Yong Feng scite author profile

We propose a straightforward method that simultaneously reconstructs the 3D facial structure and provides dense alignment. To achieve this, we design a 2D representation called UV position map which records the 3D shape of a complete face in UV space, then train a simple Convolutional Neural Network to regress it from a single 2D image. We also integrate a weight mask into the loss function during training to improve the performance of the network. Our method does not rely on any prior face model, and can reconstruct full facial geometry along with semantic meaning. Meanwhile, our network is very light-weighted and spends only 9.8ms to process an image, which is extremely faster than previous works. Experiments on multiple challenging datasets show that our method surpasses other state-of-the-art methods on both reconstruction and alignment tasks by a large margin. Code is available at https://github.com/YadiraF/PRNet.

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Learning an animatable detailed 3D face model from in-the-wild images

Feng¹,

et al. 2021

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While current monocular 3D face reconstruction methods can recover fine geometric details, they suffer several limitations. Some methods produce faces that cannot be realistically animated because they do not model how wrinkles vary with expression. Other methods are trained on high-quality face scans and do not generalize well to in-the-wild images. We present the first approach that regresses 3D face shape and animatable details that are specific to an individual but change with expression. Our model, DECA (Detailed Expression Capture and Animation), is trained to robustly produce a UV displacement map from a low-dimensional latent representation that consists of person-specific detail parameters and generic expression parameters, while a regressor is trained to predict detail, shape, albedo, expression, pose and illumination parameters from a single image. To enable this, we introduce a novel detail-consistency loss that disentangles person-specific details from expression-dependent wrinkles. This disentanglement allows us to synthesize realistic person-specific wrinkles by controlling expression parameters while keeping person-specific details unchanged. DECA is learned from in-the-wild images with no paired 3D supervision and achieves state-of-the-art shape reconstruction accuracy on two benchmarks. Qualitative results on in-the-wild data demonstrate DECA's robustness and its ability to disentangle identity-and expression-dependent details enabling animation of reconstructed faces. The model and code are publicly available at https://deca.is.tue.mpg.de. CCS Concepts: • Computing methodologies → Mesh models.

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Collaborative Regression of Expressive Bodies using Moderation

Feng

Choutas

Bolkart

et al. 2021

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Experiments and crystal plasticity finite element simulations of nanoindentation on Ti–6Al–4V alloy

Han

Tang

Kou

et al. 2015

Materials Science and Engineering: A

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Probabilistic analyses of structural dynamic response with modified Kriging-based moving extremum framework

Fei

Feng

et al. 2021

Engineering Failure Analysis

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Cellular automata modeling of static recrystallization based on the curvature driven subgrain growth mechanism

et al. 2013

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Static recrystallization simulations by coupling cellular automata and crystal plasticity finite element method using a physically based model for nucleation

et al. 2014

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Learning an animatable detailed 3D face model from in-the-wild images

Feng¹,

Feng

Black

et al. 2021

ACM Trans. Graph.

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Yong Feng

Joint 3D Face Reconstruction and Dense Alignment with Position Map Regression Network

Learning an animatable detailed 3D face model from in-the-wild images

Collaborative Regression of Expressive Bodies using Moderation

Experiments and crystal plasticity finite element simulations of nanoindentation on Ti–6Al–4V alloy

Probabilistic analyses of structural dynamic response with modified Kriging-based moving extremum framework

Cellular automata modeling of static recrystallization based on the curvature driven subgrain growth mechanism

Static recrystallization simulations by coupling cellular automata and crystal plasticity finite element method using a physically based model for nucleation

Learning an animatable detailed 3D face model from in-the-wild images

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