This repo is based on RAI code, including its python bindings. See https://github.com/MarcToussaint/rai for a README of the RAI code.
The repo is now used for three lecture formats: the robotics lab course in simulation, the robotics lab course in real, and the robotics lectures. Please follow the respective sections.
This assumes a standard Ubuntu 18.04 or 20.04 machine.
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The following assumes $HOME/git as your git path, and $HOME/opt to install 3rd-party libs -- please stick to this (no system-wide installs)
-
If you'll use python:
sudo apt-get install python3 python3-dev python3-numpy python3-pip python3-distutils
echo 'export PATH="${PATH}:$HOME/.local/bin"' >> ~/.bashrc #add this to your .bashrc, if not done already
pip3 install --user jupyter nbconvert matplotlib pybind11 opencv-python
- Clone and compile our robotics-course code:
mkdir -p $HOME/git
cd $HOME/git
git clone --recursive https://github.com/MarcToussaint/robotics-course.git
cd robotics-course
make -j1 installUbuntuAll # calls sudo apt-get install; you can always interrupt
# If this fails, please try `make -j1 printUbuntuAll` to print all packages and install manually
# if you are going to use opencv, run also
# sudo apt install libopencv-dev
mkdir build
cd build
cmake ..
make -j $(command nproc)
- If you use python, run tests:
jupyter-notebook tutorials/1-basics.ipynb
jupyter-notebook course3-Simulation
- If you use C++, compile and run the tests:
cd course3-Simulation/01-test
make
./x.exe
#and the same for all other course3-Simulation/... tests
- Alternative non-cmake build system (not recommended, but allows to configure config.mk):
cd $HOME/git/robotics-course
rm -Rf build
make -j $(command nproc)
ln -s rai/lib build
- When pulling updates for the repo, don't forget to also update the submodules:
git pull
git submodule update
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We tested this (sometimes) in docker. See here for a collection of docker setups. In mini20 the above install was tested. full18 includes a pre-compiled PhysX.
-
When enabling Physx (as alternative to bullet), first install PhysX from source as described here, then add Physx lib path to LD_LIBRARY_PATH
export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:$HOME/opt/physx3.4/lib # add path (temporary)
echo 'export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:$HOME/opt/physx3.4/lib' >> ~/.bashrc # or add permenantly in bashrc
This assumes a standard Ubuntu 18.04 machine.
In this course, check that in 'config.mk' we have (disabling lots of stuff)
ROS=0
OPENCV=0
PHYSX=0
BULLET=0
CERES = 0
NLOPT = 0
git clone --recursive https://github.com/MarcToussaint/robotics-course.git
cd robotics-course
make -j1 installUbuntuAll # calls sudo apt-get install; you can always interrupt
# If this fails, please try `make -j1 printUbuntuAll` to print all packages and install manually
make -j $(command nproc) # builds libs and tests
ln -s rai/lib build
To test the python notebooks:
# export PATH="${PATH}:$HOME/.local/bin" #add this to your .bashrc, if not done already
pip3 install --user jupyter nbconvert matplotlib
jupyter-notebook tutorials/1-basics.ipynb
After loading the pr2 and the kitchen (running first 3 cells in the notebook), the simulator window should look similar to:
- Install ROS Kinetic
- Source and install
pip install wstools catkin_pkg --user
source /opt/ros/kinetic/setup.bash
- The following assumes all git repos are cloned into $HOME/git
- clone
mkdir -p ~/git
cd ~/git
git clone --recursive https://github.com/MarcToussaint/robotics-course.git
cd robotics-course
- change
ROS = 0to#ROS = 0inconfig.mk - install also baxter sources using
cd course1-Lectures/external
./installBaxterSources.sh
- compile
make -j1 installUbuntuAll # calls sudo apt-get install; you can always interrupt
make -j4 # builds libs and tests
- if using c++, install
qtcreatoras described here - when in the lab, connect to the wifi mlr-robolab (password: mlr-robolab)
- call
source bin/baxterwlansetup.shfrom ~/git/robotics-course - source ROS and the baxter sources
source /opt/ros/kinetic/setup.bash
source external/devel/setup.bash
- IF YOU'RE THE ONLY ONE USING BAXTER, turn on baxter and call
bin/baxterStart.sh - Try
rostopic list - Try the cpp example
cd course2-Baxter/01-baxterMini
make
./x.exe -useRos 1
- Try the python example
cd course2-Baxter/01-baxterMini
jupyter-notebook motion.ipynb
- Before turning off baxter, run
rosrun baxter_tools tuck_arms.py -t
- ROS kinectic (for Ubuntu 16.04) or ROS melodic (for Ubuntu 18.04)
- OpenCV (from source)
- PhysX (from source)
- Bullet (from source)
- qtcreator (from source or ubuntu, setting up projects, pretty printers, source parsing)
- Python3:
sudo apt-get install python3 python3-dev python3-numpy python3-pip python3-distutils
sudo update-alternatives --install /usr/bin/python python /usr/bin/python3.6 1
- rai::Array and arr (tensors, arrays, std::vector)
- Features and Objectives for KOMO
- Graph and
.gfiles (Python dictionaries, any-type container, file format, logic) - Editing robot model/configuration files (URDF, transformations, frame tree)
- docker (testing rai within docker, also Ubuntu 18.04)
- Basics: Configurations, Features & Jacobians
- Features: Learn about the language to define and query features and their Jacobians. Including querying collision features (whether and which objects are in collision).
On the back of the robot near the pedestal base, there is a power button. Push it and wait for the machine to finish booting.
Connect to the lab mlr-robolab WLAN (password: mlr-robolab)
Baxter runs with ROS, and you'll need to set your environment variables to enable ROS communication. The easiest way to do this is to connect to run one of following scripts in Terminal from the mlr folder:
source bin/baxterwlansetup.sh
Call the start-up script, which enables baxter, untucks the arms, turns off the ultrasonics (they click very loudly in any videos), and calibrates the grippers.
bin/baxterStart.sh
Kill /end_effector_publisher node which corrupts the /robot/joint_states. This only has to be run once when the robot is turned on.
rosnode kill /end_effector_publisher
Switch on the air pump. Pull and slowly turn the black valve to make the air pressure around 60-100psi (preferably 70 psi, the pressure will increase slowly so turn the valve slowly as it increases) Once the pressure is set the pump will automatically keep its pressure. Turn off air pump when finished using.
The gripper can be accessed same as the electric gripper.
- To launch the ASUS camera, install openni2. Change kinetic to a different ROS version in the command if you're not using Kinetic.
sudo apt-get install ros-kinetic-openni2-launch
Plug in the camera USB and run the following command.
roslaunch openni2_launch openni2.launch depth_registration:="true" hw_registered_processing:="true" color_depth_synchronization:="true" auto_exposure:="false" auto_white_balance:="false"
- To launch the Kinect camera, install freenect. Change kinetic to a different ROS version in the command if you're not using Kinetic.
sudo apt-get install ros-kinetic-freenect-stack
Plug in the camera USB and run the following command.
roslaunch freenect_launch freenect.launch camera:="kinect"
Always tuck the arms before shutting down, to keep the spring wear to a minimum.
bin/baxterTuck.sh
or
rosrun baxter_tools tuck_arms.py -t
Then press the power button once to turn the robot off.
Alternatively, you can ssh in to the robot (password: rethink) and run:
ssh [email protected]
sudo shutdown -h now
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One some machines, OpenGL with the glfw seems broke. You'll have to change back to an older version which uses freeglut. For this, in
rai/Gui/Makefileswitch the 0/1 forFREEGLUTandGLFW -
Beware ros node names!! (Maybe it is good if everybody uses the same rosNodeName? That way they block each other? Behavior undefined!)
Within the submodules, to set ssh access, call:
git remote set-url origin [email protected]:MarcToussaint/rai.git
git remote set-url origin [email protected]:MarcToussaint/rai-robotModels.git