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LLD-SLAM

Authors: Alexander Vakhitov, based on the ORB-SLAM2 system by Raul Mur-Artal, Juan D. Tardos, J. M. M. Montiel and Dorian Galvez-Lopez (DBoW2)

03.06.2019 Release of the LLD-SLAM source code

LLD-SLAM is a real-time point+line Stereo SLAM library based on a well known ORB-SLAM2 system. It computes the camera trajectory and a sparse 3D reconstruction consisting of points and lines.

LLD-SLAM

Related Publications:

[Point+Line LLD SLAM] A. Vakhitov and V. Lempitsky. Learnable Line Segment Descriptor for Visual SLAM. IEEE Access, 2019.

1. License

LLD-SLAM is released under a GPLv3 license. For a list of all code/library dependencies (and associated licenses), please see Dependencies.md.

If you use LLD-SLAM in an academic work, please cite:

@article{murTRO2015,
  title={Learnable Line Segment Descriptor for Visual SLAM},
  author={Vakhitov, Alexander and Lempitsky, Victor},
  journal={IEEE Access},
  year={2019}
 }

2. Prerequisites

We have tested the library in Ubuntu 12.04, 14.04 and 16.04, but it should be easy to compile in other platforms. A powerful computer (e.g. i7) will ensure real-time performance and provide more stable and accurate results.

C++11 or C++0x Compiler

We use the new thread and chrono functionalities of C++11.

LBDMOD library

We use LBDMOD for line detection and description. Please download, make, install and insert path to the CMakelists.txt.

Pangolin

We use Pangolin for visualization and user interface. Dowload and install instructions can be found at: https://github.com/stevenlovegrove/Pangolin.

OpenCV

We use OpenCV to manipulate images and features. Dowload and install instructions can be found at: http://opencv.org. Required at leat 2.4.3. Tested with OpenCV 2.4.11 and OpenCV 3.2.

Eigen3

Required by g2o (see below). Download and install instructions can be found at: http://eigen.tuxfamily.org. Required at least 3.1.0.

DBoW2 and g2o (Included in Thirdparty folder)

We use modified versions of the DBoW2 library to perform place recognition and g2o library to perform non-linear optimizations. Both modified libraries (which are BSD) are included in the Thirdparty folder.

ROS (optional)

We provide some examples to process the live input of a monocular, stereo or RGB-D camera using ROS. Building these examples is optional. In case you want to use ROS, a version Hydro or newer is needed.

3. Building LLD-SLAM library and examples

Clone the repository:

git clone git@github.com:alexandervakhitov/lld-slam.git LLD_SLAM

We provide a script build.sh to build the Thirdparty libraries and LLD-SLAM. Please make sure you have installed all required dependencies (see section 2). Please modify the CMakelists.txt: insert a correct path to the LBDMOD library instead of . Then execute:

cd LLD_SLAM
chmod +x build.sh
./build.sh

This will create libLLD_SLAM.so at lib folder and the executables stereo_kitti and stereo_euroc in Examples folder.

4. Stereo Examples

KITTI+EuRoC combined Dataset

  1. Download the KITTI dataset (grayscale images) from http://www.cvlibs.net/datasets/kitti/eval_odometry.php

  2. Download a sequence (ASL format) from http://projects.asl.ethz.ch/datasets/doku.php?id=kmavvisualinertialdatasets

  3. Download the precomputed line detections and LBD descriptors from https://yadi.sk/d/D5QEuced7y5I1w. Modify the KITTIX_Y.yaml, 'EuRoC_Y.yaml' files to include the paths to the downloaded and unpacked dataset.

  4. Execute one of the following commands depending on the dataset you are going to use. Change KITTIX_Y.yaml to KITTI00-02_Y.yaml, KITTI03_Y.yaml or KITTI04-12_Y.yaml for Y = {LBD,Empty} for sequence 0 to 2, 3, and 4 to 12 respectively. Change PATH_TO_DATASET_FOLDER to the uncompressed dataset folder. Change SEQUENCE_NUMBER to 00, 01, 02,.., 11. Substitute $SSS with SEQUENCE_NUMBER in the *.yaml file.

./Examples/Stereo/stereo_kitti Vocabulary/ORBvoc.txt Examples/Stereo/KITTIX.yaml PATH_TO_DATASET_FOLDER/dataset/sequences/SEQUENCE_NUMBER
./Examples/Stereo/stereo_euroc Vocabulary/ORBvoc.txt Examples/Stereo/EuRoC_Y.yaml PATH_TO_SEQUENCE/mav0/cam0/data PATH_TO_SEQUENCE/mav0/cam1/data Examples/Stereo/EuRoC_TimeStamps/SEQUENCE.txt
./Examples/Stereo/stereo_euroc Vocabulary/ORBvoc.txt Examples/Stereo/EuRoC_Y.yaml PATH_TO_SEQUENCE/cam0/data PATH_TO_SEQUENCE/cam1/data Examples/Stereo/EuRoC_TimeStamps/SEQUENCE.txt

KITTI+EuRoC dataset composition

No. in combined No. in KITTI No. in EuRoC
0 0
1 1
2 2
3 3
4 4
5 0
6 1
7 3
8 5
9 7
10 7
11 9
12 6
13 5
14 8
15 9
16 10
17 2
18 4
19 6
20 8
21 10

5. Processing your own sequences

You will need to create a settings file with the calibration of your camera. See the settings file provided for the KITTI and EuRoC datasets for stereo cameras. We use the calibration model of OpenCV. See the examples to learn how to create a program that makes use of the LLD-SLAM library and how to pass images to the SLAM system. Stereo input must be synchronized and rectified. Use the LBD descriptor and detector available in the LBDMOD library, as we show in the lld-public.

6. SLAM and Localization Modes

You can change between the SLAM and Localization mode using the GUI of the map viewer.

SLAM Mode

This is the default mode. The system runs in parallal three threads: Tracking, Local Mapping and Loop Closing. The system localizes the camera, builds new map and tries to close loops.

Localization Mode

This mode can be used when you have a good map of your working area. In this mode the Local Mapping and Loop Closing are deactivated. The system localizes the camera in the map (which is no longer updated), using relocalization if needed.

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