1,284 research outputs found
Pose Induction for Novel Object Categories
We address the task of predicting pose for objects of unannotated object
categories from a small seed set of annotated object classes. We present a
generalized classifier that can reliably induce pose given a single instance of
a novel category. In case of availability of a large collection of novel
instances, our approach then jointly reasons over all instances to improve the
initial estimates. We empirically validate the various components of our
algorithm and quantitatively show that our method produces reliable pose
estimates. We also show qualitative results on a diverse set of classes and
further demonstrate the applicability of our system for learning shape models
of novel object classes
Keep it SMPL: Automatic Estimation of 3D Human Pose and Shape from a Single Image
We describe the first method to automatically estimate the 3D pose of the
human body as well as its 3D shape from a single unconstrained image. We
estimate a full 3D mesh and show that 2D joints alone carry a surprising amount
of information about body shape. The problem is challenging because of the
complexity of the human body, articulation, occlusion, clothing, lighting, and
the inherent ambiguity in inferring 3D from 2D. To solve this, we first use a
recently published CNN-based method, DeepCut, to predict (bottom-up) the 2D
body joint locations. We then fit (top-down) a recently published statistical
body shape model, called SMPL, to the 2D joints. We do so by minimizing an
objective function that penalizes the error between the projected 3D model
joints and detected 2D joints. Because SMPL captures correlations in human
shape across the population, we are able to robustly fit it to very little
data. We further leverage the 3D model to prevent solutions that cause
interpenetration. We evaluate our method, SMPLify, on the Leeds Sports,
HumanEva, and Human3.6M datasets, showing superior pose accuracy with respect
to the state of the art.Comment: To appear in ECCV 201
Structure from Recurrent Motion: From Rigidity to Recurrency
This paper proposes a new method for Non-Rigid Structure-from-Motion (NRSfM)
from a long monocular video sequence observing a non-rigid object performing
recurrent and possibly repetitive dynamic action. Departing from the
traditional idea of using linear low-order or lowrank shape model for the task
of NRSfM, our method exploits the property of shape recurrency (i.e., many
deforming shapes tend to repeat themselves in time). We show that recurrency is
in fact a generalized rigidity. Based on this, we reduce NRSfM problems to
rigid ones provided that certain recurrency condition is satisfied. Given such
a reduction, standard rigid-SfM techniques are directly applicable (without any
change) to the reconstruction of non-rigid dynamic shapes. To implement this
idea as a practical approach, this paper develops efficient algorithms for
automatic recurrency detection, as well as camera view clustering via a
rigidity-check. Experiments on both simulated sequences and real data
demonstrate the effectiveness of the method. Since this paper offers a novel
perspective on rethinking structure-from-motion, we hope it will inspire other
new problems in the field.Comment: To appear in CVPR 201
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