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Scripting environments like Matlab, Python and the OpenSim GUI shell allow users to interact with the classes of the OpenSim API (see The Introduction to the OpenSim API). There are many example scripts that are located in the OpenSim scripting folder, available with the distribution to help you get started. This page summarizes is resources of some of the common calls that you will make in the scripting environment of your choice. 

...

Beginner Scripting Resources  

  • Run the example scripts found in the distribution.
  • As you run the example scripts, find the related Classes and Methods in 
    New window link
    BodyDoxygen
    Linkhttps://simtk.org/api_docs/opensim/api_docs/
  • The structure for classes can often be found in OpenSim's files (.xml or .osim). For example, Setup_Scale.xml shows the hierarchy of the ScaleTool.
  • Use the
    New window link
    BodyOpenSim Search bar
    Linkhttp://opensim.stanford.edu/support/index.html
     to search for a Class or Method in the documentation, on the forum or on the Doxygen pages. 
  • If you are having trouble with a Class or Method, ask a question on the 
    New window link
    BodyOpenSim forum
    Linkhttps://simtk.org/forums/viewforum.php?f=91&sid=c0e8a20a44fe5ca1524b3bb78fe03dcf&sid=26e02750f974c25f796217f05616c06a
    .

Inline Method and Type getting

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Packages and libraries are collections of classes and methods (see Introduction to the OpenSim API for background) that have a well-defined interface and can be imported into your programming environment to utilize. These can be packages to browse files, read and write files, do mathematics operations, and run  run simulations. The commands below are common packages or libraries you will find useful.

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Code Block
languagepython
titleBuilding a MarkerSet Object from file and attaching it to a Model
>>> myModel = modeling.Model("gait2354_simbody.xmlosim")         		      # Load a Model from file
>>> markerSetFile = "gait2354_MarkerSet.xml"				                # Define the full path to the MarkerSet file
>>> newMarkers = modeling.MarkerSet(myModel, markerSetFile)	 # Construct a MarkerSet Object 
>>> myModel.updateMarkerSet(newMarkers)						                     # Append newMarkers to the Model's MarkerSet, replacing markers with the same name

...

Code Block
languagepython
titleBuilding a MarkerSet Object Programmatically and attaching it to a Model
>>> myModel = modeling.Model("gait2354.osim")				# Create a Model Object
>>> pelvisbody =                          # Create a Model Object
>>> pelvisbody = myModel.getBodySet().get("pelvis")			                         # Get a handle to the pelvis body
>>> newMarkerSetnewMarker = modeling.MarkerSet()						# Create an empty MarkerSet Object
>>> newMarkerSet.addMarkers("LASI", [1, 1, 1], pelvisbody)	# Add a Marker to the MarkerSetMarker("LASI", pelvisbody, modeling.Vec3(1,1,1))   # Create a Marker called 'LASI', that is attached to the pelvis at [(1,1,1])
>>> myModel.replaceMarkerSetaddMarker(myState,newMarkers)			# Replace the models existing MarkerSet with new MarkerSet
>>> myState = myModel.initSystem()newMarker)                                     # Initialize the system and obtain the default# stateAdd  newMarker to the Model


Code Block
titleBuilding a Body Programmatically in Matlab
>> nBodynewBody  = Body(); 										                                        % Creates ana body with default mass=1
>> massCenter = Vec3(-0.0707,0.0,0.0);						% Create a Vec3 Object with Mass center information
>> inertiaMat = Mat33(0.1028,0,0,0,0.0871,0,0,0,0.0579);	% Create a Mat33 (3x3 Matrix) with inertial information
>> nBody.setName('pelvis')									                       % Create a Vec3 Object with mass center information
>> inertia = Inertia(0.128, 0.0871, 0.0579, 0, 0, 0);        % Create an Inertia object with only principal axes
>> newBody.setName('pelvis');                                % Set the name of the body using a string
>> nBodynewBody.setMass(11)										% Set the mass of the body using a double
>> nBody.setMassCenter(massCenter)							% Set the Mass Center
>> nBody.setInertia(inertiaMat)								% Set the Inertia 
 
%% Alternatively, a body can be created by sending all of these properties directly to the constructor
>> massCenter = Vec3(-0.0707,0.0,0.0);						% Create a Vec3 Object with Mass center information
>> inertiaMat = Mat33(0.1028,0,0,0,0.0871,0,0,0,0.0579);	% Create a Mat33 (3x3 Matrix) with inertial information
>> bodyName = 'pelvis'										% Set the name of the body using a string
>> bodyMass = 11											% Set the mass of the body using a double
>> nBody  = Body(bodyName,bodyMass,massCenter,inertiaMat);	% Creates an body from properties sent to constructor
Code Block
titleCreate a Joint programmatically in Matlab
>> pBody  = Body('pelvis', bodyMass,massCenter,inertiaMat); 	% Either create or get a handle to the parent body
>> cBody  = Body('femur_r',bodyMass,massCenter,inertiaMat);		% Either create or get a handle to the child body
>> name = 'hip_r'												% Assign the joint name
>> locInParent   = Vec3(-0.0707,-0.0661,0.0835);				% A Vec3 location in the parent frame
>> orienInParent = Vec3(0,0,0);									% A Vec3 orientation in the parent frame
>> locInChild = Vec3(0,0.0,0);									% A Vec3 location in the child frame
>> orienInChild= Vec3(0,0,0);									% A Vec3 orientation in the child frame
>> rrHip = BallJoint(name,nBody,locInParent,orienInParent,cBody,locInChild,orienInChild)
Code Block
titleCreate a Torque Actuator for the Knee Joint (flex/ext) programmatically in Matlab
>> myModel = Model('gait2354.osim');				# Create a Model Object
>> femur_r = myModel.getBodySet().get('femur_r');	# Get a Handle to the Body A
>> tibia_r  = myModel.getBodySet().get('tibia_r');	# Get a Handle to the Body B
>> zAxisTorque = Vec3(0,0,1);					# A Vec3 of the z-axis
>> torqueActuator = TorqueActuator();			# Create a Torque Actuator Object
>> torqueActuator.setBodyA(femur_r); 			# Set Body A
>> torqueActuator.setBodyB(tibia_r);			# Set Body B
>> torqueActuator.setAxis(zAxisTorque);			# Set the axis about the torque to act
>> torqueActuator.setOptimalForce(10);			# Set the optimal force (gain) of the actuator
Code Block
languagepy
titleCreate a Coordinate Actuator programmatically in Python
>>> myModel = opensim.Model("arm26.osim")
>>> coordActuator = opensim.CoordinateActuator()
>>> coordActuator.setName('r_elbow_actuator')
>>> coordActuator.setCoordinate(myModel.getComponent('r_shoulder/r_shoulder_elev'))

Loading, Creating, and Initializing Models

Loading models and dealing with model states is very common. Below are the methods for loading, copying and initializing a model

ActionGUI CommandMatlab/Python Command
Loads the specified model in the GUIloadModel(modelFileName) 
Creates a handle to the current model in the GUImyModel = getCurrentModel() 
Load a model from file (Create Model Object)myModel = modeling.Model(modelFileName)myModel = Model('gait2354.osim')
Creates a copy of myModel.myModelCopy = modeling.Model(myModel)myModelCopy = Model(myModel)
Initialize the model and get the default statemyState = myModel.initSystem()myState = myModel.initSystem()
Code Block
languagepython
titleLoading a Model and States in the GUI Scripting Window
>>> modelFileName = modelFolder+"/gait2354_simbody.osim" # Define the full path to the model file
>>> loadModel(modelFileName);                                      % Set the mass of the body
>> newBody.setMassCenter(massCenter);                        % Set the mass center
>> newBody.setInertia(inertia);                              % Set the body's inertia 
 
%% Alternatively, a body can be created by sending all of these properties directly to the constructor
>> massCenter = Vec3(-0.0707,0.0,0.0);                       % Create a Vec3 Object with Mass center information
>> inertia = Inertia(0.128, 0.0871, 0.0579, 0, 0, 0);        % Create an Inertia object with only principal axes
>> bodyName = 'pelvis';                                      % Set the name of the body
>> bodyMass = 11;                                            % Set the mass of the body
>> newBody = Body(bodyName, bodyMass, massCenter, inertia);  % Creates a body from properties sent to constructor


Code Block
titleCreate a Joint programmatically in Matlab
>> pBody = Body('pelvis', bodyMass, massCenter, inertia);       % Create the parent body
>> cBody = Body('femur_r', bodyMass, massCenter, inertia);      % Create the child body
>> name = 'hip_r';                                              % Joint name
>> locInParent = Vec3(-0.0707,-0.0661,0.0835);                  % Location of the joint origin expressed in the parent frame
>> oriInParent = Vec3(0,0,0);                                   % Orientation of the joint frame in the parent frame
>> locInChild = Vec3(0,0,0);                                    % Location of the joint origin expressed in the child frame
>> oriInChild = Vec3(0,0,0);                                    % Orientation of the joint frame       # Load in the model into the GUI
>>> myModelchild frame
>> rHip = getCurrentModelBallJoint()name, pBody, locInParent, oriInParent, cBody, locInChild, oriInChild); % Construct the                 # Create a handle to the current model
>>> myState = myModel.initSystem()                       # Initialize the model and obtain the default state

Exploring and Editing Models and Model Components

You can use the functionality of the OpenSim API to access the properties of a model and change their values. For examples, refer to the distributed scripts muscleScaler and alterTendonSlackLength. The OpenSim API Doxygen lists all of the available functions. For example, executing the following commands in the GUI scripting shell, sets and gets the name of the current model. 

Code Block
languagepython
>>> myModel = getCurrentModel()
>>> myModel.setName("My Model")
>>> mymodel.getName()  
>>> "my Model"
Info
You should
hip joint


Code Block
titleCreate a Torque Actuator for the Knee Joint (flex/ext) programmatically in Matlab
>> myModel = Model('gait2354.osim');                % Create a Model Object from file
>> femur_r = myModel.getBodySet().get('femur_r');   % Get a handle to the femur
>> tibia_r  = myModel.getBodySet().get('tibia_r');  % Get a handle to the tibia
>> zAxis = Vec3(0,0,1);                             % A Vec3 of the z-axis
>> torqueActuator = TorqueActuator();               % Create a TorqueActuator Object
>> torqueActuator.setBodyA(femur_r);                % Set BodyA
>> torqueActuator.setBodyB(tibia_r);                % Set BodyB
>> torqueActuator.setAxis(zAxis);                   % Set the axis about which the torque will act
>> torqueActuator.setOptimalForce(10);              % Set the optimal force (gain) of the actuator


Code Block
languagepy
titleCreate a Coordinate Actuator programmatically in Python
>>> myModel = opensim.Model("arm26.osim")
>>> coordActuator = opensim.CoordinateActuator()
>>> coordActuator.setName('r_elbow_actuator')
>>> coordActuator.setCoordinate(myModel.getComponent('r_shoulder/r_shoulder_elev'))

Loading, Creating, and Initializing Models

Loading models and dealing with model states is very common. Below are the methods for loading, copying and initializing a model

ActionGUI CommandMatlab/Python Command
Loads the specified model in the GUIloadModel(modelFileName)
Creates a handle to the current model in the GUImyModel = getCurrentModel()
Load a model from file (Create Model Object)myModel = modeling.Model(modelFileName)myModel = Model('gait2354.osim')
Creates a copy of myModel.myModelCopy = modeling.Model(myModel)myModelCopy = Model(myModel)
Initialize the model and get the default statemyState = myModel.initSystem()myState = myModel.initSystem()


Code Block
languagepython
titleLoading a Model and States in the GUI Scripting Window
>>> modelFileName = modelFolder+"/gait2354_simbody.osim" # Define the full path to the model file
>>> loadModel(modelFileName)                             # Load the model into the GUI
>>> myModel = getCurrentModel()                          # Create a handle to the current model
>>> myState = myModel.initSystem()                       # Initialize the model and obtain the default state


Exploring and Editing Models and Model Components

You can use the functionality of the OpenSim API to access the properties of a model and change their values. For examples, refer to the distributed scripts muscleScaler and alterTendonSlackLength. The OpenSim API Doxygen lists all of the available functions. For example, executing the following commands in the GUI scripting shell, sets and gets the name of the current model. 

Code Block
languagepython
>>> myModel = getCurrentModel()
>>> myModel.setName("My Model")
>>> mymodel.getName()  
>>> "my Model"


Info

You should generally avoid adding and removing objects from a model that is "live" in the OpenSim GUI. Instead you should make a copy of the model, make additions and deletions, then reload in the GUI.

...

ActionClass InformationGetting a Handle to a SetReference an Object by indexGet object from a nameAlternative 'long path'
Body Set
New window link
BodyOpenSim::BodySet
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1BodySet.html
bodySet= myModel.getBodySet()rightFemur = bodySet().get(1)rightFemur = bodySet().get("femur_r")rightFemur =myModel.getBodySet().get("femur_r")
Joint Set
New window link
BodyOpenSim::JointSet
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1JointSet.html
jointSet = myModel.getJointSet()rightHip = jointSet ().get(7)rightHip = jointSet().get("hip_r")rightHip = myModel.getJointSet().get("hip_r")
Coordinate Set
New window link
BodyOpenSim::CoordinateSet
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1CoordinateSet.html
cordSet= myModel.getCoordinateSet()hip_coord = cordSet().get(4)hip_coord = cordSet().get("hip_flexion_r")hip_coord = cordSet().get("hip_flexion_r")
Muscle Set
New window link
BodyMuscles
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1Muscle.html
muscleSet= myModel.getMuscles()recFemR = muscleSet().get(3)rec_fem_r = recFemRt().get("'recFem_r")rec_fem_r= myModel.getMuscles().get("'recFem_r")
Path Point of a Muscle
New window link
BodyOpenSim; PathPoint
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1PathPoint.html
pathPoints = myModel.getMuscles().get("'recFem_r").getGeometryPath().getPathPointSet()recFemPathPoint1 = pathPoints.get(0)recFemPathPoint1 = pathPoints.get("rect_fem_r-P1")recFemPathPoint1 = myModel.getMuscles().get("'recFem_r").getGeometryPath().getPathPointSet()

...

Code Block
languagepython
titleChange the ECRB muscle properties in the GUI
>>> ECRB = myModel.getMuscles().get("ECRB")               # Get a handle to the ECRB
>>> backupTendonSlackLength = ECRB.getTendonSlackLength() # Back up the original tendon slack length (just in case)
>>> ECRB.setTendonSlackLength(0.2105)                     # Prescribe a new Tendon slack length
>>> myModel.initSystem()                                  # Re-initialize the model

 


You may need to downcast an object from an abstract class (e.g., Muscle)  to a derived class (e.g., Thelen2003Muscle) in order to gain access to its properties and methods. Here is an example:

Code Block
languagenone
>> import org.opensim.modeling.*
>> myModel = Model('arm26.osim');
>> mcl_TRIlong = Thelen2003Muscle.safeDownCast( myModel.getMuscles().get('TRIlong') );
>> mcl_TRIlong.setFmaxTendonStrain( 0.5*mcl_TRIlong.getFmaxTendonStrain() );

 

Using the Tools

Tools contain a number of grouped Methods that allow you to run a study. For example, to scale a Model to match experimental data the ScaleTool groups GenericModelMaker(), ModelScaler() and MarkerPlacer() together. The AnalyzeTool() can group StaticOptimization() and MuscleAnalysis() together to output muscle states of a Static Optimization.  

ClassDoxygen LinkDefault construction (Scripting shell)XML construction (Scripting shell)
Scale
New window link
BodyOpenSim:: ScaleTool
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1Scale.html
scaleTool = modeling.ScaleTool()scaleTool = modeling.ScaleTool([path 'scale_Setup.xml'])
InverseKinematicsTool
New window link
BodyOpenSIm:: InverseKinematicsTool
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1InverseKinematicsTool.html
ikTool = modeling.InverseKinematicsTool()idTool = modeling.InverseKinematicsTool([path 'IK_Setup.xml'])
InverseDynamicsTool
New window link
BodyOpenSim:: InverseDynamicsTool
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1InverseDynamicsTool.html
idTool = modeling.InverseDynamicsTool()idTool = modeling.InverseDynamicsTool([path 'ID_Setup.xml'])
RRATool
New window link
BodyRRA Tool
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1RRATool.html
rraTool = modeling.RRATool()rraTool = modeling.RRATool([path 'RRA_Setup.xml'])
CMCTool
New window link
BodyOpenSim::CMCTool
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1CMCTool.html
cmcTool = modeling.CMCTool()cmcTool = modeling.CMCTool([path 'CMC_Setup.xml'])
ForwardTool
New window link
BodyForwardTool
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1ForwardTool.html
cmcTool = modeling.ForwardTool()cmcTool = modeling.ForwardTool([path 'forward_Setup.xml'])
AnalyzeTool
New window link
BodyOpenSim::AnalyzeTool
Linkhttps://simtk.org/api_docs/opensim/api_docs/classOpenSim_1_1AnalyzeTool.html
analyzeTool = modeling.AnalyzeTool()analyzeTool = modeling.AnalyzeTool([path 'analyze_Setup.xml'])

Working with Files and Paths

Below are examples of the OpenSim GUI shells native commands with files and file paths. Matlab and Python environments have their own methods for dealing with files and file paths. 

...

( 0.5*mcl_TRIlong.getFmaxTendonStrain() );


Parent and Concrete Classes

If you are calling a method or function (e.g., getting or setting properties) that you are pretty sure should work, but you are getting an error that the method doesn't exist, this may mean that you need to downcast. In the C++ programming language, programmers use a concept called "inheritance" to build up complexity without re-writing the same code multiple times. For example, in OpenSim Thelen2003Muscle and MillardMuscle both rely on code in the common parent Muscle class that they "inherit" from.

If you have a handle to a base class object (e.g. Muscle)  you may need to downcast the object to one of its derived (or concrete) classes, like the Thelen2003Muscle, in order to gain access to properties and methods specific to the concrete class. In the below example, we get a reference to a muscle in the model and return the class name and concrete class name;

Code Block
>>> model = Model(path2model)
>>> muscle = model.getMuscles().get(0);
>>> muscle.getClassName()
muscle
>>> muscle.getConcreteClassName()
Thelen2003Muscle


Then to get a reference to the concrete class you use the safeDownCast() method. 

Code Block
>>> muscle = model.getMuscles().get(0);    # The object you get here is of base class Muscle
>>> thelenMuscle = Thelen2003Muscle.safeDownCast(muscle)  # To use a method specific to Thelen2003Muscle you need to safeDownCast
>>> timeConstant = thelenMuscle.getActivationTimeConstant() # Get property that is present is specific to Thelen2003Muscle 


Outputs

OpenSim 4.0 uses component outputs and reporters to collect variables of interest and print them to file. To display the output names for a component, use the method getOutputNames();

Code Block
>>> muscle.getOutputNames();

Reading Data from TRC Files into TimeSeriesTable

To read marker trajectories from a trc file into a TimeSeriesTableVec3, construct a table by passing the filename into the TimeSeriesTableVec3 constructor. Afterwards, you can query the TimeSeriesTable for the data as shown in the code snippet below.

Code Block
>>> markerData  = TimeSeriesTableVec3('markerdata.trc');
>>> numDataRows = markerData.getNumRows();
>>> numMarkersInTable = markerData.getNumColumns();


Using the Tools

Tools contain a number of grouped Methods that allow you to run a study. For example, to scale a Model to match experimental data the ScaleTool groups GenericModelMaker(), ModelScaler() and MarkerPlacer() together. The AnalyzeTool() can group StaticOptimization() and MuscleAnalysis() together to output muscle states of a Static Optimization. Tools can be initialized from a setup file (.xml) that has stored settings. They also have methods that methods can be called to change the input models, data files, and some settings. Use the API documentation or methodsview() in Matlab (described above) to explore the methods that are available for the Tool you are using. 

Command or ClassPlatformAction
scale = ScaleTool('Scale_Setup_file.xml')MatlabReturns a Scaletool object with properties defined in the Scale_Setup_File.xml 

ik = InverseKinematicsTool()

ik.run()

Matlab

Returns an InverseKinematicsTool object with default properties. You must set the properties of the tool. 

Begin the Inverse Kinematics simulation by calling the run() method.

rra = RRATool'RRA_Setup.xml')

rra.setAdjustCOMToReduceResiduals(1)

rra.run()

Matlab

Returns an RRATool object with properties defined in the RRA.

Allow RRA to alter the trunk COM by using the setAdjustCOMToReduceResiduals() method.

Begin the RRA simulation by calling the run() method.

so = AnalyzeTool('SO_Setup.xml')MatlabReturns an AnalzeTool that has a Static Optimization analysis included. 


Working with Vectors, Matrices, and Other SimTK Classes

...

  • For Simbody doxygen links above Vec3P corresponds to a modeling.Vec3 object and RealP corresponds to a double value.
  • To see the available methods for these objects, use methodsview() or tab completion (Matlab only).
  • You can find more information in the SimTK Basics section of the User's Guide. Note that only the SimTK classes listed above are available through scripting.
  • You can also find more information in the section below on Handling C++ Templates.

ArrayDouble

In many cases the function you're trying to call takes an argument type different from the object you have already. This is true even moving data between Matlab and Java objects, and between objects in the SimTK namespace and those in the OpenSim namespace. In particular, many OpenSim methods return an ArrayDouble (Array<double) and you would prefer to convert the array to a different type. The following set of convenience methods are "Adaptors" intended to help you pass data around between OpenSim objects and low level SimTK objects.

...

Advanced Multibody Calculations with Simbody

In 4.0, you can perform advanced multibody calculations in scripting via the SimbodyMatterSubsystem inside the OpenSim Model (model.getMatterSubsystem()). The SimbodyMatterSubsystem class allows you to compute the mass matrix, Jacobians, inverse dynamics moments, etc.

...

titleUse the Simbody Inverse Dynamics Operator in Matlab

...

In 4.0, you can perform advanced multibody calculations in scripting via the SimbodyMatterSubsystem inside the OpenSim Model (model.getMatterSubsystem()). The SimbodyMatterSubsystem class allows you to compute the mass matrix, Jacobians, inverse dynamics moments, etc.

Code Block
titleUse the Simbody Inverse Dynamics Operator in Matlab
model = Model('arm26.osim');
s = model.initSystem();
% For the given inputs, we will use the inverse dynamics operator
% (calcResidualForce()) to compute the first column
% of the mass matrix. We accomplish this by setting all inputs to 0
% except for the acceleration of the first coordinate.
%   f_residual = M udot + f_inertial + f_applied 
%              = M ~[1, 0, ...] + 0 + 0
model.realizeVelocity(s);
appliedMobilityForces = Vector();
appliedBodyForces = VectorOfSpatialVec();
knownUdot = Vector(s.getNU(), 0.0);
knownUdot.set(0, 1.0);
knownLambda = Vector();
residualMobilityForces = Vector();
smss = model.getMatterSubsystem();
smss.calcResidualForce(s, appliedMobilityForces, appliedBodyForces, ...
                     = M ~[1knownUdot, 0, ...] + 0 + 0
model.realizeVelocity(s);
appliedMobilityForces = Vector();
appliedBodyForces = VectorOfSpatialVec();
knownUdot = Vector(s.getNU(), 0.0);
knownUdot.set(0, 1.0);
knownLambda = Vector();
residualMobilityForces = Vector();
smss = model.getMatterSubsystem();
smss.calcResidualForce(s, appliedMobilityForces, appliedBodyForces, ...
                       knownUdot, knownLambda, residualMobilityForces);

Handling C++ Templates (e.g. Array<double>)

Templates are advanced C++ constructs that are used extensively throughout the OpenSim API and Simbody API. If you see notation like Array<double> in the doxygen or C++ code that you are trying to replicate, this means you're working with a templatized class and will need to find its appropriate mapping in the scripting environment.

C++ templates allow the compiler to automatically generate classes from a common code base. This approach is useful primarily for containers (e.g. Array<double>, Array<int>, Array<string>) since it avoids code duplication making the code easier to maintain; however, these templates exist only in C++ and do not map easily to scripting languages.

One way to work around this is to specialize templates into classes, give those classes unique names, and then use them in scripting. The attached file lists template specializations used in OpenSim API (C++) & Doxygen and the corresponding named classes to be used in scripting (the list is current as of OpenSim 3.2):

Mapping of Templates to Class Names for Scripting

Obtaining Position and Velocity Information

For more information regarding multibody system states, refer to the SimTK Simulation Concepts documentation in the Developer's Guide.

In order to obtain simulation position or velocity state information you must have a State object in hand. 

Code Block
languagepython
titleUsing State Objects
>>> state = myModel.initSystem();
>>> myModel.equilibrateMuscles(state);

Now you can use methods on Body objects (actually, from the Frame class) to obtain the location or velocity of a point in the ground frame.

Code Block
languagepy
>>> body = myModel.getBodySet().get('r_ulna_radius_hand')
>>> massCenter = body.getMassCenter(massCenter)
>>> body.getStationVelocityInGround(state, massCenter)
>>> dir(body) # List other methods available on Body.

Using the Simbody Visualizer

You can use the visualizer from Simbody in Matlab and Python. To do so call the "setUseVisualizer" method and pass in the parameter "true", and when you run the simulation the Simbody Visualizer GUI will pop up. The example of usage is described in "TugOfWar_CompleteRunVisualizer.m"

Code Block
osimModel = Model('tug_of_war_muscles_controller.osim');
osimModel.setUseVisualizer(true);knownLambda, residualMobilityForces);

Class Templates (Vec3(), Array<double>, Vector() )

A summary of Templatized Class use in scripting can be found on the Scripting Versions of OpenSim C++ API Calls page. 

Templates are advanced C++ constructs that are used extensively throughout the OpenSim API and Simbody API. If you see notation like Array<double> in the doxygen or C++ code that you are trying to replicate, this means you're working with a templatized class and, to use that class in scripting, will need to find its appropriate mapping in the scripting environment. For more information, and a easy to use ummary of the C++ to scripting mappings, see the Scripting Versions of OpenSim C++ API Calls page. 

Obtaining Position and Velocity Information

For more information regarding multibody system states, refer to the SimTK Simulation Concepts documentation in the Developer's Guide.

In order to obtain simulation position or velocity state information you must have a State object in hand. 

Code Block
languagepython
titleUsing State Objects
>>> state = myModel.initSystem();
>>> myModel.equilibrateMuscles(state);

Now you can use methods on Body objects (actually, from the Frame class) to obtain the location or velocity of a point in the ground frame.

Code Block
languagepy
>>> body = myModel.getBodySet().get('r_ulna_radius_hand')
>>> massCenter = body.getMassCenter(massCenter)
>>> body.getStationVelocityInGround(state, massCenter)
>>> dir(body) # List other methods available on Body.

Using the Simbody Visualizer

You can use the visualizer from Simbody in Matlab and Python. To do so call the "setUseVisualizer" method and pass in the parameter "true", and when you run the simulation the Simbody Visualizer GUI will pop up. The example of usage is described in "TugOfWar_CompleteRunVisualizer.m"

Code Block
osimModel = Model('tug_of_war_muscles_controller.osim');
osimModel.setUseVisualizer(true);

Set verbosity or logging level

Info

Applies to OpenSim 4.2 (unreleased) and above.

You can control how much detail is printed to the console using the following:

Code Block
Logger.setLevel("Off");
Logger.setLevel("Critical");
Logger.setLevel("Error");
Logger.setLevel("Warn");
Logger.setLevel("Info"); % default
Logger.setLevel("Debug");
Logger.setLevel("Trace");

When performing batch processing or optimization you can turn off logging completely by calling Logger.setLevel("Off").

You can always add a new file during runtime to start logging into (in addition to whatever the current logging behavior is). This can be done by calling

Code Block
languagecpp
Logger.addFileSink('logs_folder/full_path.log');

Make sure you have permission to write to the logs_folder.

Batch Processing

There are several examples in the Matlab scripts and GUI scripts that show how to perform batch processing by calling the OpenSim API (e.g. Analyze, IK). We encourage you to use this approach rather than using Matlab's xml parsing tools. To read more about why this is the case, please see the scripting FAQ:

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