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https://github.com/mmmarinho/tro2022_adaptivecontrol

Sample code and minimal standalone example for the TRO2022 paper: "Adaptive Constrained Kinematic Control using Partial or Complete Task-Space Measurements".
https://github.com/mmmarinho/tro2022_adaptivecontrol

cpp python robotics tro2022

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Sample code and minimal standalone example for the TRO2022 paper: "Adaptive Constrained Kinematic Control using Partial or Complete Task-Space Measurements".

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README 

          
# Adaptive Constrained Kinematic Control using Partial or Complete Task-Space Measurements



## Python



### venv



```commandline

    python3 -m venv venv

    source venv/bin/activate

    python3 -m pip install dqrobotics --pre

    python3 -m pip install marinholab-papers-tro2022-adaptivecontrol

```



### When you cannot use a venv (e.g. ROS2)



```commandline

    python3 -m pip install dqrobotics --pre --break-system-packages

    python3 -m pip install marinholab-papers-tro2022-adaptivecontrol --break-system-packages

```



## Reference



Sample code and minimal example for [our TRO2022 paper](https://doi.org/10.1109/TRO.2022.3181047).



```bib

@Article{marinhoandadorno2022adaptive,

  author       = {Marinho, M. M. and Adorno, B. V.},

  title        = {Adaptive Constrained Kinematic Control using Partial or Complete Task-Space Measurements},

  journal      = {IEEE Transactions on Robotics (T-RO)},

  year         = {2022},

  month        = dec,

  doi          = {10.1109/TRO.2022.3181047},

  volume       = {38},

  number       = {6},

  pages        = {3498--3513}

}

```



## Standalone Example



- The red object represents the estimated robot, initially very wrong **on purpose** to evaluate the adaptation.

- The estimation usually converges within a few seconds using measurements from a simulated sensor.

- Simultaneously, the robot proceeds through the box, toward the target poses, without collisions. 

- You can change the pose of the `xd0` and `xd1` objects in the scene, as long as you do it **before** the simulation starts.



https://github.com/mmmarinho/tro2022_adaptivecontrol/assets/46012516/2abe0b0b-6e48-46e9-9a86-061ba013b355



## Usage 



### Download & extract the standalone version (only do this once)

```bash

cd ~

sudo apt install curl jq -y

wget $(curl -sL https://api.github.com/repos/mmmarinho/tro2022_adaptivecontrol/releases/latest | jq -r '.assets[].browser_download_url')

tar -xvf tro2022_adaptivecontrol_example.tar.xz

```

### Running



1. Open the example scene, namely `tro2022_adaptivecontrol_example/TRO2022_MarinhoAdorno_ReferenceScene.ttt` on CoppeliaSim.

2. Run

```bash

cd ~/tro2022_adaptivecontrol_example

./run_example.sh

```

### Troubleshooting



If you have the error below when running the pre-compiled example, please use `Ubuntu 22.04` or later.



```bash

./run_example.sh

bin/adaptive_control_example: /lib/x86_64-linux-gnu/libc.so.6: version GLIBC_2.32' not found (required by bin/adaptive_control_example) bin/adaptive_control_example: /lib/x86_64-linux-gnu/libc.so.6: version GLIBC_2.34' not found (required by bin/adaptive_control_example)

bin/adaptive_control_example: /lib/x86_64-linux-gnu/libstdc++.so.6: version GLIBCXX_3.4.29' not found (required by bin/adaptive_control_example) bin/adaptive_control_example: /lib/x86_64-linux-gnu/libc.so.6: version GLIBC_2.32' not found (required by lib/libdqrobotics.so)

bin/adaptive_control_example: /lib/x86_64-linux-gnu/libstdc++.so.6: version GLIBCXX_3.4.29' not found (required by lib/libdqrobotics-interface-vrep.so) bin/adaptive_control_example: /lib/x86_64-linux-gnu/libc.so.6: version GLIBC_2.32' not found (required by lib/libdqrobotics-interface-vrep.so)

bin/adaptive_control_example: /lib/x86_64-linux-gnu/libc.so.6: version `GLIBC_2.34' not found (required by lib/libdqrobotics-interface-vrep.so)

```



## Known limitations *of this example*/*TODO* list/*Extra info*



- The stopping criterion is elapsed time, so it might not converge for all initial parameters.

- The initial convergence to measurements mentioned in the paper *TODO* for this example.

- The estimated model is randomized so it might start in an implausible zone. Fixing this is *TODO* for this example.

- Sample code for partial measurements is included, but they have not been tested in this example, only in the physical robot.

The adaptation is supposed to move the parameters of the `estimated_robot` towards the ideal kinematic model defined by `real_robot` in the code. 

The robot model in CoppeliaSim is for visualization only.

- A different solver was used in the paper's experiments, in this example we use an open-source solver, so the behavior might be somewhat different.

- The final target position is, **ON PURPOSE**, chosen as somewhere the robot cannot reach. It serves to show that even in such case the robot does not collide with the environment.



## Build from source



### Ubuntu



```bash

sudo apt install g++ cmake git libeigen3-dev

```



### `macos`

```bash

brew install cmake eigen cppzmq boost

```



### Download the repo



```bash

cd ~

mkdir git

cd git

git clone https://github.com/mmmarinho/tro2022_adaptivecontrol.git --recursive

```



### Build



With all dependencies correctly configured,



```bash

cd ~/git/tro2022_adaptivecontrol

chmod +x .build.sh

./.build.sh

```



## Running



1. Open the example scene, namely `TRO2022_MarinhoAdorno_ReferenceScene.ttt` on CoppeliaSim.

2. Run

```bash

cd ~/git/tro2022_adaptivecontrol

chmod +x .run.sh

./.run.sh

```



## Example console output of the results



Running on an 8 core Ubuntu VM.



*Not considering the setup step prints*



```console

Reference timeout for xd0

  Average computational time = 0.00126314 seconds.

  Clock overruns =7 (Too many, i.e. hundreds, indicate that the sampling time is too low for this CPU).

  Final task pose error norm 2.37699e-15 (Dual quaternion norm).

  Final task translation error norm 0 (in meters).

  Final measurement error norm 9.3756e-16 (Dual quaternion norm).

  Final measurement translation error norm 0 (in meters).

Reference timeout for xd1

  Average computational time = 0.000902905 seconds.

  Clock overruns =7 (Too many, i.e. hundreds, indicate that the sampling time is too low for this CPU).

  Final task pose error norm 0.0225817 (Dual quaternion norm).

  Final task translation error norm 0.044178 (in meters).

  Final measurement error norm 0.000940036 (Dual quaternion norm).

  Final measurement translation error norm 0.001836 (in meters).

```



## Tested on



- Ubuntu 22.04 `5.19.0-41-generic #42~22.04.1-Ubuntu SMP PREEMPT_DYNAMIC Tue Apr 18 17:40:00 UTC 2 x86_64 x86_64 x86_64 GNU/Linux`

- g++ --version `g++ (Ubuntu 11.3.0-1ubuntu1~22.04.1) 11.3.0`

- CoppeliaSim EDU 5.4.1 (rev4)

- DQ Robotics cpp as shown in the submodule information.

- DQ Robotics cpp-interface-vrep as shown in the submodule information.

- DQ Robotics cpp-interface-qpoases as shown in the submodule information.

- qpOASES as shown in the submodule information.

- sas_core as shown in the submodule information.



## Changelog



- 2025.05. Updating code to work with `DQ_CoppeliaSimInterfaceZMQ`.

- 2025.06. Removed Python wrapper instructions now that it's available via PyPI.