The Simscape Multibody Link plug-in provides the primary interface for exporting CAD assemblies into Simscape Multibody software. The plug-in is compatible with three CAD applications: Autodesk Inventor, Creo Parametric, and SolidWorks. The installation steps of Simscape Multibody Link are given below:
- Run MATLAB as administrator.
- Add the saved installation files to the MATLAB path.
- You can do this by entering
addpath('foldername')at the MATLAB command prompt. Replace foldername with the name of the folder in which you saved the installation files—e.g.,C:\Temp. - At the MATLAB command prompt, enter
install_addon('zipname'). - Replace zipname with the name of the zip archive—e.g.,
smlink.r2015b.win64.zip.
- For exporting the CAD model assembly from SolidWorks to the MATALB Simulink we need to add Simscape Multibody Link to the SolidWorks from
Settings/addins/Simscape Multibody Link. - CAD model can be exported to the 1st and 2nd generation of Simulink by
Tools/Simscape Multibody Link/ Export / Simscape Multibody1st/2nd generation, this creates the ‘.xml’ file which can be imported in to the MATLAB by using commandsmimport(‘filename.xml’)for 2nd generation ofmechimport(‘filename.xml’)for 1st generation. - After importing the Model in the Simulink, MATLAB Simulink automatically generates the Simulink block diagram of the model and ‘
.slx‘ file.
- As a test, I made one CAD model assembly of the snake robot with 4 actuated revolute joints and imported into Simulink by the steps asserted above.
- By default, all actuators have automatically calculated motion control, Hence, on starting simulation shows random movements.
- For controlling motion of each revolute joints, I used
PS Converter Blocks, which converts physical signal to the Simulink signal. Also used oneRepeating Sequence Source Blocksto give time dependent angle vectors from MATLAB workspace as the inputs of the actuators.
- User defined
MATLAB Function Blocksare used to ensure the initial conditions and definition of the domain of the input angle vectors to -90 to 90 degrees. - Angle vectors are generated by using MATLAB code including equations of the snake gaits and imported them to the
source blocksfrom MATLAB workspace.
- Cable-driven parallel manipulators (CDRPMs) are a special class of parallel robots in which rigid ex- tensile links are replaced by actuated cables. In the referenced literature, different types of workspace have been introduced based on various definitions for cable-driven parallel manipulators.
- The distal end positions and workspace of studied manipulator:
- My derived model for cable driven manipulators: Here is the mathematical model including equations for angles of each links as a function of reduced length of the cable.
δ**l1 + δ**l2 + δ**l3 = δ**L (total reduced lenght of cable)
θ1 = δL/5t × 1800/π
θ2 = 2δL/5t × 1800/π
θ3 = 2δL/5t × 1800/π
- Equations derived in the mathematical model are implemented on the 3Fingered model using Simulink blocks and controlled the reduced length of cable by dashboard control block in such a way that all the angles at the revolute joints are automatically calculated.
- In this setup the user can control the cable manually and verify the results from the simulation in the same way as in real environment.
- A proportional–integral–derivative controller (PID controller or three term controller) is a control loop feedback mechanism widely used in industrial control systems and a variety of other applications requiring continuously modulated control. A PID controller continuously calculates an error value
{\displaystyle e(t)}e(t) as the difference between a desired setpoint (SP) and a measured process variable (PV) and applies a correction based on proportional, integral, and derivative terms (denoted P, I, and D respectively). - I made one PID controller using Simulink blocks given below but Simulink PID Controller Block is used in the simulation of the given CAD models.
PID controller Blockis tuned I to get required gain values for desired reaction time.
