Skip to content

Latest commit

 

History

History
330 lines (229 loc) · 13.8 KB

README.md

File metadata and controls

330 lines (229 loc) · 13.8 KB

image-20200927095842317 H2-Mapping:

Real-time Dense Mapping Using Hierarchical Hybrid Representation

Chenxing Jiang*, Hanwen Zhang*, Peize Liu, Zehuan Yu, Hui Cheng, Boyu Zhou †, Shaojie Shen

IEEE Robotics and Automation Letters (2023 Best Paper Award)

Abstract

Constructing a high-quality dense map in real-time is essential for robotics, AR/VR, and digital twins applications. As Neural Radiance Field (NeRF) greatly improves the mapping performance, in this letter, we propose a NeRF-based mapping method that enables higher-quality reconstruction and real-time capability even on edge computers. Specifically, we propose a novel hierarchical hybrid representation that leverages implicit multiresolution hash encoding aided by explicit octree SDF priors, describing the scene at different levels of detail. This representation allows for fast scene geometry initialization and makes scene geometry easier to learn. Besides, we present a coverage-maximizing keyframe selection strategy to address the forgetting issue and enhance mapping quality, particularly in marginal areas. To the best of our knowledge, our method is the first to achieve high-quality NeRF-based mapping on edge computers of handheld devices and quadrotors in real-time. Experiments demonstrate that our method outperforms existing NeRF-based mapping methods in geometry accuracy, texture realism, and time consumption.

H2-mapping: real-time dense mapping using hierarchical hybrid representation

Installation

  1. Begin by cloning this repository and all its submodules using the following command:

    git clone --recursive https://github.com/SYSU-STAR/H2-Mapping
  2. Create an anaconda environment called h2mapping. Note that installing the 0.17.0 version of open3d may result in errors during reconstruction evaluation. Please install the 0.16.0 version of open3d instead.

    cd H2-Mapping/mapping
    conda env create -f h2mapping.yaml
  3. Install the Pytorch manually for your hardware platform.

  4. Install the dependency packages.

    bash install.sh
  5. Install tinycudann and its pytorch extension following https://github.com/NVlabs/tiny-cuda-nn

    cd third_party/tinycudann
    cmake . -B build -DCMAKE_BUILD_TYPE=RelWithDebInfo
    cmake --build build --config RelWithDebInfo -j
    cd bindings/torch
    python setup.py install

Run in dataset (Only Mapping)

  1. Replace the filename in src/mapping.py with the built library
torch.classes.load_library("third_party/sparse_octree/build/lib.xxx/svo.xxx.so")

Replica dataset

  1. Download the data as below and the data is saved into the ./Datasets/Replica folder.
bash mapping/scripts/download_replica.sh
  1. To execute H2-Mapping, please proceed with the following steps. If you wish to preserve the intermediate results for visualization purposes, you have the option to modify the "save_ckpt_freq" parameter in the configuration file configs/replica/room_0.
# take replica room0 dataset as example
cd mapping
python -W ignore demo/run_mapping.py configs/replica/room_0.yaml

The final reconstructed mesh will be saved in mapping/logs/{DATASET}/{DATA SEQUENCE}/{FILE_NAME}/mesh.

Run in ROS (Full SLAM)

  1. Install the Ubuntu, ROS, Ceres, OpenCV. If you successfully run VINS-Fusion, you will be able to run our tracking code as well.

    The current version of our platform includes:

    • Ubuntu=20.04

    • ROS=noetic

    • Ceres=1.14.0

    • OpenCV=4.2.0

  2. Build our Tracking module

cd H2-Mapping
catkin_make
  1. Replace the filename in src/mapping.py with the built library
torch.classes.load_library("third_party/sparse_octree/build/lib.xxx/svo.xxx.so")

Self-captured House dataset

  1. Please download the ROS bag containing RGB-D sensor data from the Realsense L515. You can access the file through the provided link: tower_compress.bag;

  2. Decompress the ROS bag

    rosbag decompress tower_compress.bag
  3. Configure the tracking parameter in the designated configuration file. For reference, consider the example file located at src/dvins/config/uav2022/uav_nerf.yaml. This configuration file is for the provided tower_compress.orig.bag.

  4. Configure the ros_args parameter in the designated configuration file. For reference, consider the example file located at configs/realsense/realsense.yaml. This configuration file is for the provided tower_compress.orig.bag.

    # set intrinsic parameters, ROS topics of rgb image, depth image and odometry
    ros_args:
      intrinsic: [601.347290039062, 601.343017578125, 329.519226074219, 238.586654663086] # K[0, 0], K[1, 1], K[0, 2], K[1, 2]
      color_topic: '/camera/color/image_raw'
      depth_topic: '/camera/aligned_depth_to_color/image_raw'
      pose_topic: '/vins_estimator/cam_pose'
  5. Run the mapping module. If you wish to preserve the intermediate results for visualization purposes, you have the option to modify the "save_ckpt_freq" parameter in the configuration file configs/realsense/tower.

    conda activate h2mapping
    cd H2-Mapping
    source devel/setup.bash
    cd mapping
    python -W ignore demo/run_mapping.py configs/realsense/tower.yaml -run_ros

    Once the mapping module is prepared and operational, you will observe a distinctive sign in the console that reads " ========== MAPPING START ===========". This indicator confirms the initiation of the mapping process.

    Note: The default configuration was utilized in our paper's experiment, conducted on NVIDIA Jetson AGX Orin (32GB RAM). In case you encounter memory limitations on your platform, you can attempt reducing the insert_ratio parameter in the configs/realsense/tower.yaml file, but it may result in inferior outcomes.

  6. Run the Tracking module

cd H2-Mapping
bash ros_cmd/run_vins_rgbd.sh
  1. Play the ROS Bag
rosbag play tower_compress.orig.bag
  1. In a separate console, execute the command rosnode kill -a to terminate all the modules. Afterwards, the marching cube algorithm will be executed to reconstruct a mesh for visualization.

Use your own RGB-D sequence

  1. Modify the mapping configuration file in mapping/configs/realsense. Please take note of the following:

    Note:

    (1) Ensure that the value assigned to the "offset" (m) parameter is sufficiently large. This value is utilized to ensure that the coordinates of each point are positive.

    (2) Ensure that the upper bound of the "bound" (m) parameter is suitably large. This parameter defines the boundary of the scene. However, if the range is too much larger than the scene you want to reconstruct, the performance may degrade.

    (3) Choose the appropriate value for "num_vertexes" based on the size of your scene. It should be large enough to encompass all the vertices of the octree.

    (4) Ensure that there will be no frame with a minimum depth smaller than max_depth.

  2. Modify the tracking configuration file in src/dvins/config/uav2022/uav_nerf.yaml to suit your specific device.

  3. To execute the code similar to the provided demo.

Evaluation

Reconstruction Error

  1. Download the ground truth Replica meshes
bash scripts/download_replica_mesh.sh
  1. Replace the filename in eval/eval_recon.py with the built library
torch.classes.load_library("third_party/sparse_octree/build/lib.xxx/svo.xxx.so")
  1. Then run the command below. The 2D metric requires rendering of 1000 depth images. Use -2d to enable 2D metric. Use -3d to enable 3D metric. The reconstruction results will be saved in the $OUTPUT_FOLDER
# assign any output_folder and gt mesh you like, here is just an example
cd mapping
OUTPUT_FOLDER=logs/replica/room0/FILE_NAME
GT_MESH=../Datasets/Replica/cull_replica_mesh/room0.ply
python eval/eval_recon.py \
$OUTPUT_FOLDER/bak/config.yaml \
--rec_mesh $OUTPUT_FOLDER/mesh/final_mesh.ply \
--gt_mesh $GT_MESH \
--ckpt $OUTPUT_FOLDER/ckpt/final_ckpt.pth \
--out_dir $OUTPUT_FOLDER \
-2d \
-3d

Rendering Error

  1. Replace the filename in src/mapping.py with the built library
torch.classes.load_library("third_party/sparse_octree/build/lib.xxx/svo.xxx.so")
  1. Then run the command below. It will calculate the SSIM and PSNR of the color rendering. Additionally, it will calculate the L1 loss of the depth rendering. The resulting rendering videos and images will be automatically saved in the designated $OUTPUT_FOLDER.
# assign any output_folder you like, here is just an example
cd mapping
OUTPUT_FOLDER=logs/replica/room0/FILE_NAME
python eval/eval_color.py \
$OUTPUT_FOLDER/bak/config.yaml \
--result_file $OUTPUT_FOLDER

Note: If you want to evaluate the rendering error in your custom dataset, you should emulate the structure of mapping/src/dataset/replica.py and create a corresponding MY_DATA.py file. Additionally, ensure to include lines in the config file specifying the dataset as dataset: MY_DATA and the data_path: YOUR_DATASET_PATH.

Visualization

Provided that you have configured the saving of intermediate results by adjusting the "save_ckpt_freq" parameter in the configuration file, you can employ the code to visualize the ongoing process. This functionality allows you to observe the progression of the intermediate results.

room0_mesh_out

  1. Replace the filename in vis/vis_mesh.py with the built library
torch.classes.load_library("third_party/sparse_octree/build/lib.xxx/svo.xxx.so")
  1. Then run the command below. It will first reconstruct the mesh of each intermediate results and then visualize the mesh and pose.
# assign any output_folder you like, here is just an example
# create_mesh is only require to set once
cd mapping
OUTPUT_FOLDER=logs/replica/room0/FILE_NAME
python vis/vis_mesh.py \
$OUTPUT_FOLDER/bak/config.yaml \
--result_file $OUTPUT_FOLDER \
-create_mesh 

FAQ

  1. There is a conflict between OpenCV and cv_bridge during the build process of our tracking module

This issue is related to the version of cv_bridge. To resolve it, you can follow these steps (using ROS Noetic and OpenCV 4.5.2 as an example):

(1) Remove the previous cv_bridge package for the ROS version:

sudo apt-get remove ros-noetic-cv-bridge

(2) Download the new version of cv_bridge

(3) Locate the CMakeLists.txt file of cv_bridge and modify the following line to match the version of OpenCV you have installed

// In CMakeLists.txt of cv_bridge
find_package(OpenCV 4.5.2 REQUIRED) // Change it to your installed version of OpenCV

(4) Build and install the cv_bridge

mkdir build
cd build
cmake ..
make
sudo make install

(5) Add the cmake path for cv_bridge in the src/dvins/vins_estimator/CMakeLists.txt and src/dvins/pose_graph/CMakeLists.txt

set(cv_bridge_DIR /usr/local/share/cv_bridge/cmake) // At the beginning

Acknowledgement

We adapted some codes from some remarkable repositories including VINS-Fusion, NICE-SLAM, Vox-Fusion and Tiny-cuda-nn. We express our gratitude for the authors' generosity in sharing their code publicly.

Contact

You can contact the author through email: [email protected], [email protected] and [email protected]

Citing

If you find our work useful, please consider citing:

@ARTICLE{10243098,
  author={Jiang, Chenxing and Zhang, Hanwen and Liu, Peize and Yu, Zehuan and Cheng, Hui and Zhou, Boyu and Shen, Shaojie},
  journal={IEEE Robotics and Automation Letters}, 
  title={H$_{2}$-Mapping: Real-Time Dense Mapping Using Hierarchical Hybrid Representation}, 
  year={2023},
  volume={8},
  number={10},
  pages={6787-6794},
  doi={10.1109/LRA.2023.3313051}}