Your search keyword '"Tewari, Ayush"' showing total 46 results

1. Diffusion Posterior Illumination for Ambiguity-aware Inverse Rendering

Author

Lyu, Linjie, Tewari, Ayush, Habermann, Marc, Saito, Shunsuke, Zollh?fer, Michael, Leimk?hler, Thomas, Theobalt, Christian, Lyu, Linjie, Tewari, Ayush, Habermann, Marc, Saito, Shunsuke, Zollh?fer, Michael, Leimk?hler, Thomas, and Theobalt, Christian

Abstract

Inverse rendering, the process of inferring scene properties from images, is a challenging inverse problem. The task is ill-posed, as many different scene configurations can give rise to the same image. Most existing solutions incorporate priors into the inverse-rendering pipeline to encourage plausible solutions, but they do not consider the inherent ambiguities and the multi-modal distribution of possible decompositions. In this work, we propose a novel scheme that integrates a denoising diffusion probabilistic model pre-trained on natural illumination maps into an optimization framework involving a differentiable path tracer. The proposed method allows sampling from combinations of illumination and spatially-varying surface materials that are, both, natural and explain the image observations. We further conduct an extensive comparative study of different priors on illumination used in previous work on inverse rendering. Our method excels in recovering materials and producing highly realistic and diverse environment map samples that faithfully explain the illumination of the input images.

Published

2024

2. AvatarStudio: Text-driven Editing of 3D Dynamic Human Head Avatars

Author

Mendiratta, Mohit, Pan, Xingang, Elgharib, Mohamed, Teotia, Kartik, B R, Mallikarjun, Tewari, Ayush, Golyanik, Vladislav, Kortylewski, Adam, Theobalt, Christian, Mendiratta, Mohit, Pan, Xingang, Elgharib, Mohamed, Teotia, Kartik, B R, Mallikarjun, Tewari, Ayush, Golyanik, Vladislav, Kortylewski, Adam, and Theobalt, Christian

Abstract

Capturing and editing full-head performances enables the creation of virtual characters with various applications such as extended reality and media production. The past few years witnessed a steep rise in the photorealism of human head avatars. Such avatars can be controlled through different input data modalities, including RGB, audio, depth, IMUs, and others. While these data modalities provide effective means of control, they mostly focus on editing the head movements such as the facial expressions, head pose, and/or camera viewpoint. In this paper, we propose AvatarStudio, a text-based method for editing the appearance of a dynamic full head avatar. Our approach builds on existing work to capture dynamic performances of human heads using Neural Radiance Field (NeRF) and edits this representation with a text-to-image diffusion model. Specifically, we introduce an optimization strategy for incorporating multiple keyframes representing different camera viewpoints and time stamps of a video performance into a single diffusion model. Using this personalized diffusion model, we edit the dynamic NeRF by introducing view-and-time-aware Score Distillation Sampling (VT-SDS) following a model-based guidance approach. Our method edits the full head in a canonical space and then propagates these edits to the remaining time steps via a pre-trained deformation network. We evaluate our method visually and numerically via a user study, and results show that our method outperforms existing approaches. Our experiments validate the design choices of our method and highlight that our edits are genuine, personalized, as well as 3D- and time-consistent.

Published

2024

3. FlowMap: High-Quality Camera Poses, Intrinsics, and Depth via Gradient Descent

Author

Smith, Cameron, Charatan, David, Tewari, Ayush, Sitzmann, Vincent, Smith, Cameron, Charatan, David, Tewari, Ayush, and Sitzmann, Vincent

Abstract

This paper introduces FlowMap, an end-to-end differentiable method that solves for precise camera poses, camera intrinsics, and per-frame dense depth of a video sequence. Our method performs per-video gradient-descent minimization of a simple least-squares objective that compares the optical flow induced by depth, intrinsics, and poses against correspondences obtained via off-the-shelf optical flow and point tracking. Alongside the use of point tracks to encourage long-term geometric consistency, we introduce differentiable re-parameterizations of depth, intrinsics, and pose that are amenable to first-order optimization. We empirically show that camera parameters and dense depth recovered by our method enable photo-realistic novel view synthesis on 360-degree trajectories using Gaussian Splatting. Our method not only far outperforms prior gradient-descent based bundle adjustment methods, but surprisingly performs on par with COLMAP, the state-of-the-art SfM method, on the downstream task of 360-degree novel view synthesis (even though our method is purely gradient-descent based, fully differentiable, and presents a complete departure from conventional SfM)., Comment: Project website: https://cameronosmith.github.io/flowmap

Published

2024

4. Drag Your GAN: Interactive Point-based Manipulation on the Generative Image Manifold

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Pan, Xingang, Tewari, Ayush, Leimk?hler, Thomas, Liu, Lingjie, Meka, Abhimitra, Theobalt, Christian, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Pan, Xingang, Tewari, Ayush, Leimk?hler, Thomas, Liu, Lingjie, Meka, Abhimitra, and Theobalt, Christian

Published

2023

5. A Deeper Analysis of Volumetric Relightiable Faces

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Rao, Pramod, Mallikarjun, B. R., Fox, Gereon, Weyrich, Tim, Bickel, Bernd, Pfister, Hanspeter, Matusik, Wojciech, Zhan, Fangneng, Tewari, Ayush, Theobalt, Christian, Elgharib, Mohamed, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Rao, Pramod, Mallikarjun, B. R., Fox, Gereon, Weyrich, Tim, Bickel, Bernd, Pfister, Hanspeter, Matusik, Wojciech, Zhan, Fangneng, Tewari, Ayush, Theobalt, Christian, and Elgharib, Mohamed

Abstract

Portrait viewpoint and illumination editing is an important problem with several applications in VR/AR, movies, and photography. Comprehensive knowledge of geometry and illumination is critical for obtaining photorealistic results. Current methods are unable to explicitly model in 3D while handling both viewpoint and illumination editing from a single image. In this paper, we propose VoRF, a novel approach that can take even a single portrait image as input and relight human heads under novel illuminations that can be viewed from arbitrary viewpoints. VoRF represents a human head as a continuous volumetric field and learns a prior model of human heads using a coordinate-based MLP with individual latent spaces for identity and illumination. The prior model is learned in an auto-decoder manner over a diverse class of head shapes and appearances, allowing VoRF to generalize to novel test identities from a single input image. Additionally, VoRF has a reflectance MLP that uses the intermediate features of the prior model for rendering One-Light-at-A-Time (OLAT) images under novel views. We synthesize novel illuminations by combining these OLAT images with target environment maps. Qualitative and quantitative evaluations demonstrate the effectiveness of VoRF for relighting and novel view synthesis, even when applied to unseen subjects under uncontrolled illumination. This work is an extension of Rao et al. (VoRF: Volumetric Relightable Faces 2022). We provide extensive evaluation and ablative studies of our model and also provide an application, where any face can be relighted using textual input.

Published

2023

6. ConceptFusion: Open-set Multimodal 3D Mapping

Author

Jatavallabhula, Krishna Murthy, Kuwajerwala, Alihusein, Gu, Qiao, Omama, Mohd, Chen, Tao, Maalouf, Alaa, Li, Shuang, Iyer, Ganesh, Saryazdi, Soroush, Keetha, Nikhil, Tewari, Ayush, Tenenbaum, Joshua B., de Melo, Celso Miguel, Krishna, Madhava, Paull, Liam, Shkurti, Florian, Torralba, Antonio, Jatavallabhula, Krishna Murthy, Kuwajerwala, Alihusein, Gu, Qiao, Omama, Mohd, Chen, Tao, Maalouf, Alaa, Li, Shuang, Iyer, Ganesh, Saryazdi, Soroush, Keetha, Nikhil, Tewari, Ayush, Tenenbaum, Joshua B., de Melo, Celso Miguel, Krishna, Madhava, Paull, Liam, Shkurti, Florian, and Torralba, Antonio

Abstract

Building 3D maps of the environment is central to robot navigation, planning, and interaction with objects in a scene. Most existing approaches that integrate semantic concepts with 3D maps largely remain confined to the closed-set setting: they can only reason about a finite set of concepts, pre-defined at training time. Further, these maps can only be queried using class labels, or in recent work, using text prompts. We address both these issues with ConceptFusion, a scene representation that is (1) fundamentally open-set, enabling reasoning beyond a closed set of concepts and (ii) inherently multimodal, enabling a diverse range of possible queries to the 3D map, from language, to images, to audio, to 3D geometry, all working in concert. ConceptFusion leverages the open-set capabilities of today's foundation models pre-trained on internet-scale data to reason about concepts across modalities such as natural language, images, and audio. We demonstrate that pixel-aligned open-set features can be fused into 3D maps via traditional SLAM and multi-view fusion approaches. This enables effective zero-shot spatial reasoning, not needing any additional training or finetuning, and retains long-tailed concepts better than supervised approaches, outperforming them by more than 40% margin on 3D IoU. We extensively evaluate ConceptFusion on a number of real-world datasets, simulated home environments, a real-world tabletop manipulation task, and an autonomous driving platform. We showcase new avenues for blending foundation models with 3D open-set multimodal mapping. For more information, visit our project page https://concept-fusion.github.io or watch our 5-minute explainer video https://www.youtube.com/watch?v=rkXgws8fiDs, Comment: RSS 2023. Project page: https://concept-fusion.github.io Explainer video: https://www.youtube.com/watch?v=rkXgws8fiDs Code: https://github.com/concept-fusion/concept-fusion

Published

2023

7. AvatarStudio: Text-driven Editing of 3D Dynamic Human Head Avatars

Author

Mendiratta, Mohit, Pan, Xingang, Elgharib, Mohamed, Teotia, Kartik, R, Mallikarjun B, Tewari, Ayush, Golyanik, Vladislav, Kortylewski, Adam, Theobalt, Christian, Mendiratta, Mohit, Pan, Xingang, Elgharib, Mohamed, Teotia, Kartik, R, Mallikarjun B, Tewari, Ayush, Golyanik, Vladislav, Kortylewski, Adam, and Theobalt, Christian

Abstract

Capturing and editing full head performances enables the creation of virtual characters with various applications such as extended reality and media production. The past few years witnessed a steep rise in the photorealism of human head avatars. Such avatars can be controlled through different input data modalities, including RGB, audio, depth, IMUs and others. While these data modalities provide effective means of control, they mostly focus on editing the head movements such as the facial expressions, head pose and/or camera viewpoint. In this paper, we propose AvatarStudio, a text-based method for editing the appearance of a dynamic full head avatar. Our approach builds on existing work to capture dynamic performances of human heads using neural radiance field (NeRF) and edits this representation with a text-to-image diffusion model. Specifically, we introduce an optimization strategy for incorporating multiple keyframes representing different camera viewpoints and time stamps of a video performance into a single diffusion model. Using this personalized diffusion model, we edit the dynamic NeRF by introducing view-and-time-aware Score Distillation Sampling (VT-SDS) following a model-based guidance approach. Our method edits the full head in a canonical space, and then propagates these edits to remaining time steps via a pretrained deformation network. We evaluate our method visually and numerically via a user study, and results show that our method outperforms existing approaches. Our experiments validate the design choices of our method and highlight that our edits are genuine, personalized, as well as 3D- and time-consistent., Comment: 17 pages, 17 figures. Project page: https://vcai.mpi-inf.mpg.de/projects/AvatarStudio

Published

2023

8. FlowCam: Training Generalizable 3D Radiance Fields without Camera Poses via Pixel-Aligned Scene Flow

Author

Smith, Cameron, Du, Yilun, Tewari, Ayush, Sitzmann, Vincent, Smith, Cameron, Du, Yilun, Tewari, Ayush, and Sitzmann, Vincent

Abstract

Reconstruction of 3D neural fields from posed images has emerged as a promising method for self-supervised representation learning. The key challenge preventing the deployment of these 3D scene learners on large-scale video data is their dependence on precise camera poses from structure-from-motion, which is prohibitively expensive to run at scale. We propose a method that jointly reconstructs camera poses and 3D neural scene representations online and in a single forward pass. We estimate poses by first lifting frame-to-frame optical flow to 3D scene flow via differentiable rendering, preserving locality and shift-equivariance of the image processing backbone. SE(3) camera pose estimation is then performed via a weighted least-squares fit to the scene flow field. This formulation enables us to jointly supervise pose estimation and a generalizable neural scene representation via re-rendering the input video, and thus, train end-to-end and fully self-supervised on real-world video datasets. We demonstrate that our method performs robustly on diverse, real-world video, notably on sequences traditionally challenging to optimization-based pose estimation techniques., Comment: Project website: http://cameronosmith.github.io/flowcam

Published

2023

9. Drag Your GAN: Interactive Point-based Manipulation on the Generative Image Manifold

Author

Pan, Xingang, Tewari, Ayush, Leimkühler, Thomas, Liu, Lingjie, Meka, Abhimitra, Theobalt, Christian, Pan, Xingang, Tewari, Ayush, Leimkühler, Thomas, Liu, Lingjie, Meka, Abhimitra, and Theobalt, Christian

Abstract

Synthesizing visual content that meets users' needs often requires flexible and precise controllability of the pose, shape, expression, and layout of the generated objects. Existing approaches gain controllability of generative adversarial networks (GANs) via manually annotated training data or a prior 3D model, which often lack flexibility, precision, and generality. In this work, we study a powerful yet much less explored way of controlling GANs, that is, to "drag" any points of the image to precisely reach target points in a user-interactive manner, as shown in Fig.1. To achieve this, we propose DragGAN, which consists of two main components: 1) a feature-based motion supervision that drives the handle point to move towards the target position, and 2) a new point tracking approach that leverages the discriminative generator features to keep localizing the position of the handle points. Through DragGAN, anyone can deform an image with precise control over where pixels go, thus manipulating the pose, shape, expression, and layout of diverse categories such as animals, cars, humans, landscapes, etc. As these manipulations are performed on the learned generative image manifold of a GAN, they tend to produce realistic outputs even for challenging scenarios such as hallucinating occluded content and deforming shapes that consistently follow the object's rigidity. Both qualitative and quantitative comparisons demonstrate the advantage of DragGAN over prior approaches in the tasks of image manipulation and point tracking. We also showcase the manipulation of real images through GAN inversion., Comment: Accepted to SIGGRAPH 2023. Project page: https://vcai.mpi-inf.mpg.de/projects/DragGAN

Published

2023

10. Learning to Render Novel Views from Wide-Baseline Stereo Pairs

Author

Du, Yilun, Smith, Cameron, Tewari, Ayush, Sitzmann, Vincent, Du, Yilun, Smith, Cameron, Tewari, Ayush, and Sitzmann, Vincent

Abstract

We introduce a method for novel view synthesis given only a single wide-baseline stereo image pair. In this challenging regime, 3D scene points are regularly observed only once, requiring prior-based reconstruction of scene geometry and appearance. We find that existing approaches to novel view synthesis from sparse observations fail due to recovering incorrect 3D geometry and due to the high cost of differentiable rendering that precludes their scaling to large-scale training. We take a step towards resolving these shortcomings by formulating a multi-view transformer encoder, proposing an efficient, image-space epipolar line sampling scheme to assemble image features for a target ray, and a lightweight cross-attention-based renderer. Our contributions enable training of our method on a large-scale real-world dataset of indoor and outdoor scenes. We demonstrate that our method learns powerful multi-view geometry priors while reducing the rendering time. We conduct extensive comparisons on held-out test scenes across two real-world datasets, significantly outperforming prior work on novel view synthesis from sparse image observations and achieving multi-view-consistent novel view synthesis., Comment: CVPR 2023, Project Webpage: https://yilundu.github.io/wide_baseline/, Last Two Authors Equal Advising

Published

2023

11. Diffusion Posterior Illumination for Ambiguity-aware Inverse Rendering

Author

Lyu, Linjie, Tewari, Ayush, Habermann, Marc, Saito, Shunsuke, Zollhöfer, Michael, Leimkühler, Thomas, Theobalt, Christian, Lyu, Linjie, Tewari, Ayush, Habermann, Marc, Saito, Shunsuke, Zollhöfer, Michael, Leimkühler, Thomas, and Theobalt, Christian

Abstract

Inverse rendering, the process of inferring scene properties from images, is a challenging inverse problem. The task is ill-posed, as many different scene configurations can give rise to the same image. Most existing solutions incorporate priors into the inverse-rendering pipeline to encourage plausible solutions, but they do not consider the inherent ambiguities and the multi-modal distribution of possible decompositions. In this work, we propose a novel scheme that integrates a denoising diffusion probabilistic model pre-trained on natural illumination maps into an optimization framework involving a differentiable path tracer. The proposed method allows sampling from combinations of illumination and spatially-varying surface materials that are, both, natural and explain the image observations. We further conduct an extensive comparative study of different priors on illumination used in previous work on inverse rendering. Our method excels in recovering materials and producing highly realistic and diverse environment map samples that faithfully explain the illumination of the input images., Comment: SIGGRAPH Asia 2023

Published

2023

12. Approaching human 3D shape perception with neurally mappable models

Author

O'Connell, Thomas P., Bonnen, Tyler, Friedman, Yoni, Tewari, Ayush, Tenenbaum, Josh B., Sitzmann, Vincent, Kanwisher, Nancy, O'Connell, Thomas P., Bonnen, Tyler, Friedman, Yoni, Tewari, Ayush, Tenenbaum, Josh B., Sitzmann, Vincent, and Kanwisher, Nancy

Abstract

Humans effortlessly infer the 3D shape of objects. What computations underlie this ability? Although various computational models have been proposed, none of them capture the human ability to match object shape across viewpoints. Here, we ask whether and how this gap might be closed. We begin with a relatively novel class of computational models, 3D neural fields, which encapsulate the basic principles of classic analysis-by-synthesis in a deep neural network (DNN). First, we find that a 3D Light Field Network (3D-LFN) supports 3D matching judgments well aligned to humans for within-category comparisons, adversarially-defined comparisons that accentuate the 3D failure cases of standard DNN models, and adversarially-defined comparisons for algorithmically generated shapes with no category structure. We then investigate the source of the 3D-LFN's ability to achieve human-aligned performance through a series of computational experiments. Exposure to multiple viewpoints of objects during training and a multi-view learning objective are the primary factors behind model-human alignment; even conventional DNN architectures come much closer to human behavior when trained with multi-view objectives. Finally, we find that while the models trained with multi-view learning objectives are able to partially generalize to new object categories, they fall short of human alignment. This work provides a foundation for understanding human shape inferences within neurally mappable computational architectures.

Published

2023

13. Diffusion with Forward Models: Solving Stochastic Inverse Problems Without Direct Supervision

Author

Tewari, Ayush, Yin, Tianwei, Cazenavette, George, Rezchikov, Semon, Tenenbaum, Joshua B., Durand, Frédo, Freeman, William T., Sitzmann, Vincent, Tewari, Ayush, Yin, Tianwei, Cazenavette, George, Rezchikov, Semon, Tenenbaum, Joshua B., Durand, Frédo, Freeman, William T., and Sitzmann, Vincent

Abstract

Denoising diffusion models are a powerful type of generative models used to capture complex distributions of real-world signals. However, their applicability is limited to scenarios where training samples are readily available, which is not always the case in real-world applications. For example, in inverse graphics, the goal is to generate samples from a distribution of 3D scenes that align with a given image, but ground-truth 3D scenes are unavailable and only 2D images are accessible. To address this limitation, we propose a novel class of denoising diffusion probabilistic models that learn to sample from distributions of signals that are never directly observed. Instead, these signals are measured indirectly through a known differentiable forward model, which produces partial observations of the unknown signal. Our approach involves integrating the forward model directly into the denoising process. This integration effectively connects the generative modeling of observations with the generative modeling of the underlying signals, allowing for end-to-end training of a conditional generative model over signals. During inference, our approach enables sampling from the distribution of underlying signals that are consistent with a given partial observation. We demonstrate the effectiveness of our method on three challenging computer vision tasks. For instance, in the context of inverse graphics, our model enables direct sampling from the distribution of 3D scenes that align with a single 2D input image., Comment: Project page: https://diffusion-with-forward-models.github.io

Published

2023

14. gCoRF: Generative Compositional Radiance Fields

Author

BR, Mallikarjun, Tewari, Ayush, Pan, Xingang, Elgharib, Mohamed, Theobalt, Christian, BR, Mallikarjun, Tewari, Ayush, Pan, Xingang, Elgharib, Mohamed, and Theobalt, Christian

Abstract

3D generative models of objects enable photorealistic image synthesis with 3D control. Existing methods model the scene as a global scene representation, ignoring the compositional aspect of the scene. Compositional reasoning can enable a wide variety of editing applications, in addition to enabling generalizable 3D reasoning. In this paper, we present a compositional generative model, where each semantic part of the object is represented as an independent 3D representation learned from only in-the-wild 2D data. We start with a global generative model (GAN) and learn to decompose it into different semantic parts using supervision from 2D segmentation masks. We then learn to composite independently sampled parts in order to create coherent global scenes. Different parts can be independently sampled while keeping the rest of the object fixed. We evaluate our method on a wide variety of objects and parts and demonstrate editing applications., Comment: https://vcai.mpi-inf.mpg.de/projects/gCoRF

Published

2022

15. Neural Radiance Transfer Fields for Relightable Novel-view Synthesis with Global Illumination

Author

Lyu, Linjie, Tewari, Ayush, Leimkuehler, Thomas, Habermann, Marc, Theobalt, Christian, Lyu, Linjie, Tewari, Ayush, Leimkuehler, Thomas, Habermann, Marc, and Theobalt, Christian

Abstract

Given a set of images of a scene, the re-rendering of this scene from novel views and lighting conditions is an important and challenging problem in Computer Vision and Graphics. On the one hand, most existing works in Computer Vision usually impose many assumptions regarding the image formation process, e.g. direct illumination and predefined materials, to make scene parameter estimation tractable. On the other hand, mature Computer Graphics tools allow modeling of complex photo-realistic light transport given all the scene parameters. Combining these approaches, we propose a method for scene relighting under novel views by learning a neural precomputed radiance transfer function, which implicitly handles global illumination effects using novel environment maps. Our method can be solely supervised on a set of real images of the scene under a single unknown lighting condition. To disambiguate the task during training, we tightly integrate a differentiable path tracer in the training process and propose a combination of a synthesized OLAT and a real image loss. Results show that the recovered disentanglement of scene parameters improves significantly over the current state of the art and, thus, also our re-rendering results are more realistic and accurate.

Published

2022

16. Neural Groundplans: Persistent Neural Scene Representations from a Single Image

Author

Sharma, Prafull, Tewari, Ayush, Du, Yilun, Zakharov, Sergey, Ambrus, Rares, Gaidon, Adrien, Freeman, William T., Durand, Fredo, Tenenbaum, Joshua B., Sitzmann, Vincent, Sharma, Prafull, Tewari, Ayush, Du, Yilun, Zakharov, Sergey, Ambrus, Rares, Gaidon, Adrien, Freeman, William T., Durand, Fredo, Tenenbaum, Joshua B., and Sitzmann, Vincent

Abstract

We present a method to map 2D image observations of a scene to a persistent 3D scene representation, enabling novel view synthesis and disentangled representation of the movable and immovable components of the scene. Motivated by the bird's-eye-view (BEV) representation commonly used in vision and robotics, we propose conditional neural groundplans, ground-aligned 2D feature grids, as persistent and memory-efficient scene representations. Our method is trained self-supervised from unlabeled multi-view observations using differentiable rendering, and learns to complete geometry and appearance of occluded regions. In addition, we show that we can leverage multi-view videos at training time to learn to separately reconstruct static and movable components of the scene from a single image at test time. The ability to separately reconstruct movable objects enables a variety of downstream tasks using simple heuristics, such as extraction of object-centric 3D representations, novel view synthesis, instance-level segmentation, 3D bounding box prediction, and scene editing. This highlights the value of neural groundplans as a backbone for efficient 3D scene understanding models., Comment: Project page: https://prafullsharma.net/neural_groundplans

Published

2022

17. FIRe: Fast Inverse Rendering using Directional and Signed Distance Functions

Author

Yenamandra, Tarun, Tewari, Ayush, Yang, Nan, Bernard, Florian, Theobalt, Christian, Cremers, Daniel, Yenamandra, Tarun, Tewari, Ayush, Yang, Nan, Bernard, Florian, Theobalt, Christian, and Cremers, Daniel

Abstract

Neural 3D implicit representations learn priors that are useful for diverse applications, such as single- or multiple-view 3D reconstruction. A major downside of existing approaches while rendering an image is that they require evaluating the network multiple times per camera ray so that the high computational time forms a bottleneck for downstream applications. We address this problem by introducing a novel neural scene representation that we call the directional distance function (DDF). To this end, we learn a signed distance function (SDF) along with our DDF model to represent a class of shapes. Specifically, our DDF is defined on the unit sphere and predicts the distance to the surface along any given direction. Therefore, our DDF allows rendering images with just a single network evaluation per camera ray. Based on our DDF, we present a novel fast algorithm (FIRe) to reconstruct 3D shapes given a posed depth map. We evaluate our proposed method on 3D reconstruction from single-view depth images, where we empirically show that our algorithm reconstructs 3D shapes more accurately and it is more than 15 times faster (per iteration) than competing methods., Comment: News: Accepted to WACV'24. Project page: https://vision.in.tum.de/research/geometry/fire

Published

2022

18. Disentangled3D: Learning a 3D Generative Model with Disentangled Geometry and Appearance from Monocular Images

Author

Tewari, Ayush, R, Mallikarjun B, Pan, Xingang, Fried, Ohad, Agrawala, Maneesh, Theobalt, Christian, Tewari, Ayush, R, Mallikarjun B, Pan, Xingang, Fried, Ohad, Agrawala, Maneesh, and Theobalt, Christian

Abstract

Learning 3D generative models from a dataset of monocular images enables self-supervised 3D reasoning and controllable synthesis. State-of-the-art 3D generative models are GANs which use neural 3D volumetric representations for synthesis. Images are synthesized by rendering the volumes from a given camera. These models can disentangle the 3D scene from the camera viewpoint in any generated image. However, most models do not disentangle other factors of image formation, such as geometry and appearance. In this paper, we design a 3D GAN which can learn a disentangled model of objects, just from monocular observations. Our model can disentangle the geometry and appearance variations in the scene, i.e., we can independently sample from the geometry and appearance spaces of the generative model. This is achieved using a novel non-rigid deformable scene formulation. A 3D volume which represents an object instance is computed as a non-rigidly deformed canonical 3D volume. Our method learns the canonical volume, as well as its deformations, jointly during training. This formulation also helps us improve the disentanglement between the 3D scene and the camera viewpoints using a novel pose regularization loss defined on the 3D deformation field. In addition, we further model the inverse deformations, enabling the computation of dense correspondences between images generated by our model. Finally, we design an approach to embed real images into the latent space of our disentangled generative model, enabling editing of real images., Comment: CVPR 2022

Published

2022

19. PhotoApp

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, R, Mallikarjun B, Tewari, Ayush, Dib, Abdallah, Weyrich, Tim, Bickel, Bernd, Seidel, Hans-Peter, Pfister, Hanspeter, Matusik, Wojciech, Chevallier, Louis, Elgharib, Mohamed, Theobalt, Christian, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, R, Mallikarjun B, Tewari, Ayush, Dib, Abdallah, Weyrich, Tim, Bickel, Bernd, Seidel, Hans-Peter, Pfister, Hanspeter, Matusik, Wojciech, Chevallier, Louis, Elgharib, Mohamed, and Theobalt, Christian

Abstract

Photorealistic editing of head portraits is a challenging task as humans are very sensitive to inconsistencies in faces. We present an approach for high-quality intuitive editing of the camera viewpoint and scene illumination (parameterised with an environment map) in a portrait image. This requires our method to capture and control the full reflectance field of the person in the image. Most editing approaches rely on supervised learning using training data captured with setups such as light and camera stages. Such datasets are expensive to acquire, not readily available and do not capture all the rich variations of in-the-wild portrait images. In addition, most supervised approaches only focus on relighting, and do not allow camera viewpoint editing. Thus, they only capture and control a subset of the reflectance field. Recently, portrait editing has been demonstrated by operating in the generative model space of StyleGAN. While such approaches do not require direct supervision, there is a significant loss of quality when compared to the supervised approaches. In this paper, we present a method which learns from limited supervised training data. The training images only include people in a fixed neutral expression with eyes closed, without much hair or background variations. Each person is captured under 150 one-light-at-a-time conditions and under 8 camera poses. Instead of training directly in the image space, we design a supervised problem which learns transformations in the latent space of StyleGAN. This combines the best of supervised learning and generative adversarial modeling. We show that the StyleGAN prior allows for generalisation to different expressions, hairstyles and backgrounds. This produces high-quality photorealistic results for in-the-wild images and significantly outperforms existing methods. Our approach can edit the illumination and pose simultaneously, and runs at interactive rates.

Published

2022

20. GAN2X: Non-Lambertian Inverse Rendering of Image GANs

Author

Pan, Xingang, Tewari, Ayush, Liu, Lingjie, Theobalt, Christian, Pan, Xingang, Tewari, Ayush, Liu, Lingjie, and Theobalt, Christian

Abstract

2D images are observations of the 3D physical world depicted with the geometry, material, and illumination components. Recovering these underlying intrinsic components from 2D images, also known as inverse rendering, usually requires a supervised setting with paired images collected from multiple viewpoints and lighting conditions, which is resource-demanding. In this work, we present GAN2X, a new method for unsupervised inverse rendering that only uses unpaired images for training. Unlike previous Shape-from-GAN approaches that mainly focus on 3D shapes, we take the first attempt to also recover non-Lambertian material properties by exploiting the pseudo paired data generated by a GAN. To achieve precise inverse rendering, we devise a specularity-aware neural surface representation that continuously models the geometry and material properties. A shading-based refinement technique is adopted to further distill information in the target image and recover more fine details. Experiments demonstrate that GAN2X can accurately decompose 2D images to 3D shape, albedo, and specular properties for different object categories, and achieves the state-of-the-art performance for unsupervised single-view 3D face reconstruction. We also show its applications in downstream tasks including real image editing and lifting 2D GANs to decomposed 3D GANs., Comment: Accepted to 3DV 2022. The video demo is available at the project page: https://vcai.mpi-inf.mpg.de/projects/GAN2X

Published

2022

21. Advances in Neural Rendering

Author

Tewari, Ayush, Thies, Justus, Mildenhall, Ben, Srinivasan, Pratul, Tretschk, Edgar, Wang, Yifan, Lassner, Christoph, Sitzmann, Vincent, Martin-Brualla, Ricardo, Lombardi, Stephen, Simon, Tomas, Theobalt, Christian, Niessner, Matthias, Barron, Jonathan T., Wetzstein, Gordon, Zollhoefer, Michael, Golyanik, Vladislav, Tewari, Ayush, Thies, Justus, Mildenhall, Ben, Srinivasan, Pratul, Tretschk, Edgar, Wang, Yifan, Lassner, Christoph, Sitzmann, Vincent, Martin-Brualla, Ricardo, Lombardi, Stephen, Simon, Tomas, Theobalt, Christian, Niessner, Matthias, Barron, Jonathan T., Wetzstein, Gordon, Zollhoefer, Michael, and Golyanik, Vladislav

Abstract

Synthesizing photo-realistic images and videos is at the heart of computer graphics and has been the focus of decades of research. Traditionally, synthetic images of a scene are generated using rendering algorithms such as rasterization or ray tracing, which take specifically defined representations of geometry and material properties as input. Collectively, these inputs define the actual scene and what is rendered, and are referred to as the scene representation (where a scene consists of one or more objects). Example scene representations are triangle meshes with accompanied textures (e.g., created by an artist), point clouds (e.g., from a depth sensor), volumetric grids (e.g., from a CT scan), or implicit surface functions (e.g., truncated signed distance fields). The reconstruction of such a scene representation from observations using differentiable rendering losses is known as inverse graphics or inverse rendering. Neural rendering is closely related, and combines ideas from classical computer graphics and machine learning to create algorithms for synthesizing images from real-world observations. Neural rendering is a leap forward towards the goal of synthesizing photo-realistic image and video content. In recent years, we have seen immense progress in this field through hundreds of publications that show different ways to inject learnable components into the rendering pipeline. This state-of-the-art report on advances in neural rendering focuses on methods that combine classical rendering principles with learned 3D scene representations, often now referred to as neural scene representations. A key advantage of these methods is that they are 3D-consistent by design, enabling applications such as novel viewpoint synthesis of a captured scene. In addition to methods that handle static scenes, we cover neural scene representations for modeling non-rigidly deforming objects..., Comment: 33 pages, 14 figures, 5 tables; State of the Art Report at EUROGRAPHICS 2022

Published

2021

22. PhotoApp

Author

R, Mallikarjun B, Tewari, Ayush, Dib, Abdallah, Weyrich, Tim, Bickel, Bernd, Seidel, Hans-Peter, Pfister, Hanspeter, Matusik, Wojciech, Chevallier, Louis, Elgharib, Mohamed, Theobalt, Christian, R, Mallikarjun B, Tewari, Ayush, Dib, Abdallah, Weyrich, Tim, Bickel, Bernd, Seidel, Hans-Peter, Pfister, Hanspeter, Matusik, Wojciech, Chevallier, Louis, Elgharib, Mohamed, and Theobalt, Christian

Abstract

Photorealistic editing of head portraits is a challenging task as humans are very sensitive to inconsistencies in faces. We present an approach for high-quality intuitive editing of the camera viewpoint and scene illumination (parameterised with an environment map) in a portrait image. This requires our method to capture and control the full reflectance field of the person in the image. Most editing approaches rely on supervised learning using training data captured with setups such as light and camera stages. Such datasets are expensive to acquire, not readily available and do not capture all the rich variations of in-the-wild portrait images. In addition, most supervised approaches only focus on relighting, and do not allow camera viewpoint editing. Thus, they only capture and control a subset of the reflectance field. Recently, portrait editing has been demonstrated by operating in the generative model space of StyleGAN. While such approaches do not require direct supervision, there is a significant loss of quality when compared to the supervised approaches. In this paper, we present a method which learns from limited supervised training data. The training images only include people in a fixed neutral expression with eyes closed, without much hair or background variations. Each person is captured under 150 one-light-at-a-time conditions and under 8 camera poses. Instead of training directly in the image space, we design a supervised problem which learns transformations in the latent space of StyleGAN. This combines the best of supervised learning and generative adversarial modeling. We show that the StyleGAN prior allows for generalisation to different expressions, hairstyles and backgrounds. This produces high-quality photorealistic results for in-the-wild images and significantly outperforms existing methods. Our approach can edit the illumination and pose simultaneously, and runs at interactive rates.

Published

2021

23. StyleVideoGAN: A Temporal Generative Model using a Pretrained StyleGAN

Author

Fox, Gereon, Tewari, Ayush, Elgharib, Mohamed, Theobalt, Christian, Fox, Gereon, Tewari, Ayush, Elgharib, Mohamed, and Theobalt, Christian

Abstract

Generative adversarial models (GANs) continue to produce advances in terms of the visual quality of still images, as well as the learning of temporal correlations. However, few works manage to combine these two interesting capabilities for the synthesis of video content: Most methods require an extensive training dataset to learn temporal correlations, while being rather limited in the resolution and visual quality of their output. We present a novel approach to the video synthesis problem that helps to greatly improve visual quality and drastically reduce the amount of training data and resources necessary for generating videos. Our formulation separates the spatial domain, in which individual frames are synthesized, from the temporal domain, in which motion is generated. For the spatial domain we use a pre-trained StyleGAN network, the latent space of which allows control over the appearance of the objects it was trained for. The expressive power of this model allows us to embed our training videos in the StyleGAN latent space. Our temporal architecture is then trained not on sequences of RGB frames, but on sequences of StyleGAN latent codes. The advantageous properties of the StyleGAN space simplify the discovery of temporal correlations. We demonstrate that it suffices to train our temporal architecture on only 10 minutes of footage of 1 subject for about 6 hours. After training, our model can not only generate new portrait videos for the training subject, but also for any random subject which can be embedded in the StyleGAN space., Comment: Final draft

Published

2021

24. Egocentric Videoconferencing

Author

Elgharib, Mohamed, Mendiratta, Mohit, Thies, Justus, Nießner, Matthias, Seidel, Hans-Peter, Tewari, Ayush, Golyanik, Vladislav, Theobalt, Christian, Elgharib, Mohamed, Mendiratta, Mohit, Thies, Justus, Nießner, Matthias, Seidel, Hans-Peter, Tewari, Ayush, Golyanik, Vladislav, and Theobalt, Christian

Abstract

We introduce a method for egocentric videoconferencing that enables hands-free video calls, for instance by people wearing smart glasses or other mixed-reality devices. Videoconferencing portrays valuable non-verbal communication and face expression cues, but usually requires a front-facing camera. Using a frontal camera in a hands-free setting when a person is on the move is impractical. Even holding a mobile phone camera in the front of the face while sitting for a long duration is not convenient. To overcome these issues, we propose a low-cost wearable egocentric camera setup that can be integrated into smart glasses. Our goal is to mimic a classical video call, and therefore, we transform the egocentric perspective of this camera into a front facing video. To this end, we employ a conditional generative adversarial neural network that learns a transition from the highly distorted egocentric views to frontal views common in videoconferencing. Our approach learns to transfer expression details directly from the egocentric view without using a complex intermediate parametric expressions model, as it is used by related face reenactment methods. We successfully handle subtle expressions, not easily captured by parametric blendshape-based solutions, e.g., tongue movement, eye movements, eye blinking, strong expressions and depth varying movements. To get control over the rigid head movements in the target view, we condition the generator on synthetic renderings of a moving neutral face. This allows us to synthesis results at different head poses. Our technique produces temporally smooth video-realistic renderings in real-time using a video-to-video translation network in conjunction with a temporal discriminator. We demonstrate the improved capabilities of our technique by comparing against related state-of-the art approaches., Comment: Mohamed Elgharib and Mohit Mendiratta contributed equally to this work. http://gvv.mpi-inf.mpg.de/projects/EgoChat

Published

2021

25. Efficient and Differentiable Shadow Computation for Inverse Problems

Author

Lyu, Linjie, Habermann, Marc, Liu, Lingjie, R, Mallikarjun B, Tewari, Ayush, Theobalt, Christian, Lyu, Linjie, Habermann, Marc, Liu, Lingjie, R, Mallikarjun B, Tewari, Ayush, and Theobalt, Christian

Abstract

Differentiable rendering has received increasing interest for image-based inverse problems. It can benefit traditional optimization-based solutions to inverse problems, but also allows for self-supervision of learning-based approaches for which training data with ground truth annotation is hard to obtain. However, existing differentiable renderers either do not model visibility of the light sources from the different points in the scene, responsible for shadows in the images, or are too slow for being used to train deep architectures over thousands of iterations. To this end, we propose an accurate yet efficient approach for differentiable visibility and soft shadow computation. Our approach is based on the spherical harmonics approximations of the scene illumination and visibility, where the occluding surface is approximated with spheres. This allows for a significantly more efficient shadow computation compared to methods based on ray tracing. As our formulation is differentiable, it can be used to solve inverse problems such as texture, illumination, rigid pose, and geometric deformation recovery from images using analysis-by-synthesis optimization.

Published

2021

26. PhotoApp: Photorealistic Appearance Editing of Head Portraits

Author

R, Mallikarjun B, Tewari, Ayush, Dib, Abdallah, Weyrich, Tim, Bickel, Bernd, Seidel, Hans-Peter, Pfister, Hanspeter, Matusik, Wojciech, Chevallier, Louis, Elgharib, Mohamed, Theobalt, Christian, R, Mallikarjun B, Tewari, Ayush, Dib, Abdallah, Weyrich, Tim, Bickel, Bernd, Seidel, Hans-Peter, Pfister, Hanspeter, Matusik, Wojciech, Chevallier, Louis, Elgharib, Mohamed, and Theobalt, Christian

Abstract

Photorealistic editing of portraits is a challenging task as humans are very sensitive to inconsistencies in faces. We present an approach for high-quality intuitive editing of the camera viewpoint and scene illumination in a portrait image. This requires our method to capture and control the full reflectance field of the person in the image. Most editing approaches rely on supervised learning using training data captured with setups such as light and camera stages. Such datasets are expensive to acquire, not readily available and do not capture all the rich variations of in-the-wild portrait images. In addition, most supervised approaches only focus on relighting, and do not allow camera viewpoint editing. Thus, they only capture and control a subset of the reflectance field. Recently, portrait editing has been demonstrated by operating in the generative model space of StyleGAN. While such approaches do not require direct supervision, there is a significant loss of quality when compared to the supervised approaches. In this paper, we present a method which learns from limited supervised training data. The training images only include people in a fixed neutral expression with eyes closed, without much hair or background variations. Each person is captured under 150 one-light-at-a-time conditions and under 8 camera poses. Instead of training directly in the image space, we design a supervised problem which learns transformations in the latent space of StyleGAN. This combines the best of supervised learning and generative adversarial modeling. We show that the StyleGAN prior allows for generalisation to different expressions, hairstyles and backgrounds. This produces high-quality photorealistic results for in-the-wild images and significantly outperforms existing methods. Our approach can edit the illumination and pose simultaneously, and runs at interactive rates., Comment: http://gvv.mpi-inf.mpg.de/projects/PhotoApp

Published

2021

27. PatchNets: Patch-Based Generalizable Deep Implicit 3D Shape Representations

Author

Tretschk, Edgar, Tewari, Ayush, Golyanik, Vladislav, Zollhöfer, Michael, Stoll, Carsten, Theobalt, Christian, Tretschk, Edgar, Tewari, Ayush, Golyanik, Vladislav, Zollhöfer, Michael, Stoll, Carsten, and Theobalt, Christian

Abstract

Implicit surface representations, such as signed-distance functions, combined with deep learning have led to impressive models which can represent detailed shapes of objects with arbitrary topology. Since a continuous function is learned, the reconstructions can also be extracted at any arbitrary resolution. However, large datasets such as ShapeNet are required to train such models. In this paper, we present a new mid-level patch-based surface representation. At the level of patches, objects across different categories share similarities, which leads to more generalizable models. We then introduce a novel method to learn this patch-based representation in a canonical space, such that it is as object-agnostic as possible. We show that our representation trained on one category of objects from ShapeNet can also well represent detailed shapes from any other category. In addition, it can be trained using much fewer shapes, compared to existing approaches. We show several applications of our new representation, including shape interpolation and partial point cloud completion. Due to explicit control over positions, orientations and scales of patches, our representation is also more controllable compared to object-level representations, which enables us to deform encoded shapes non-rigidly., Comment: 25 pages, including supplementary material. Code: https://github.com/edgar-tr/patchnets Project page: https://gvv.mpi-inf.mpg.de/projects/PatchNets

Published

2020

28. State of the Art on Neural Rendering

Author

Tewari, Ayush, Fried, Ohad, Thies, Justus, Sitzmann, Vincent, Lombardi, Stephen, Sunkavalli, Kalyan, Martin-Brualla, Ricardo, Simon, Tomas, Saragih, Jason, Nießner, Matthias, Pandey, Rohit, Fanello, Sean, Wetzstein, Gordon, Zhu, Jun-Yan, Theobalt, Christian, Agrawala, Maneesh, Shechtman, Eli, Goldman, Dan B, Zollhöfer, Michael, Tewari, Ayush, Fried, Ohad, Thies, Justus, Sitzmann, Vincent, Lombardi, Stephen, Sunkavalli, Kalyan, Martin-Brualla, Ricardo, Simon, Tomas, Saragih, Jason, Nießner, Matthias, Pandey, Rohit, Fanello, Sean, Wetzstein, Gordon, Zhu, Jun-Yan, Theobalt, Christian, Agrawala, Maneesh, Shechtman, Eli, Goldman, Dan B, and Zollhöfer, Michael

Abstract

Efficient rendering of photo-realistic virtual worlds is a long standing effort of computer graphics. Modern graphics techniques have succeeded in synthesizing photo-realistic images from hand-crafted scene representations. However, the automatic generation of shape, materials, lighting, and other aspects of scenes remains a challenging problem that, if solved, would make photo-realistic computer graphics more widely accessible. Concurrently, progress in computer vision and machine learning have given rise to a new approach to image synthesis and editing, namely deep generative models. Neural rendering is a new and rapidly emerging field that combines generative machine learning techniques with physical knowledge from computer graphics, e.g., by the integration of differentiable rendering into network training. With a plethora of applications in computer graphics and vision, neural rendering is poised to become a new area in the graphics community, yet no survey of this emerging field exists. This state-of-the-art report summarizes the recent trends and applications of neural rendering. We focus on approaches that combine classic computer graphics techniques with deep generative models to obtain controllable and photo-realistic outputs. Starting with an overview of the underlying computer graphics and machine learning concepts, we discuss critical aspects of neural rendering approaches. This state-of-the-art report is focused on the many important use cases for the described algorithms such as novel view synthesis, semantic photo manipulation, facial and body reenactment, relighting, free-viewpoint video, and the creation of photo-realistic avatars for virtual and augmented reality telepresence. Finally, we conclude with a discussion of the social implications of such technology and investigate open research problems., Comment: Eurographics 2020 survey paper

Published

2020

29. StyleRig: Rigging StyleGAN for 3D Control over Portrait Images

Author

Tewari, Ayush, Elgharib, Mohamed, Bharaj, Gaurav, Bernard, Florian, Seidel, Hans-Peter, Pérez, Patrick, Zollhöfer, Michael, Theobalt, Christian, Tewari, Ayush, Elgharib, Mohamed, Bharaj, Gaurav, Bernard, Florian, Seidel, Hans-Peter, Pérez, Patrick, Zollhöfer, Michael, and Theobalt, Christian

Abstract

StyleGAN generates photorealistic portrait images of faces with eyes, teeth, hair and context (neck, shoulders, background), but lacks a rig-like control over semantic face parameters that are interpretable in 3D, such as face pose, expressions, and scene illumination. Three-dimensional morphable face models (3DMMs) on the other hand offer control over the semantic parameters, but lack photorealism when rendered and only model the face interior, not other parts of a portrait image (hair, mouth interior, background). We present the first method to provide a face rig-like control over a pretrained and fixed StyleGAN via a 3DMM. A new rigging network, RigNet is trained between the 3DMM's semantic parameters and StyleGAN's input. The network is trained in a self-supervised manner, without the need for manual annotations. At test time, our method generates portrait images with the photorealism of StyleGAN and provides explicit control over the 3D semantic parameters of the face., Comment: CVPR 2020 (Oral). Project page: https://gvv.mpi-inf.mpg.de/projects/StyleRig

Published

2020

30. Non-Rigid Neural Radiance Fields: Reconstruction and Novel View Synthesis of a Dynamic Scene From Monocular Video

Author

Tretschk, Edgar, Tewari, Ayush, Golyanik, Vladislav, Zollhöfer, Michael, Lassner, Christoph, Theobalt, Christian, Tretschk, Edgar, Tewari, Ayush, Golyanik, Vladislav, Zollhöfer, Michael, Lassner, Christoph, and Theobalt, Christian

Abstract

We present Non-Rigid Neural Radiance Fields (NR-NeRF), a reconstruction and novel view synthesis approach for general non-rigid dynamic scenes. Our approach takes RGB images of a dynamic scene as input (e.g., from a monocular video recording), and creates a high-quality space-time geometry and appearance representation. We show that a single handheld consumer-grade camera is sufficient to synthesize sophisticated renderings of a dynamic scene from novel virtual camera views, e.g. a `bullet-time' video effect. NR-NeRF disentangles the dynamic scene into a canonical volume and its deformation. Scene deformation is implemented as ray bending, where straight rays are deformed non-rigidly. We also propose a novel rigidity network to better constrain rigid regions of the scene, leading to more stable results. The ray bending and rigidity network are trained without explicit supervision. Our formulation enables dense correspondence estimation across views and time, and compelling video editing applications such as motion exaggeration. Our code will be open sourced., Comment: Project page (incl. supplemental videos and code): https://vcai.mpi-inf.mpg.de/projects/nonrigid_nerf/ or https://gvv.mpi-inf.mpg.de/projects/nonrigid_nerf

Published

2020

31. Monocular Real-time Full Body Capture with Inter-part Correlations

Author

Zhou, Yuxiao, Habermann, Marc, Habibie, Ikhsanul, Tewari, Ayush, Theobalt, Christian, Xu, Feng, Zhou, Yuxiao, Habermann, Marc, Habibie, Ikhsanul, Tewari, Ayush, Theobalt, Christian, and Xu, Feng

Abstract

We present the first method for real-time full body capture that estimates shape and motion of body and hands together with a dynamic 3D face model from a single color image. Our approach uses a new neural network architecture that exploits correlations between body and hands at high computational efficiency. Unlike previous works, our approach is jointly trained on multiple datasets focusing on hand, body or face separately, without requiring data where all the parts are annotated at the same time, which is much more difficult to create at sufficient variety. The possibility of such multi-dataset training enables superior generalization ability. In contrast to earlier monocular full body methods, our approach captures more expressive 3D face geometry and color by estimating the shape, expression, albedo and illumination parameters of a statistical face model. Our method achieves competitive accuracy on public benchmarks, while being significantly faster and providing more complete face reconstructions., Comment: Accepted by CVPR 2021

Published

2020

32. i3DMM: Deep Implicit 3D Morphable Model of Human Heads

Author

Yenamandra, Tarun, Tewari, Ayush, Bernard, Florian, Seidel, Hans-Peter, Elgharib, Mohamed, Cremers, Daniel, Theobalt, Christian, Yenamandra, Tarun, Tewari, Ayush, Bernard, Florian, Seidel, Hans-Peter, Elgharib, Mohamed, Cremers, Daniel, and Theobalt, Christian

Abstract

We present the first deep implicit 3D morphable model (i3DMM) of full heads. Unlike earlier morphable face models it not only captures identity-specific geometry, texture, and expressions of the frontal face, but also models the entire head, including hair. We collect a new dataset consisting of 64 people with different expressions and hairstyles to train i3DMM. Our approach has the following favorable properties: (i) It is the first full head morphable model that includes hair. (ii) In contrast to mesh-based models it can be trained on merely rigidly aligned scans, without requiring difficult non-rigid registration. (iii) We design a novel architecture to decouple the shape model into an implicit reference shape and a deformation of this reference shape. With that, dense correspondences between shapes can be learned implicitly. (iv) This architecture allows us to semantically disentangle the geometry and color components, as color is learned in the reference space. Geometry is further disentangled as identity, expressions, and hairstyle, while color is disentangled as identity and hairstyle components. We show the merits of i3DMM using ablation studies, comparisons to state-of-the-art models, and applications such as semantic head editing and texture transfer. We will make our model publicly available., Comment: Project page: http://gvv.mpi-inf.mpg.de/projects/i3DMM

Published

2020

33. Learning Complete 3D Morphable Face Models from Images and Videos

Author

R, Mallikarjun B, Tewari, Ayush, Seidel, Hans-Peter, Elgharib, Mohamed, Theobalt, Christian, R, Mallikarjun B, Tewari, Ayush, Seidel, Hans-Peter, Elgharib, Mohamed, and Theobalt, Christian

Abstract

Most 3D face reconstruction methods rely on 3D morphable models, which disentangle the space of facial deformations into identity geometry, expressions and skin reflectance. These models are typically learned from a limited number of 3D scans and thus do not generalize well across different identities and expressions. We present the first approach to learn complete 3D models of face identity geometry, albedo and expression just from images and videos. The virtually endless collection of such data, in combination with our self-supervised learning-based approach allows for learning face models that generalize beyond the span of existing approaches. Our network design and loss functions ensure a disentangled parameterization of not only identity and albedo, but also, for the first time, an expression basis. Our method also allows for in-the-wild monocular reconstruction at test time. We show that our learned models better generalize and lead to higher quality image-based reconstructions than existing approaches., Comment: Project Page - https://gvv.mpi-inf.mpg.de/projects/LeMoMo

Published

2020

34. PIE: Portrait Image Embedding for Semantic Control

Author

Tewari, Ayush, Elgharib, Mohamed, R., Mallikarjun B, Bernard, Florian, Seidel, Hans-Peter, Pérez, Patrick, Zollhöfer, Michael, Theobalt, Christian, Tewari, Ayush, Elgharib, Mohamed, R., Mallikarjun B, Bernard, Florian, Seidel, Hans-Peter, Pérez, Patrick, Zollhöfer, Michael, and Theobalt, Christian

Abstract

Editing of portrait images is a very popular and important research topic with a large variety of applications. For ease of use, control should be provided via a semantically meaningful parameterization that is akin to computer animation controls. The vast majority of existing techniques do not provide such intuitive and fine-grained control, or only enable coarse editing of a single isolated control parameter. Very recently, high-quality semantically controlled editing has been demonstrated, however only on synthetically created StyleGAN images. We present the first approach for embedding real portrait images in the latent space of StyleGAN, which allows for intuitive editing of the head pose, facial expression, and scene illumination in the image. Semantic editing in parameter space is achieved based on StyleRig, a pretrained neural network that maps the control space of a 3D morphable face model to the latent space of the GAN. We design a novel hierarchical non-linear optimization problem to obtain the embedding. An identity preservation energy term allows spatially coherent edits while maintaining facial integrity. Our approach runs at interactive frame rates and thus allows the user to explore the space of possible edits. We evaluate our approach on a wide set of portrait photos, compare it to the current state of the art, and validate the effectiveness of its components in an ablation study., Comment: To appear in SIGGRAPH Asia 2020. Project webpage: https://gvv.mpi-inf.mpg.de/projects/PIE

Published

2020

35. Monocular Reconstruction of Neural Face Reflectance Fields

Author

R., Mallikarjun B, Tewari, Ayush, Oh, Tae-Hyun, Weyrich, Tim, Bickel, Bernd, Seidel, Hans-Peter, Pfister, Hanspeter, Matusik, Wojciech, Elgharib, Mohamed, Theobalt, Christian, R., Mallikarjun B, Tewari, Ayush, Oh, Tae-Hyun, Weyrich, Tim, Bickel, Bernd, Seidel, Hans-Peter, Pfister, Hanspeter, Matusik, Wojciech, Elgharib, Mohamed, and Theobalt, Christian

Abstract

The reflectance field of a face describes the reflectance properties responsible for complex lighting effects including diffuse, specular, inter-reflection and self shadowing. Most existing methods for estimating the face reflectance from a monocular image assume faces to be diffuse with very few approaches adding a specular component. This still leaves out important perceptual aspects of reflectance as higher-order global illumination effects and self-shadowing are not modeled. We present a new neural representation for face reflectance where we can estimate all components of the reflectance responsible for the final appearance from a single monocular image. Instead of modeling each component of the reflectance separately using parametric models, our neural representation allows us to generate a basis set of faces in a geometric deformation-invariant space, parameterized by the input light direction, viewpoint and face geometry. We learn to reconstruct this reflectance field of a face just from a monocular image, which can be used to render the face from any viewpoint in any light condition. Our method is trained on a light-stage training dataset, which captures 300 people illuminated with 150 light conditions from 8 viewpoints. We show that our method outperforms existing monocular reflectance reconstruction methods, in terms of photorealism due to better capturing of physical premitives, such as sub-surface scattering, specularities, self-shadows and other higher-order effects., Comment: Project page - http://gvv.mpi-inf.mpg.de/projects/FaceReflectanceFields

Published

2020

36. Neural Voice Puppetry: Audio-driven Facial Reenactment

Author

Thies, Justus, Elgharib, Mohamed, Tewari, Ayush, Theobalt, Christian, Nießner, Matthias, Thies, Justus, Elgharib, Mohamed, Tewari, Ayush, Theobalt, Christian, and Nießner, Matthias

Abstract

We present Neural Voice Puppetry, a novel approach for audio-driven facial video synthesis. Given an audio sequence of a source person or digital assistant, we generate a photo-realistic output video of a target person that is in sync with the audio of the source input. This audio-driven facial reenactment is driven by a deep neural network that employs a latent 3D face model space. Through the underlying 3D representation, the model inherently learns temporal stability while we leverage neural rendering to generate photo-realistic output frames. Our approach generalizes across different people, allowing us to synthesize videos of a target actor with the voice of any unknown source actor or even synthetic voices that can be generated utilizing standard text-to-speech approaches. Neural Voice Puppetry has a variety of use-cases, including audio-driven video avatars, video dubbing, and text-driven video synthesis of a talking head. We demonstrate the capabilities of our method in a series of audio- and text-based puppetry examples, including comparisons to state-of-the-art techniques and a user study., Comment: Video: https://youtu.be/s74_yQiJMXA Project/Demo/Code: https://justusthies.github.io/posts/neural-voice-puppetry

Published

2019

37. 3D Morphable Face Models -- Past, Present and Future

Author

Egger, Bernhard, Smith, William A. P., Tewari, Ayush, Wuhrer, Stefanie, Zollhoefer, Michael, Beeler, Thabo, Bernard, Florian, Bolkart, Timo, Kortylewski, Adam, Romdhani, Sami, Theobalt, Christian, Blanz, Volker, Vetter, Thomas, Egger, Bernhard, Smith, William A. P., Tewari, Ayush, Wuhrer, Stefanie, Zollhoefer, Michael, Beeler, Thabo, Bernard, Florian, Bolkart, Timo, Kortylewski, Adam, Romdhani, Sami, Theobalt, Christian, Blanz, Volker, and Vetter, Thomas

Abstract

In this paper, we provide a detailed survey of 3D Morphable Face Models over the 20 years since they were first proposed. The challenges in building and applying these models, namely capture, modeling, image formation, and image analysis, are still active research topics, and we review the state-of-the-art in each of these areas. We also look ahead, identifying unsolved challenges, proposing directions for future research and highlighting the broad range of current and future applications., Comment: ACM Transactions on Graphics (TOG)

Published

2019

38. Text-based Editing of Talking-head Video

Author

Fried, Ohad, Tewari, Ayush, Zollhöfer, Michael, Finkelstein, Adam, Shechtman, Eli, Goldman, Dan B, Genova, Kyle, Jin, Zeyu, Theobalt, Christian, Agrawala, Maneesh, Fried, Ohad, Tewari, Ayush, Zollhöfer, Michael, Finkelstein, Adam, Shechtman, Eli, Goldman, Dan B, Genova, Kyle, Jin, Zeyu, Theobalt, Christian, and Agrawala, Maneesh

Abstract

Editing talking-head video to change the speech content or to remove filler words is challenging. We propose a novel method to edit talking-head video based on its transcript to produce a realistic output video in which the dialogue of the speaker has been modified, while maintaining a seamless audio-visual flow (i.e. no jump cuts). Our method automatically annotates an input talking-head video with phonemes, visemes, 3D face pose and geometry, reflectance, expression and scene illumination per frame. To edit a video, the user has to only edit the transcript, and an optimization strategy then chooses segments of the input corpus as base material. The annotated parameters corresponding to the selected segments are seamlessly stitched together and used to produce an intermediate video representation in which the lower half of the face is rendered with a parametric face model. Finally, a recurrent video generation network transforms this representation to a photorealistic video that matches the edited transcript. We demonstrate a large variety of edits, such as the addition, removal, and alteration of words, as well as convincing language translation and full sentence synthesis., Comment: A version with higher resolution images can be downloaded from the authors' website

Published

2019

39. DEMEA: Deep Mesh Autoencoders for Non-Rigidly Deforming Objects

Author

Tretschk, Edgar, Tewari, Ayush, Zollhöfer, Michael, Golyanik, Vladislav, Theobalt, Christian, Tretschk, Edgar, Tewari, Ayush, Zollhöfer, Michael, Golyanik, Vladislav, and Theobalt, Christian

Abstract

Mesh autoencoders are commonly used for dimensionality reduction, sampling and mesh modeling. We propose a general-purpose DEep MEsh Autoencoder (DEMEA) which adds a novel embedded deformation layer to a graph-convolutional mesh autoencoder. The embedded deformation layer (EDL) is a differentiable deformable geometric proxy which explicitly models point displacements of non-rigid deformations in a lower dimensional space and serves as a local rigidity regularizer. DEMEA decouples the parameterization of the deformation from the final mesh resolution since the deformation is defined over a lower dimensional embedded deformation graph. We perform a large-scale study on four different datasets of deformable objects. Reasoning about the local rigidity of meshes using EDL allows us to achieve higher-quality results for highly deformable objects, compared to directly regressing vertex positions. We demonstrate multiple applications of DEMEA, including non-rigid 3D reconstruction from depth and shading cues, non-rigid surface tracking, as well as the transfer of deformations over different meshes., Comment: 27 pages, including supplementary material

Published

2019

40. EgoFace: Egocentric Face Performance Capture and Videorealistic Reenactment

Author

Elgharib, Mohamed, BR, Mallikarjun, Tewari, Ayush, Kim, Hyeongwoo, Liu, Wentao, Seidel, Hans-Peter, Theobalt, Christian, Elgharib, Mohamed, BR, Mallikarjun, Tewari, Ayush, Kim, Hyeongwoo, Liu, Wentao, Seidel, Hans-Peter, and Theobalt, Christian

Abstract

Face performance capture and reenactment techniques use multiple cameras and sensors, positioned at a distance from the face or mounted on heavy wearable devices. This limits their applications in mobile and outdoor environments. We present EgoFace, a radically new lightweight setup for face performance capture and front-view videorealistic reenactment using a single egocentric RGB camera. Our lightweight setup allows operations in uncontrolled environments, and lends itself to telepresence applications such as video-conferencing from dynamic environments. The input image is projected into a low dimensional latent space of the facial expression parameters. Through careful adversarial training of the parameter-space synthetic rendering, a videorealistic animation is produced. Our problem is challenging as the human visual system is sensitive to the smallest face irregularities that could occur in the final results. This sensitivity is even stronger for video results. Our solution is trained in a pre-processing stage, through a supervised manner without manual annotations. EgoFace captures a wide variety of facial expressions, including mouth movements and asymmetrical expressions. It works under varying illuminations, background, movements, handles people from different ethnicities and can operate in real time., Comment: Project Page: http://gvv.mpi-inf.mpg.de/projects/EgoFace

Published

2019

41. FML: Face Model Learning from Videos

Author

Tewari, Ayush, Bernard, Florian, Garrido, Pablo, Bharaj, Gaurav, Elgharib, Mohamed, Seidel, Hans-Peter, Pérez, Patrick, Zollhöfer, Michael, Theobalt, Christian, Tewari, Ayush, Bernard, Florian, Garrido, Pablo, Bharaj, Gaurav, Elgharib, Mohamed, Seidel, Hans-Peter, Pérez, Patrick, Zollhöfer, Michael, and Theobalt, Christian

Abstract

Monocular image-based 3D reconstruction of faces is a long-standing problem in computer vision. Since image data is a 2D projection of a 3D face, the resulting depth ambiguity makes the problem ill-posed. Most existing methods rely on data-driven priors that are built from limited 3D face scans. In contrast, we propose multi-frame video-based self-supervised training of a deep network that (i) learns a face identity model both in shape and appearance while (ii) jointly learning to reconstruct 3D faces. Our face model is learned using only corpora of in-the-wild video clips collected from the Internet. This virtually endless source of training data enables learning of a highly general 3D face model. In order to achieve this, we propose a novel multi-frame consistency loss that ensures consistent shape and appearance across multiple frames of a subject's face, thus minimizing depth ambiguity. At test time we can use an arbitrary number of frames, so that we can perform both monocular as well as multi-frame reconstruction., Comment: CVPR 2019 (Oral). Video: https://www.youtube.com/watch?v=SG2BwxCw0lQ, Project Page: https://gvv.mpi-inf.mpg.de/projects/FML19

Published

2018

42. A Hybrid Model for Identity Obfuscation by Face Replacement

Author

Sun, Qianru, Tewari, Ayush, Xu, Weipeng, Fritz, Mario, Theobalt, Christian, Schiele, Bernt, Sun, Qianru, Tewari, Ayush, Xu, Weipeng, Fritz, Mario, Theobalt, Christian, and Schiele, Bernt

Abstract

As more and more personal photos are shared and tagged in social media, avoiding privacy risks such as unintended recognition becomes increasingly challenging. We propose a new hybrid approach to obfuscate identities in photos by head replacement. Our approach combines state of the art parametric face synthesis with latest advances in Generative Adversarial Networks (GAN) for data-driven image synthesis. On the one hand, the parametric part of our method gives us control over the facial parameters and allows for explicit manipulation of the identity. On the other hand, the data-driven aspects allow for adding fine details and overall realism as well as seamless blending into the scene context. In our experiments, we show highly realistic output of our system that improves over the previous state of the art in obfuscation rate while preserving a higher similarity to the original image content., Comment: ECCV'18, camera-ready version

Published

2018

43. Deep Video Portraits

Author

Kim, Hyeongwoo, Garrido, Pablo, Tewari, Ayush, Xu, Weipeng, Thies, Justus, Nießner, Matthias, Pérez, Patrick, Richardt, Christian, Zollhöfer, Michael, Theobalt, Christian, Kim, Hyeongwoo, Garrido, Pablo, Tewari, Ayush, Xu, Weipeng, Thies, Justus, Nießner, Matthias, Pérez, Patrick, Richardt, Christian, Zollhöfer, Michael, and Theobalt, Christian

Abstract

We present a novel approach that enables photo-realistic re-animation of portrait videos using only an input video. In contrast to existing approaches that are restricted to manipulations of facial expressions only, we are the first to transfer the full 3D head position, head rotation, face expression, eye gaze, and eye blinking from a source actor to a portrait video of a target actor. The core of our approach is a generative neural network with a novel space-time architecture. The network takes as input synthetic renderings of a parametric face model, based on which it predicts photo-realistic video frames for a given target actor. The realism in this rendering-to-video transfer is achieved by careful adversarial training, and as a result, we can create modified target videos that mimic the behavior of the synthetically-created input. In order to enable source-to-target video re-animation, we render a synthetic target video with the reconstructed head animation parameters from a source video, and feed it into the trained network -- thus taking full control of the target. With the ability to freely recombine source and target parameters, we are able to demonstrate a large variety of video rewrite applications without explicitly modeling hair, body or background. For instance, we can reenact the full head using interactive user-controlled editing, and realize high-fidelity visual dubbing. To demonstrate the high quality of our output, we conduct an extensive series of experiments and evaluations, where for instance a user study shows that our video edits are hard to detect., Comment: SIGGRAPH 2018, Video: https://www.youtube.com/watch?v=qc5P2bvfl44

Published

2018

44. InverseFaceNet: Deep Monocular Inverse Face Rendering

Author

Kim, Hyeongwoo, Zollhöfer, Michael, Tewari, Ayush, Thies, Justus, Richardt, Christian, Theobalt, Christian, Kim, Hyeongwoo, Zollhöfer, Michael, Tewari, Ayush, Thies, Justus, Richardt, Christian, and Theobalt, Christian

Abstract

We introduce InverseFaceNet, a deep convolutional inverse rendering framework for faces that jointly estimates facial pose, shape, expression, reflectance and illumination from a single input image. By estimating all parameters from just a single image, advanced editing possibilities on a single face image, such as appearance editing and relighting, become feasible in real time. Most previous learning-based face reconstruction approaches do not jointly recover all dimensions, or are severely limited in terms of visual quality. In contrast, we propose to recover high-quality facial pose, shape, expression, reflectance and illumination using a deep neural network that is trained using a large, synthetically created training corpus. Our approach builds on a novel loss function that measures model-space similarity directly in parameter space and significantly improves reconstruction accuracy. We further propose a self-supervised bootstrapping process in the network training loop, which iteratively updates the synthetic training corpus to better reflect the distribution of real-world imagery. We demonstrate that this strategy outperforms completely synthetically trained networks. Finally, we show high-quality reconstructions and compare our approach to several state-of-the-art approaches., Comment: CVPR 2018 (poster) 10 pages (+5 pages)

Published

2017

45. MoFA: Model-based Deep Convolutional Face Autoencoder for Unsupervised Monocular Reconstruction

Author

Tewari, Ayush, Zollhöfer, Michael, Kim, Hyeongwoo, Garrido, Pablo, Bernard, Florian, Pérez, Patrick, Theobalt, Christian, Tewari, Ayush, Zollhöfer, Michael, Kim, Hyeongwoo, Garrido, Pablo, Bernard, Florian, Pérez, Patrick, and Theobalt, Christian

Abstract

In this work we propose a novel model-based deep convolutional autoencoder that addresses the highly challenging problem of reconstructing a 3D human face from a single in-the-wild color image. To this end, we combine a convolutional encoder network with an expert-designed generative model that serves as decoder. The core innovation is our new differentiable parametric decoder that encapsulates image formation analytically based on a generative model. Our decoder takes as input a code vector with exactly defined semantic meaning that encodes detailed face pose, shape, expression, skin reflectance and scene illumination. Due to this new way of combining CNN-based with model-based face reconstruction, the CNN-based encoder learns to extract semantically meaningful parameters from a single monocular input image. For the first time, a CNN encoder and an expert-designed generative model can be trained end-to-end in an unsupervised manner, which renders training on very large (unlabeled) real world data feasible. The obtained reconstructions compare favorably to current state-of-the-art approaches in terms of quality and richness of representation., Comment: International Conference on Computer Vision (ICCV) 2017 (Oral), 13 pages

Published

2017

46. Self-supervised Multi-level Face Model Learning for Monocular Reconstruction at over 250 Hz

Author

Tewari, Ayush, Zollhöfer, Michael, Garrido, Pablo, Bernard, Florian, Kim, Hyeongwoo, Pérez, Patrick, Theobalt, Christian, Tewari, Ayush, Zollhöfer, Michael, Garrido, Pablo, Bernard, Florian, Kim, Hyeongwoo, Pérez, Patrick, and Theobalt, Christian

Abstract

The reconstruction of dense 3D models of face geometry and appearance from a single image is highly challenging and ill-posed. To constrain the problem, many approaches rely on strong priors, such as parametric face models learned from limited 3D scan data. However, prior models restrict generalization of the true diversity in facial geometry, skin reflectance and illumination. To alleviate this problem, we present the first approach that jointly learns 1) a regressor for face shape, expression, reflectance and illumination on the basis of 2) a concurrently learned parametric face model. Our multi-level face model combines the advantage of 3D Morphable Models for regularization with the out-of-space generalization of a learned corrective space. We train end-to-end on in-the-wild images without dense annotations by fusing a convolutional encoder with a differentiable expert-designed renderer and a self-supervised training loss, both defined at multiple detail levels. Our approach compares favorably to the state-of-the-art in terms of reconstruction quality, better generalizes to real world faces, and runs at over 250 Hz., Comment: CVPR 2018 (Oral). Project webpage: https://gvv.mpi-inf.mpg.de/projects/FML

Published

2017