TGK-Planner: An Efficient Topology Guided Kinodynamic Planner for Autonomous Quadrotors
A newer version is in here.
TGK-Planner is a hierarchical trajectory planner for multirotors with a sampling-based kinodynamic front-end and an optimization back-end. It can serve as a global kinodynamic planner to find asymptotically optimal trajectories or as a local kinodynamic planner for quick replans.
Authors: Hongkai YE and Fei GAO from the ZJU Fast Lab.
Related Paper: Arxiv Preprint (Accepted by IEEE RA-L)
Video Links: Youtube, Bilibili (For Mainland China)
The repo has been tested on Ubuntu 16.04 and 18.04 with ros-desktop-full installation.
The uav_simulator depends on the C++ linear algebra library Armadillo. You can install it by:
~$ sudo apt-get install libarmadillo-dev
We recommand create a new catkin workspace:
~$ mkdir -p tgk_ws/src
Change directory to ~/tgk_ws/src and clone the repo:
~$ cd tgk_ws/src
~/tgk_ws/src$ git clone https://github.com/ZJU-FAST-Lab/TGK-Planner.git
Change directory to ~/tgk_ws and make:
~/tgk_ws/src$ cd ..
~/tgk_ws$ catkin_make
In directory ~/tgk_ws, set up the environment and launch the simulator:
~/tgk_ws$ source devel/setup.bash
~/tgk_ws$ roslaunch state_machine rviz.launch
Open another terminal, set up the environment and launch the planner:
~/tgk_ws$ source devel/setup.bash
~/tgk_ws$ roslaunch state_machine planning.launch
If everything goes well, you should be able to navigate the drone as the gif shows below. (Click 3D Nav Goal in the Rviz panel or press g in keyboard to selecet goal. Click down both left and right mouse buttons and drag to change the goal altitude.)
By default, the global map is known, and the space outside a certain local bound is treated as free.
To acquire more realistic simulations, a GPU-based onboard depth camera sensor simulator can be enabled by changing the CMakeLists.txt in the package depth_sensor_simulator as below and then re-compile. (Do not foget to change the 'arch' and 'code' flags according to your graphics card devices. You can check the right code here.)
#set(ENABLE_CUDA false)
set(ENABLE_CUDA true)
...
list(APPEND CUDA_NVCC_FLAGS -arch=sm_30)
list(APPEND CUDA_NVCC_FLAGS -gencode arch=compute_30,code=sm_30)
Set the occ_map/use_global_map param in planning.launch to false and re-launch both rviz.launch and rviz.launch as before.
<param name="occ_map/use_global_map" value="false" type="bool"/>
Now the map is built on instant depth observations.
In planning.launch:
# Smaller rho means more aggressive maneuvers and higher flying speed.
<param name="krrt/rho" value="0.13" type="double"/>
# It should decrease as rho increases.
<param name="sampler/vel_mag_mean" value="3.0" type="double" />
# Time budget for replan. More time budget leads to higher quality trajectories.
<param name="fsm/replan_time" value="0.05" type="double"/> RRT*
In simulator.launch:
# Obstacle numbers.
<param name="map/obs_num" value="550"/>
<param name="map/circle_num" value="100"/>
We use a self developed Root-Finder to solve polynomial equations.
The source code is released under GPLv3 license.
The peoject is under maintaince.
For any technical issues, please contact Hongkai YE ([email protected], [email protected]) or Fei GAO ([email protected]).