Simscape Model of the Nano-Active-Stabilization-System
Table of Contents
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-
- 1. Simulink Project (link) -
- 2. Simscape Model (link) -
- 3. Simscape Subsystems (link) -
- 4. Kinematics of the Station (link) -
- 5. Metrology (link) -
- 6. Computation of the positioning error of the Sample (link) -
- 7. Tuning of the Dynamics of the Simscape model (link) -
- 8. Disturbances (link) -
- 9. Tomography Experiment (link) -
- 10. Active Damping Techniques on the Uni-axial Model (link) -
- 11. Active Damping Techniques on the full Simscape Model (link) -
- 12. Useful Matlab Functions (link) +
- 1. Simulink Project (link) +
- 2. Simscape Model (link) +
- 3. Simscape Subsystems (link) +
- 4. Kinematics of the Station (link) +
- 5. Metrology (link) +
- 6. Computation of the positioning error of the Sample (link) +
- 7. Tuning of the Dynamics of the Simscape model (link) +
- 8. Disturbances (link) +
- 9. Tomography Experiment (link) +
- 10. Active Damping Techniques on the Uni-axial Model (link) +
- 11. Active Damping Techniques on the full Simscape Model (link) +
- 12. Useful Matlab Functions (link)
1 Simulink Project (link)
+1 Simulink Project (link)
The project is managed with a Simulink Project. @@ -288,8 +289,8 @@ Such project is briefly presented here
2 Simscape Model (link)
+2 Simscape Model (link)
The model of the NASS is based on Simulink and Simscape Multi-Body. @@ -298,8 +299,8 @@ Such toolbox is presented here.
3 Simscape Subsystems (link)
+3 Simscape Subsystems (link)
The model is decomposed of multiple subsystems. @@ -313,8 +314,8 @@ All these subsystems are described he
4 Kinematics of the Station (link)
+4 Kinematics of the Station (link)
First, we consider perfectly rigid elements and joints and we just study the kinematic of the station. @@ -324,8 +325,8 @@ This is detailed here.
5 Metrology (link)
+5 Metrology (link)
6 Computation of the positioning error of the Sample (link)
+6 Computation of the positioning error of the Sample (link)
From the measurement of the position of the sample with respect to the granite and from the wanted position of each stage, we can compute the positioning error of the sample with respect to the nano-hexapod. @@ -343,8 +344,8 @@ This is done here.
7 Tuning of the Dynamics of the Simscape model (link)
+7 Tuning of the Dynamics of the Simscape model (link)
From dynamical measurements perform on the real positioning station, we tune the parameters of the simscape model to have similar dynamics. @@ -356,8 +357,8 @@ This is explained here.
8 Disturbances (link)
+8 Disturbances (link)
The effect of disturbances on the position of the micro-station have been measured. @@ -374,8 +375,8 @@ We also discuss how the disturbances are implemented in the model.
9 Tomography Experiment (link)
+9 Tomography Experiment (link)
Now that the dynamics of the Model have been tuned and the Disturbances have included, we can simulate experiments.
@@ -387,8 +388,8 @@ Tomography experiments are simulated and the results are presented
-
Active damping techniques are applied to the Uniaxial Simscape model.
@@ -396,8 +397,8 @@ Active damping techniques are applied to the Uniaxial Simscape model.
Active damping techniques are applied to the full Simscape model.
@@ -405,8 +406,8 @@ Active damping techniques are applied to the full Simscape model.
Many matlab functions are shared among all the files of the projects.
@@ -420,8 +421,7 @@ These functions are all defined here.
10 Active Damping Techniques on the Uni-axial Model (link)
+10 Active Damping Techniques on the Uni-axial Model (link)
11 Active Damping Techniques on the full Simscape Model (link)
+11 Active Damping Techniques on the full Simscape Model (link)
12 Useful Matlab Functions (link)
+12 Useful Matlab Functions (link)