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Research Overview

Inferring and exploiting contact

Generative Proxemics: A Prior for 3D Social Interaction from Images

BITE -- Dog Shape and Pose from an Image

HOLD -- inferring 3D hand and object shape from video

MOVER -- Reconstructing 3D Scenes and People using Interaction

Datasets for understanding humans and animals

The Poses for Equine Research Dataset (PFERD)

BEAT2 Dataset for Holistic Co-Speech Gesture Generation

ARCTIC: A Dataset for Dexterous Bimanual Hand-Object Manipulation

The BioAMASS Dataset

OpenCapBench dataset

Human health and the 3D body

Body Shape Models in Treating Anorexia Nervosa

Customized Bone Plants for Humerus Shaft Fractures

Reconstructing Signing Avatars From Video Using Linguistic Priors

The AI animator

HAAR: Text-Conditioned Generative Model of 3D Strand-based Human Hairstyles

Gaussian Garments

PuzzleAvatar: Assembling 3D Avatars from Personal Albums

FLARE: Fast Learning of Animatable and Relightable Mesh Avatars

Language, Vision, and World Models

AWOL: Analysis WithOut synthesis using Language

Re-Thinking Inverse Graphics with Large Language Models

TeCH: Text-guided Reconstruction of Clothed Humans

Human pose, shape, and motion capture

WHAM: Reconstructing World-grounded Humans with Accurate 3D Motion

3D Human Pose Estimation via Intuitive Physics

Accurate 3D Body Shape Regression using Metric and Semantic Attributes

BEV

Generating human motion

Generating Human Interaction Motions in Scenes with Text Control

TEMOS: Generating Diverse Human Motions from Text

EMAGE: Full-body Gestures from Audio

TEACH: Temporal Action Compositions for 3D Humans

Robot Perception Group

AirCap: 3D Motion Capture

AirCap: Perception-Based Control

AirCapRL: Aerial Motion Capture Using Deep RL

Data Team

Lab Tours and Public Outreach

Collecting Data - From the Idea to the Publication

Capture Technologies Setup

Completed Projects

Human Pose, Shape and Action

3D Pose from Images

2D Pose from Images

Beyond Motion Capture

Action and Behavior

Body Perception

Body Applications

Pose and Motion Priors

Clothing Models (2011-2015)

Reflectance Filtering

Learning on Manifolds

Markerless Animal Motion Capture

Multi-Camera Capture

2D Pose from Optical Flow

Body Perception

Neural Prosthetics and Decoding

Part-based Body Models

Intrinsic Depth

Lie Bodies

Layers, Time and Segmentation

Understanding Action Recognition (JHMDB)

Intrinsic Video

Intrinsic Images

Action Recognition with Tracking

Neural Control of Grasping

Flowing Puppets

Faces

Deformable Structures

Model-based Anthropometry

Modeling 3D Human Breathing

Optical flow in the LGN

FlowCap

Smooth Loops from Unconstrained Video

PCA Flow

Efficient and Scalable Inference

Motion Blur in Layers

Facade Segmentation

Smooth Metric Learning

Robust PCA

3D Recognition

Object Detection

Perzeptive Systeme Video Members Publications

FlowCap

Research photo flowcap method
FlowCap. Left to right: image capture with Kinect RGB camera, optical flow, per pixel part labels, part centers with uncertainty (red circles) and motion vectors (10x actual magnitude), estimated kinematic structure of the part centers

We estimate 2D human pose from video using only optical flow. The key insight is that dense optical flow can provide information about 2D body pose. Like range data, flow is largely invariant to appearance but unlike depth it can be directly computed from monocular video. We demonstrate that body parts can be detected from dense flow using the same random forest approach used by the Microsoft Kinect. Unlike range data, however, when people stop moving, there is no optical flow and they effectively disappear. To address this, our FlowCap method uses a Kalman filter to propagate body part positions and velocities over time and a regression method to predict 2D body pose from part centers. No range sensor is required and FlowCap estimates 2D human pose from monocular video sources containing human motion. Such sources include hand-held phone cameras and archival television video. We demonstrate 2D body pose estimation in a range of scenarios and show that the method works with real-time optical flow. The results suggest that optical flow shares invariances with range data that, when complemented with tracking, make it valuable for pose estimation. Please visit the project webpage http://flowcap.is.tue.mpg.de for more information and to gain access to the training data.

Video

Members

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Perzeptive Systeme
Javier Romero
Affiliated Researcher
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Perzeptive Systeme
Michael Black
Director
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Perzeptive Systeme
Matthew Loper

Publications

Perceiving Systems Conference Paper FlowCap: 2D Human Pose from Optical Flow Romero, J., Loper, M., Black, M. J. In Pattern Recognition, Proc. 37th German Conference on Pattern Recognition (GCPR), LNCS 9358:412-423, Springer, GCPR, 2015 () video pdf preprint BibTeX