nass-simscape/org/uncertainty_experiment.org

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Evaluating the Plant Uncertainty in various experimental conditions

Introduction   ignore

The goal of this document is to study how the dynamics of the system is changing with the experimental conditions.

These experimental conditions are:

We are interested in the dynamics from the nano-hexapod actuators to:

  • the sensors included in the nano-hexapod (force sensor, relative motion sensor)
  • the measured position of the sample with respect to the granite

The variability of the dynamics is studied for two nano-hexapod concepts:

  • a soft nano-hexapod
  • a stiff nano-hexapod

The conclusions are drawn in Section sec:conclusion

Variation of the Sample Mass

<<sec:variability_sample_mass>>

Introduction   ignore

We here study the change of dynamics due to the sample mass. To see only the effect of the sample mass, we keep the same resonance frequency of the sample, and we set it to 10kHz so it is above the dynamics of interest.

Identification   ignore

We initialize all the stages with the default parameters.

We identify the dynamics for the following sample masses, both with a soft and stiff nano-hexapod.

  masses = [1, 10, 50]; % [kg]

Plots   ignore

The following transfer functions are shown:

<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_iff_sample_mass.png
Variability of the dynamics from actuator force to force sensor with the Sample Mass (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_dvf_sample_mass.png
Variability of the dynamics from actuator force to relative motion sensor with the Sample Mass (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_err_x_sample_mass.png
Variability of the dynamics from Forces applied in task space (X direction) to the displacement of the sample in the X direction (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_err_z_sample_mass.png
Variability of the dynamics from vertical forces applied in the task space to the displacement of the sample in the vertical direction (png, pdf)

Conclusion   ignore

Let's note $\omega_0$ the first resonance which corresponds to the resonance of the payload+nano-hexapod top platform resonating on top of the nano-hexapod base.

An increase of the payload mass decreases $\omega_0$. This is more easily seem with the soft nano-hexapod as the resonance $\omega_0$ is separated from the resonances of the micro-station.

  • For the soft nano-hexapod, the main effect is the change of $\omega_0$.
  • For the stiff nano-hexapod, it also affects the others resonances corresponding to the resonances of the micro-station
$\frac{\tau_{mi}}{\tau_m}$ $\frac{d\mathcal{L}_i}{\tau_i}$ $\frac{\mathcal{X}_i}{\mathcal{F}_i}$
Soft Nano-Hexapod Changes the low frequency gain Changes the high frequency gain Changes $\omega_0$ and high frequency gain
Stiff Nano-Hexapod Changes the location of the modes and low frequency gain Changes the location of the modes and high frequency gain Changes the dynamics above $\omega_0$

Variation of the Sample Resonance Frequency

<<sec:variability_sample_freq>>

Introduction   ignore

Identification   ignore

We initialize all the stages with the default parameters.

We identify the dynamics for the following sample resonance frequency.

  mass_w = [50, 100, 500]; % [Hz]
  mass = 10; % [Kg]

Plots   ignore

The following transfer functions are shown:

<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_iff_sample_w.png
Variability of the dynamics from actuator force to force sensor with the Sample Mass (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_dvf_sample_w.png
Variability of the dynamics from actuator force to relative motion sensor with the Sample Mass (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_err_sample_w.png
Variability of the dynamics from a torque applied on the sample by the nano-hexapod in the X direction to the rotation of the sample around the X axis (png, pdf)

Conclusion   ignore

Let's note $\omega_m$ the frequency of the resonance of the Payload.

$\frac{\tau_{mi}}{\tau_m}$ $\frac{d\mathcal{L}_i}{\tau_i}$ $\frac{\mathcal{X}_i}{\mathcal{F}_i}$
Soft Nano-Hexapod No visible effect Small effect around $\omega_m$ Two c.c. zeros at $\omega_m$ followed by two c.c. poles
Stiff Nano-Hexapod Slightly change the dynamics Slightly change the dynamics Greatly affect the dynamics above the first resonance

Variation of the Spindle Angle

<<sec:variability_spindle_angle>>

Introduction   ignore

Identification

We identify the dynamics for the following Tilt stage angles.

  initializeSample('mass', 50);
  Rz_amplitudes = [0, pi/4, pi/2, pi]; % [rad]

Plots   ignore

The following transfer functions are shown:

<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_iff_spindle_angle.png
Variability of the dynamics from the actuator force to the force sensor with the Spindle Angle (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_err_spindle_angle.png
Variability of the dynamics from actuator force to absolute velocity with the Spindle Angle (png, pdf)

Conclusion   ignore

The Spindle angle has no visible effect for the soft nano-hexapod.

It has little effect on the dynamics when a stiff nano-hexapod is used. This is seem between 50Hz and 100Hz. This is probably due to the fact that the micro-station compliance is not uniform in the X and Y directions.

Variation of the Spindle Rotation Speed

<<sec:variability_rotation_speed>>

Introduction   ignore

Initialization of gravity compensation forces

We initialize all the stages such that their joints are blocked and we record the total forces/torques applied in each of these joints.

We set a payload mass of 10Kg.

  initializeSample('type', 'init', 'mass', 10);
  nano_hexapod = initializeNanoHexapod( 'type', 'init');

Finally, we simulate the system and same the forces/torques applied in each joint.

Identification

We initialize the stages with forces/torques compensating the gravity forces.

We identify the dynamics for the following Spindle rotation periods.

  Rz_periods = [60, 6, 2, 1]; % [s]

Plots

The following transfer functions are shown:

<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_iff_spindle_speed.png
Variability of the dynamics from the actuator force to the force sensor with the Spindle rotation speed (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_dvf_spindle_speed.png
Variability of the dynamics from the actuator force to the relative motion sensor with the Spindle rotation speed (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_err_spindle_speed.png
Variability of the dynamics from the actuator force in the task force to the position error of the sample (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_err_spindle_speed_coupling.png
Variability of the coupling from the actuator force in the task force to the position error of the sample (png, pdf)

Conclusion   ignore

For the stiff nano-hexapod, the rotation speed of the Spindle does not affect the (main) dynamics. It only affects the coupling due to Coriolis forces.

For the soft nano-hexapod, it greatly affects the obtained dynamics around the main resonance which corresponds to the payload vibrating on top of the nano-hexapod.

This effect is similar to the one described in rotating machinery, the c.c. poles is separated into two sets of c.c. poles, one going to decreasing frequencies while the other going to positive frequencies. This effect is due to centrifugal forces that can be modeled as negative stiffness. At some point, one of the pair of c.c. pole becomes unstable.

Also, the coupling from forces applied in the X direction to induced displacement in the Y direction becomes very high when the rotating speed is increased.

Variation of the Tilt Angle

<<sec:variability_tilt_angle>>

Introduction   ignore

Identification   ignore

We initialize all the stages with the default parameters.

We identify the dynamics for the following Tilt stage angles.

  initializeSample('mass', 50);
  Ry_amplitudes = [-3*pi/180 0 3*pi/180]; % [rad]

Plots   ignore

The following transfer functions are shown:

<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_iff_tilt_angle.png
Variability of the dynamics from the actuator force to the force sensor with the Tilt stage Angle (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_err_tilt_angle.png
Variability of the dynamics from the actuator force in the task space to the displacement of the sample (png, pdf)

Conclusion   ignore

The tilt angle has no visible effect on the dynamics.

Variation of the micro-hexapod pose

<<sec:micro_hexapod_pose>>

Introduction   ignore

Identification   ignore

We initialize all the stages with the default parameters.

We identify the dynamics for the following translations of the micro-hexapod in the X direction.

  Tx_amplitudes = [0, 5e-3, 10e-3]; % [m]

Plots   ignore

<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_iff_micro_hexapod_x.png
Variability of the dynamics from the actuator force to the force sensor with the Tilt stage Angle (png, pdf)
<<plt-matlab>>
/tdehaeze/nass-simscape/media/branch/master/org/figs/dynamics_variability_err_micro_hexapod_x.png
Variability of the dynamics from the actuator force in the task space to the displacement of the sample (png, pdf)

Conclusion   ignore

The pose of the micro-hexapod has negligible effect on the dynamics.

Conclusion

<<sec:conclusion>>

From all the experimental condition studied, the only ones that have significant effect on the dynamics are:

  • the sample mass
  • the resonance frequency of the sample
  • the rotation speed of the spindle
Soft Stiff
Sample Mass Localized effect on the resonance of the sample Effect on all the modes
Sample Resonance Localized effect at the resonance of the sample Effect on all the modes
Rotation Speed Greatly influences the dynamics and coupling No effect