MotCo | Downloads

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Free version of MotCo software is available for download
New version (projected release Spring 2011)

MotCo source is currently rewritten (in Java and C++) to allow the introduction of many new features:

• New MetaGenetic algorithm
• Distributed computing
• OpenMP parallel execution
• Remote execution and web based monitoring
• New XML based file format
• Improved user interface
• New help and guide systems
• Support of predefined libraries of limbs, muscles and joints

Current version

Version 0.77b. beta features:  Ability to work with multi-joint muscles Motor Units Generator Function Wizard Approximation Wizard

Download options:  Binary Executable (ZIP, 639Kb) Full Setup (EXE, 2024Kb)

Version history

Version 0.76 beta features:  OpenGL model editor HTML report wizard

Download options:  Binary Executable (ZIP, 559 Kb) Full Setup (EXE, 1964 Kb)

Installation Notes

Click on the above link MotCo or here to download the leatest version: 2.01MB self-extracting zip archive). Unzip MCSetup using Winzip and execute Setup.exe. This will launch installation wizard that will guide you through the rest of the setup process. After full installation the program occupies approximately 3.54 MB disk space. MotCo software puts no files in Windows system folders and can be removed by deleting all associated files and folders. The demo package includes program file MC.exe and two groups of examples. The first of them includes simulated examples of elbow flexion and extension movements. The second consists of ready to run examples that use different acceleration techniques.

Minimal System Requirements

• AMD K6 II – 300MHz or Pentium II 333 MHz, 32 MB RAM
• Windows 98, Windows Me, Windows 2000, Windows NT
• OpenGL Driver Ver. 1.2
• 1.75MB free disk space.

Other downloads

Static optimization. Matlab source file for analytical solving an optimization task consisting of three moment equations, arbitrary number of monoarticular and biarticular muscles and inequality constrains ensuring the non-negativity of all muscle forces. The used optimization function is a weighted sum of the squared muscle forces (Raikova and Prilutsky, Journal of Biomechanics 34, 1243-1255, 2001).  (SOpt.m, SOpt.zip)