IT&E Hexapod Experiments
Limbo experiment: IT&E code for developing hexapod experiments similar to Cully et al. (2015), Nature. This code is not replicating the exact experiments of the Nature paper, but can be seen as a more modern implementation of the underlying algorithm.
Citing this code
If you use our code for a scientific paper, please cite:
Antoine Cully, Jeff Clune, Danesh Tarapore, and Jean-Baptiste Mouret. "Robots that can adapt like animals." Nature 521, no. 7553 (2015): 503-507.
In BibTex:
@article{cully_robots_2015,
title = {Robots that can adapt like animals},
volume = {521},
pages = {503--507},
number = {7553},
journal = {Nature},
author = {Cully, Antoine and Clune, Jeff and Tarapore, Danesh and Mouret, Jean-Baptiste},
year = {2015}
}
Authors
- Author/Maintainer: Konstantinos Chatzilygeroudis
- Other contributors: Vassilis Vassiliades, Antoine Cully, Jean-Baptiste Mouret
How to compile
Dependencies
Setting up the ResiBots environment
We use the environmental RESIBOTS_DIR variable for easy configuration and library finding (it basically points to one folder where every local installation happens that is related to the project). Thus, before installing/compiling anything, make sure that you add this line to your ~/.bashrc or ~/.zshrc file:
export RESIBOTS_DIR=/path/to/resibots/installation/folderFrom now on, we assume that the RESIBOTS_DIR variable is set.
Installing DART
To simulate our hexapod we are using the DART simulator. To install use the following procedure:
sudo apt-add-repository ppa:libccd-debs/ppa
sudo apt-add-repository ppa:fcl-debs/ppa
sudo apt-add-repository ppa:dartsim/ppa
sudo apt-get update
sudo apt-get install build-essential cmake pkg-config git
sudo apt-get install libeigen3-dev libassimp-dev libccd-dev libfcl-dev libboost-regex-dev libboost-system-dev libode-dev
sudo apt-get install libopenscenegraph-dev
sudo apt-get install libtinyxml-dev libtinyxml2-dev
sudo apt-get install liburdfdom-dev liburdfdom-headers-dev
cd /path/to/tmp/folder
git clone git://github.com/dartsim/dart.git
cd dart
git checkout v6.3.0
mkdir build
cd build
cmake -DDART_ENABLE_SIMD=ON ..
make -j4
sudo make installInstalling the hexapod common files
In order to simulate the hexapod you nead to get the URDF file and the controller library:
cd /path/to/tmp/folder
git clone https://github.com/resibots/hexapod_common.git
cd hexapod_common/hexapod_models
./waf configure --prefix=$RESIBOTS_DIR
./waf install
cd ../hexapod_controller
./waf configure --prefix=$RESIBOTS_DIR
./waf
./waf installInstalling the DART wrapper
To facilitate the simulation we have created a simple wrapper over the DART simulator that is specific to our hexapod robot:
cd /path/to/tmp/folder
git clone https://github.com/resibots/hexapod_simu.git
cd hexapod_simu/hexapod_dart
./waf configure --prefix=$RESIBOTS_DIR
./waf
./waf installInstalling limbo's dependencies
sudo apt-get update
sudo apt-get install libeigen3-dev libboost-serialization-dev libboost-filesystem-dev libboost-test-dev libboost-program-options-dev libboost-thread-dev libboost-regex-dev libboost-graph-dev
sudo apt-get install libtbb-devCompiling the experiment
- Get limbo:
git clone https://github.com/resibots/limbo.git - Go to your
limboroot directory - Create an experiment folder (if there's none) and cd to it:
mkdir exp && cd exp - Clone ite_v2:
git clone https://github.com/resibots/ite_v2.git - Go back to your
limboroot directory - Configure the experiment:
./waf configure --exp ite_v2 - Compile the experiment:
./waf --exp ite_v2
How to run
- Compile the experiment (as shown above)
- Run it (assuming you are on limbo root dir and the
RESIBOTS_DIRfolder is set properly):./build/exp/ite_v2/hexapod_simu path_to_archive [-l id_of_to_be_removed] [-n number_of_BO_iterations]./build/exp/ite_v2/hexapod_graphic path_to_archive [-l id_of_to_be_removed] [-n number_of_BO_iterations]for the graphics version- the ids of the legs are zero-based; i.e., they span from 0 to 5
- Some already generated archives (to save you time) are in the
archivesfolder. You can use map_elites_hexapod_v2 to generate new ones.
Funding
This work has been funded by the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement number 637972 - ResiBots).