Join members of the OpenSim Team on Wednesday July 26th for an introduction to OpenSim and new tools for rapidly developing musculoskeletal simulations.
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- Open the Anaconda Prompt
Create environment (python 3.9 10 recommended)
Code Block (base) C:\Users\me> conda create -n opencap-processing python=3.910
Activate environment
Code Block (base) C:\Users\me> conda activate opencap-processing
Install OpenSim within environment
Code Block (opencap-processing) C:\Users\me> conda install -c opensim-org opensim=4.4.1=py39np120py310np121
(Optional): Install an IDE such as Spyder (you can use any IDE or run code from the terminal)
Code Block (opencap-processing) C:\Users\me> conda install spyder
- Clone/download the repository to your machine
- Using Git
Navigate to the directory where you want to download the code. For example:
Code Block (opencap-processing) C:\Users\me> cd Documents
Clone the repository
Code Block (opencap-processing) C:\Users\me\Documents> git clone https://github.com/stanfordnmbl/opencap-processing.git
- Without using Git
- Download the repository by visiting https://github.com/stanfordnmbl/opencap-processing/archive/refs/heads/main.zip
- Unzip the folder
- We will assume your PATH looks like C:\Users\me\Documents\opencap-processing and that the path to the README file is C:\Users\me\Documents\opencap-processing\README.md
- Using Git
- Install required Python packages
Navigate to the repository (make sure you are in Documents)
Code Block (opencap-processing) C:\Users\me\Documents> cd opencap-processing
Install packages
Code Block (opencap-processing) C:\Users\me\Documents\opencap-processing> python -m pip install -r requirements.txt
Create environment variable for authentication, you will be prompted to provide your OpenCap credentials. An environment variable (
.env
file) will be saved after authenticating.Code Block (opencap-processing) C:\Users\me\Documents\opencap-processing> python createAuthenticationEnvFile.py
Run example.py to verify that everything was correctly installed so far. If you get some plots popping out, then you can proceed to step 10.
Code Block (opencap-processing) C:\Users\me\Documents\opencap-processing> python example.py
If you're a Mac user, you can stop here. If you're on Windows or Linux, you'll need this extra step. This part of the workshop will involve running dynamic simulations of walking using OpenSimAD, which is a custom version of OpenSim with support for Automatic Differentiation (AD). OpenSimAD requires a compiler, which is not installed by default on Windows, and the OpenBLAS libraries, which you need to manually install on Linux.
(Windows only): Install Visual Studio
The Community variant is sufficient and is free for everyone.
During the installation, select the workload Desktop Development with C++.
- The code was tested with the 2017, 2019, and 2022 Community editions.
(Linux only): Install OpenBLAS libraries
Code Block sudo apt-get install libopenblas-base
Run Examples/example_walking_opensimAD.py to verify that everything was correctly installed so far. If you see some IPOPT iterations, then you're all set. We'll go through the example during the workshop.
Code Block (opencap-processing) C:\Users\me\Documents\opencap-processing> cd Examples (opencap-processing) C:\Users\me\Documents\opencap-processing\Examples> example_walking_opensimAD.py
- (Optional): Download the processed example data from Demo #2 as reference. The folder name (4d5c3eb1-1a59-4ea1-9178-d3634610561c) is the identifier of the session. If you follow all the steps of the workshop, files will be downloaded/generated under opencap-processing/Data/4d5c3eb1-1a59-4ea1-9178-d3634610561c. If you run into issues during the workshop (eg, when compiling files), you can download the processed example data and copy them under ./opencap-processing/Data/4d5c3eb1-1a59-4ea1-9178-d3634610561c (make sure the path to the metadata file looks like: opencap-processing/Data/4d5c3eb1-1a59-4ea1-9178-d3634610561c/sessionMetadata.yaml). This should allow you to complete the workshop.
Part 2: AddBiomechanics
1. Create account
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- Open the Anaconda Prompt.
Create a new conda environment for Python 3.10.
Code Block (base) C:\Users\me> conda create -n addbio-processing python=3.10 matplotlib
Activate the conda environment.
Code Block (base) C:\Users\me> conda activate addbio-processing
- If paths to previous OpenSim versions exist on your PYTHONPATH environment variable, remove them and restart the shell.
Install the OpenSim conda package. This installs a version of OpenSim including Moco that is compatible with Python 3.10 and includes NumPy 1.21.
Code Block (addbio-processing) C:\Users\me> conda install -c opensim_admin-org opensim-moco=4.4.1=py310np121
Launch a Python interpreter from your conda environment.
Code Block (addbio-processing) C:\Users\me> python
Test the OpenSim configuration by checking the timestamp from running
Code Block >>> import opensim >>> opensim.GetVersionAndDate()
in the Python interpreter; the date should be in July 2023.
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The top level directory contained in the zip folder is /AddBiomechanics, and contains two subdirectories: /AddBiomechanics/Data and /AddBiomechanics/Results. The Data folder contains the model file, marker trajectories, and ground reaction forces needed to complete the workshop. The text editor you choose should support XML formatting since modifying the OpenSim model file will be necessary. The Results folder contains result files already processed by AddBiomechanics, which will be necessary in the latter half of the tutorial, but may be also useful if technical difficulties occur. The Scripts folder contains copies of the additional Moco scripts from the hands-on portion of the tutorial.
The completed example can be found on the web here: TGCS2023_ExampleSubject. Participants may use this link to view the settings used for the example or to visualize and plot the processed data.
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Visit the Moco website here.
Slides
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Publications
Uhlrich SD, Falisse A, Kidzinski L, Muccini J, Ko M, Chaudhari AS, Hicks JL, Delp SL (2022) OpenCap: 3D human movement dynamics from smartphone videos. bioRxiv. https://doi.org/10.1101/2022.07.07.499061
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Werling K, Bianco NA, Raitor M, Stingel J, Hicks JL, Collins SH, Delp SL, Liu CK (2023) AddBiomechanics: Automating model scaling, inverse kinematics, and inverse dynamics from human motion data through sequential optimization. bioRxiv. https://doi.org/10.1101/2023.06.15.545116
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Dembia CL, Bianco NA, Falisse A, Hicks JL, Delp SL (2020) OpenSim Moco: Musculoskeletal optimal control. PLoS Comput Biol 16(12): e1008493. https://doi.org/10.1371/journal.pcbi.1008493
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