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EllipsoidSLAM

Update

Aug 22, 2021

  • Now support Ubuntu 20.04 and OpenCV 4.2
  • Fix bugs for crushes

Introduction

We propose a sparse object-level SLAM using Quadrics and Symmetry Properties for indoor environments. The algorithm is specially designed for mobile robots mounting an RGB-D camera. The algorithm takes bounding boxes generated from object detection and also the point cloud from the RGB-D frame to estimate the pose and occupy space of objects. Since ellipsoids are taken as the object representation, we name it EllipsoidSLAM.

We have released a C++ implementation and a demo trajectory. We need to point out that this code is only a basic demo:

  • The core modules of Groundplane Extraction, Ellipsoid Estimation, and Symmetry Estimation are basic versions. They may not have full performance. Please see the paper for the complete framework.
  • By default, only mapping is supported. If you want, it's possible to make simple changes to the Optimizer to enable the SLAM mode.

Author

Ziwei Liao et al., Robotics Institute, School of Mechanical Engineering & Automation, Beihang University, Beijing, China (Email: liaoziwei{at}buaa.edu.cn)

Related Paper

Please cite the following papers when you found this code useful for your research. Welcome to read our new paper [2], which proposes two RGB-D observation models for quadrics, and introduces an automatic data association method.

[1] Ziwei Liao, Wei Wang, Xianyu Qi, Xiaoyu Zhang, Lin Xue, Jianzhen Jiao, Ran Wei, Object-oriented SLAM using Quadrics and Symmetry Properties for Indoor Environments. arXiv 2020. [pdf] [Video]

[2] Liao, Z.; Wang, W.; Qi, X.; Zhang, X. RGB-D Object SLAM Using Quadrics for Indoor Environments. Sensors 2020, 20, 5150. [pdf]

Codes

Dependencies

The code has been tested on Ubuntu 16.04/18.04. The main dependencies are:

  • OpenCV (4.X recommended)
  • PCL 1.7+
  • Pangolin
  • g2o

For g2o, a modified version with SE3 transformation has been attached in the code. Use one simple command to compile it:

$ sh install_g2o.sh

Build

These commands will automatically generate the Core module and an interface for RGB-D dataset:

$ mkdir build
$ cd build
$ cmake .. 
$ make -j

if there occurs a linking problem, add the lib directory to the environment variable:

export LD_LIBRARY_PATH={YOUR_SOUCE_CODE_PATH}/lib:$LD_LIBRARY_PATH

Demos

TUM-Cabinet

The codes contain a trajectory of fr3_cabinet, which belongs to the TUM-RGB-D dataset. The bounding boxes are generated by YOLO. Just use one command to run the demo:

Run

./build/rgbd ./Example/param/TUM3.yaml ./Example/dataset/cabinet/

Please press Enter in the console to see the result of every frame. A visualization tool based on Pangolin is offered to visualize the point cloud, the symmetry planes, the ground plane, and the ellipsoids.

Your Own Dataset

First, please run object detector like YOLO to generate bounding boxes and store the result as text files, with each line containing:

  • id x1 y1 x2 y2 label probability instance

where, (x1,y1), (x2,y2) are the top-left, bottom-right corners. Multiple objects are supported, however, you need to manually specify the data association in [instance].

Second, keep the directory structure the same as the demo, then run the RGB-D interface. For the best effect, you may need to check the ground plane extraction and the point cloud segmentation.

Notes

  • All the important parameters could be adjusted in the .yaml file. See the comments in the file for details.

  • The code is released under the BSD license. Feel free to adjust it as you like for research. Please cite our paper in your publications if you feel it helpful.

  • The code referred to several open-source SLAM codes, thanks to their great work: ORBSLAM, CubeSLAM.

  • If you have any further questions, feel free to contact the author: liaoziwei{at}buaa.edu.cn