruct realistic body shape and appearance models from dynamic human performances, and show preliminary results on challenging sequences captured with a Kinect.
Long Range Motion Estimation and Applications
Long Range Motion Estimation and Applications, University of Massachusetts Amherst, University of Massachusetts Amherst, February 2015 (phdthesis)
Finding correspondences between images underlies many computer vision problems, such as optical flow, tracking, stereovision and alignment. Finding these correspondences involves formulating a matching function and optimizing it. This optimization process is often gradient descent, which avoids exhaustive search, but relies on the assumption of being in the basin of attraction of the right local minimum. This is often the case when the displacement is small, and current methods obtain very accurate results for small motions. However, when the motion is large and the matching function is bumpy this assumption is less likely to be true. One traditional way of avoiding this abruptness is to smooth the matching function spatially by blurring the images. As the displacement becomes larger, the amount of blur required to smooth the matching function becomes also larger. This averaging of pixels leads to a loss of detail in the image. Therefore, there is a trade-off between the size of the objects that can be tracked and the displacement that can be captured.
In this thesis we address the basic problem of increasing the size of the basin of attraction in a matching function. We use an image descriptor called distribution fields (DFs). By blurring the images in DF space instead of in pixel space, we in- crease the size of the basin attraction with respect to traditional methods. We show competitive results using DFs both in object tracking and optical flow. Finally we demonstrate an application of capturing large motions for temporal video stitching.
2014
Modeling the Human Body in 3D: Data Registration and Human Shape Representation
Brown University, Department of Computer Science, May 2014 (phdthesis)
Learning People Detectors for Tracking in Crowded Scenes.
Tang, S., Andriluka, M., Milan, A., Schindler, K., Roth, S., Schiele, B.
2014, Scene Understanding Workshop (SUNw, CVPR workshop) (unpublished)
2013
Statistics on Manifolds with Applications to Modeling Shape Deformations
Brown University, August 2013 (phdthesis)
Statistical models of non-rigid deformable shape have wide application in many fi
elds,
including computer vision, computer graphics, and biometry. We show that shape deformations
are well represented through nonlinear manifolds that are also matrix Lie groups.
These pattern-theoretic representations lead to several advantages over other alternatives,
including a principled measure of shape dissimilarity and a natural way to compose deformations.
Moreover, they enable building models using statistics on manifolds. Consequently,
such models are superior to those based on Euclidean representations. We
demonstrate this by modeling 2D and 3D human body shape. Shape deformations are
only one example of manifold-valued data. More generally, in many computer-vision and
machine-learning problems, nonlinear manifold representations arise naturally and provide
a powerful alternative to Euclidean representations. Statistics is traditionally concerned
with data in a Euclidean space, relying on the linear structure and the distances associated
with such a space; this renders it inappropriate for nonlinear spaces. Statistics can,
however, be generalized to nonlinear manifolds. Moreover, by respecting the underlying
geometry, the statistical models result in not only more e
ffective analysis but also consistent
synthesis. We go beyond previous work on statistics on manifolds by showing how,
even on these curved spaces, problems related to modeling a class from scarce data can be
dealt with by leveraging information from related classes residing in di
fferent regions of the
space. We show the usefulness of our approach with 3D shape deformations. To summarize
our main contributions: 1) We de
fine a new 2D articulated model -- more expressive than
traditional ones -- of deformable human shape that factors body-shape, pose, and camera
variations. Its high realism is obtained from training data generated from a detailed 3D
model. 2) We defi
ne a new manifold-based representation of 3D shape deformations that
yields statistical deformable-template models that are better than the current state-of-the-
art. 3) We generalize a transfer learning idea from Euclidean spaces to Riemannian
manifolds. This work demonstrates the value of modeling manifold-valued data and their
statistics explicitly on the manifold. Specifi
cally, the methods here provide new tools for
shape analysis.
Probabilistic Models for 3D Urban Scene Understanding from Movable Platforms
Karlsruhe Institute of Technology, Karlsruhe Institute of Technology, April 2013 (phdthesis)
Visual 3D scene understanding is an important component in autonomous
driving and robot navigation. Intelligent vehicles for example often
base their decisions on observations obtained from video cameras
as they are cheap and easy to employ. Inner-city intersections represent
an interesting but also very challenging scenario in this context:
The road layout may be very complex and observations are often noisy
or even missing due to heavy occlusions. While Highway navigation
and autonomous driving on simple and annotated intersections have
already been demonstrated successfully, understanding and navigating
general inner-city crossings with little prior knowledge remains
an unsolved problem. This thesis is a contribution to understanding
multi-object traffic scenes from video sequences. All data is provided
by a camera system which is mounted on top of the autonomous driving
platform AnnieWAY. The proposed probabilistic generative model reasons
jointly about the 3D scene layout as well as the 3D location and
orientation of objects in the scene. In particular, the scene topology,
geometry as well as traffic activities are inferred from short video
sequences. The model takes advantage of monocular information in
the form of vehicle tracklets, vanishing lines and semantic labels.
Additionally, the benefit of stereo features such as 3D scene flow
and occupancy grids is investigated. Motivated by the impressive
driving capabilities of humans, no further information such as GPS,
lidar, radar or map knowledge is required. Experiments conducted
on 113 representative intersection sequences show that the developed
approach successfully infers the correct layout in a variety of difficult
scenarios. To evaluate the importance of each feature cue, experiments
with different feature combinations are conducted. Additionally,
the proposed method is shown to improve object detection and object
orientation estimation performance.
2012
Virtual Human Bodies with Clothing and Hair: From Images to Animation
Brown University, Department of Computer Science, December 2012 (phdthesis)
From Pixels to Layers: Joint Motion Estimation and Segmentation
Brown University, Department of Computer Science, July 2012 (phdthesis)
1992
Robust Incremental Optical Flow
Yale University, Department of Computer Science, New Haven, CT, 1992, Research Report YALEU-DCS-RR-923 (phdthesis)
This thesis addresses the problem of recovering 2D image velocity, or optical flow, robustly over long image sequences. We develop a robust estimation framework for improving the reliability of motion estimates and an incremental minimization framework for recovering flow estimates over time.
Attempts to improve the robustness of optical flow have focused on detecting and accounting for motion discontinuities in the optical flow field. We show that motion discontinuities are one example of a more general class of model violations and that by formulating the optical flow problem as one of robust estimation the problems posed by motion discontinuities can be reduced, and the violations can be detected. Additionally, robust estimation provides a powerful framework for early vision problems that generalizes the popular “line process” approaches.
We formulate a temporal continuity constraint, which reflects the fact that the motion of a surface changes gradually over time. We exploit this constraint to develop a new incremental minimization framework and show how it is related to standard recursive estimation techniques. Within this framework we implement two incremental algorithms for minimizing non-convex objective functions over time; Incremental Stochastic Minimization (ISM)
and Incremental Graduated Non-Convexity (IGNC).
With this approach, motion estimates are always available, they are refined over time, the algorithm adapts to scene changes, and the amount of computation between frames is kept fixed. The psychophysical implications of temporal continuity are discussed and the power of the incremental minimization framework is demonstrated by extending image feature extraction over time.