EPro-PnP: Generalized End-to-End Probabilistic Perspective-n-Points for Monocular Object Pose Estimation
In CVPR 2022 (Oral, Best Student Paper). [paper][video]
Hansheng Chen*1,2, Pichao Wang†2, Fan Wang2, Wei Tian†1, Lu Xiong1, Hao Li2
1Tongji University, 2Alibaba Group
*Part of work done during an internship at Alibaba Group.
†Corresponding Authors: Pichao Wang, Wei Tian.
EPro-PnP is a probabilistic Perspective-n-Points (PnP) layer for end-to-end 6DoF pose estimation networks. Broadly speaking, it is essentially a continuous counterpart of the widely used categorical Softmax layer, and is theoretically generalizable to other learning models with nested optimization.
Given the layer input: an -point correspondence set
consisting of 3D object coordinates
, 2D image coordinates
, and 2D weights
, a conventional PnP solver searches for an optimal pose
(rigid transformation in SE(3)) that minimizes the weighted reprojection error. Previous work tries to backpropagate through the PnP operation, yet
is inherently non-differentiable due to the inner
operation. This leads to convergence issue if all the components in
must be learned by the network.
In contrast, our probabilistic PnP layer outputs a posterior distribution of pose, whose probability density can be derived for proper backpropagation. The distribution is approximated via Monte Carlo sampling. With EPro-PnP, the correspondences
can be learned from scratch altogether by minimizing the KL divergence between the predicted and target
pose distribution.
We release two distinct networks trained with EPro-PnP:
-
EPro-PnP-6DoF for 6DoF pose estimation
-
EPro-PnP-Det for 3D object detection
We provide a demo on the usage of the EPro-PnP layer.
If you find this project useful in your research, please consider citing:
@inproceedings{epropnp,
author = {Hansheng Chen and Pichao Wang and Fan Wang and Wei Tian and Lu Xiong and Hao Li,
title = {EPro-PnP: Generalized End-to-End Probabilistic Perspective-n-Points for Monocular Object Pose Estimation},
booktitle = {IEEE Conference on Computer Vision and Pattern Recognition (CVPR)},
year = {2022}
}