Vibrations induced by the translation stage motion
Table of Contents
1 Measurement description
Setup: Two geophone are use:
- One is on the marble (corresponding to the first column in the data)
- One at the sample location (corresponding to the second column in the data)
Two voltage amplifiers are used, their setup is:
- gain of 40dB (the gain had to be lowered from 60dB to 40dB in order to not saturate the voltage amplifiers)
- AC/DC switch on AC
- Low pass filter at 1kHz
A first order low pass filter is also added at the input of the voltage amplifiers.
Scans are done with the translation stage following sinus reference at 1Hz with amplitude of 600 000 cnt (= 3mm) The scans are done with the ELMO software.
The North of the Geophones corresponds to the +Y direction and the East of the Geophones to the +X direction (see figure 1).
The spindle and slip-ring are turned ON. The Hexapod and the tilt-stage are OFF.
Goal:
- Determine the disturbances induced by the translation stage in the Z and X directions when scanning along the Y direction
Measurements: Three measurements are done:
| Measurement File | Description |
|---|---|
mat/data_040.mat |
Z direction |
mat/data_041.mat |
E direction |
mat/data_042.mat |
E direction without any motion (Ty OFF) |
Each of the measurement mat file contains one data array with 3 columns:
| Column number | Description |
|---|---|
| 1 | Geophone - Marble |
| 2 | Geophone - Sample |
| 3 | Time |
Figure 1: Picture of the experimental setup
We also use the file mat/data_051.mat when we measure the z direction when everything is off.
The setup used for the measurement is described here.
2 Measurement Analysis
All the files (data and Matlab scripts) are accessible here.
2.1 Load data
z_ty = load('mat/data_040.mat', 'data'); z_ty = z_ty.data; z_of = load('mat/data_051.mat', 'data'); z_of = z_of.data; e_ty = load('mat/data_041.mat', 'data'); e_ty = e_ty.data; e_of = load('mat/data_042.mat', 'data'); e_of = e_of.data;
There is probably a sign error for the Geophone located on top of the Hexapod (only for the z direction). The problem probably comes from the wiring in the Slip-Ring.
z_ty(:, 2) = -z_ty(:, 2);
2.2 Voltage to Velocity
We convert the measured voltage to velocity using the function voltageToVelocityL22 (accessible here).
gain = 40; % [dB] z_ty(:, 1) = voltageToVelocityL22(z_ty(:, 1), z_ty(:, 3), gain); z_of(:, 1) = voltageToVelocityL22(z_of(:, 1), z_of(:, 3), gain); e_ty(:, 1) = voltageToVelocityL22(e_ty(:, 1), e_ty(:, 3), gain); e_of(:, 1) = voltageToVelocityL22(e_of(:, 1), e_of(:, 3), gain); z_ty(:, 2) = voltageToVelocityL22(z_ty(:, 2), z_ty(:, 3), gain); z_of(:, 2) = voltageToVelocityL22(z_of(:, 2), z_of(:, 3), gain); e_ty(:, 2) = voltageToVelocityL22(e_ty(:, 2), e_ty(:, 3), gain); e_of(:, 2) = voltageToVelocityL22(e_of(:, 2), e_of(:, 3), gain);
2.3 Time domain plots
We plot the measured velocity of the marble and sample in the vertical direction (figure 2) and in the X direction (figure 3).
We also integrate the relative velocity to obtain the relative displacement (figure 4 in the X direction and figure 5 in the Z direction).
Figure 2: Z velocity of the sample and marble when scanning with the translation stage
Figure 3: Velocity of the sample and marble in the east direction when scanning with the translation stage
Figure 4: X relative displacement of the sample with respect to the marble
Figure 5: Z relative disp of the sample with respect to the marble
2.4 Frequency Domain
We load measured ground motion at ID31 to compare with the velocities measured.
gm = load('../ground-motion/mat/psd_gm.mat', 'f', 'psd_gm', 'psd_gv');
We first compute some parameters that will be used for the PSD computation.
dt = z_ty(2, 3)-z_ty(1, 3); Fs = 1/dt; % [Hz] win = hanning(ceil(10*Fs));
Then we compute the Power Spectral Density using pwelch function.
First for the geophone located on the marble
[pxz_ty_m, f] = pwelch(z_ty(:, 1), win, [], gm.f, Fs); [pxz_of_m, ~] = pwelch(z_of(:, 1), win, [], gm.f, Fs); [pxe_ty_m, ~] = pwelch(e_ty(:, 1), win, [], gm.f, Fs); [pxe_of_m, ~] = pwelch(e_of(:, 1), win, [], gm.f, Fs);
And for the geophone located at the sample position.
[pxz_ty_s, ~] = pwelch(z_ty(:, 2), win, [], gm.f, Fs); [pxz_of_s, ~] = pwelch(z_of(:, 2), win, [], gm.f, Fs); [pxe_ty_s, ~] = pwelch(e_ty(:, 2), win, [], gm.f, Fs); [pxe_of_s, ~] = pwelch(e_of(:, 2), win, [], gm.f, Fs);
And we plot the ASD of the measured velocities:
- figure 6 compares the marble velocity in the east direction when scanning and when Ty is OFF
- figure 7 compares the sample velocity in the east direction when scanning and when Ty is OFF
- figure 8 shows the marble and sample velocities in the Z direction when scanning with the translation stage
Figure 6: Amplitude spectral density of the measured velocities corresponding to the geophone in the east direction located on the marble when the translation stage is OFF and when it is scanning at 1Hz
Figure 7: Amplitude spectral density of the measured velocities corresponding to the geophone in the east direction located at the sample location when the translation stage is OFF and when it is scanning at 1Hz
Figure 8: Amplitude spectral density of the measure velocity corresponding to the geophone in the vertical direction located on the granite and at the sample location when the translation stage is scanning at 1Hz
Figure 9: Amplitude spectral density of the measure velocity corresponding to the geophone in the vertical direction located on the granite and at the sample location when the translation stage is scanning at 1Hz
2.5 Relative Motion
And finally for the relative velocity between the sample and the marble.
[pxz_ty_r, f] = pwelch(z_ty(:, 2)-z_ty(:, 1), win, [], gm.f, Fs); [pxz_of_r, ~] = pwelch(z_of(:, 2)-z_of(:, 1), win, [], gm.f, Fs); [pxe_ty_r, ~] = pwelch(e_ty(:, 2)-e_ty(:, 1), win, [], gm.f, Fs); [pxe_of_r, ~] = pwelch(e_of(:, 2)-e_of(:, 1), win, [], gm.f, Fs);
Fig. 11 shows the relative velocity of the sample with respect to the granite in the X direction when the translation stage is OFF and when it is scanning at 1Hz
figure; hold on; plot(f, sqrt(pxz_of_r), 'DisplayName', 'Ty OFF - Relative - Z'); plot(f, sqrt(pxz_of_s), 'DisplayName', 'Ty 1Hz - Relative - Z'); plot(f, sqrt(pxz_of_m), 'DisplayName', 'Ty 1Hz - Relative - Z'); hold off; set(gca, 'xscale', 'log'); set(gca, 'yscale', 'log'); xlabel('Frequency [Hz]'); ylabel('ASD of the measured velocity $\left[\frac{m/s}{\sqrt{Hz}}\right]$') legend('Location', 'northwest'); xlim([0.1, 500]);
figure; hold on; plot(f, sqrt(pxz_of_r), 'DisplayName', 'Ty OFF - Relative - Z'); plot(f, sqrt(pxz_ty_r), 'DisplayName', 'Ty 1Hz - Relative - Z'); hold off; set(gca, 'xscale', 'log'); set(gca, 'yscale', 'log'); xlabel('Frequency [Hz]'); ylabel('ASD of the measured velocity $\left[\frac{m/s}{\sqrt{Hz}}\right]$') legend('Location', 'northwest'); xlim([0.1, 500]);
Figure 10: Amplitude spectral density of the measured relative velocity in the X direction
figure; hold on; plot(f, sqrt(pxe_of_r), 'DisplayName', 'Ty OFF - Relative - E'); plot(f, sqrt(pxe_ty_r), 'DisplayName', 'Ty 1Hz - Relative - E'); hold off; set(gca, 'xscale', 'log'); set(gca, 'yscale', 'log'); xlabel('Frequency [Hz]'); ylabel('ASD of the measured velocity $\left[\frac{m/s}{\sqrt{Hz}}\right]$') legend('Location', 'northwest'); xlim([0.1, 500]);
Figure 11: Amplitude spectral density of the measured relative velocity in the X direction
2.6 Save
The Power Spectral Density of the relative velocity is saved for further analysis.
save('mat/pxz_ty_r.mat', 'f', 'pxz_ty_r', 'pxz_ty_s'); save('mat/pxe_ty_r.mat', 'f', 'pxe_ty_r', 'pxe_ty_s');
2.7 Position of the translation stage and Current
The position of the translation and current flowing in its actuator are measured using the elmo software and saved as an csv file.
2.7.1 Data pre-processing
Let’s look at at the start of the csv file.
sed -n 1,30p mat/sin_elmo.csv | nl -ba -
1 Elmo txt chart ver 2.0 2 3 [File Properties] 4 Creation Time,2019-05-13 05:11:45 5 Last Updated,2019-05-13 05:11:45 6 Resolution,0.001 7 Sampling Time,5E-05 8 Recording Time,5.461 9 10 [Chart Properties] 11 No.,Name,X Linear,X No. 12 1,Chart #1,True,0 13 2,Chart #2,True,0 14 15 [Chart Data] 16 Display No.,X No.,Y No.,X Unit,Y Unit,Color,Style,Width 17 1,1,2,sec,N/A,ff0000ff,Solid,TwoPoint 18 2,1,3,sec,N/A,ff0000ff,Solid,TwoPoint 19 2,1,4,sec,N/A,ff007f00,Solid,TwoPoint 20 21 [Signal Names] 22 1,Time (sec) 23 2,Position [cnt] 24 3,Current Command [A] 25 4,Total Current Command [A] 26 27 [Signals Data Group 1] 28 1,2,3,4, 29 0,1110769,-0.320872406596209,-0.320872406596209, 30 0.001,1108743,-0.319658428261391,-0.319658428261391,
The real data starts at line 29.
We then load this cvs file starting at line 29.
data = csvread("mat/sin_elmo.csv", 29, 0);
2.7.2 Time domain data
We plot the position of the translation stage measured by the encoders. There is 200000 encoder count for each mm, we then divide by 200000 to obtain mm. The result is shown on figure 12.
figure; hold on; plot(data(:, 1), data(:, 2)/200000); hold off; xlim([0, 5]); xlabel('Time [s]'); ylabel('Position [mm]');
Figure 12: Y position of the translation stage measured by the encoders
Figure 13: Y position of the translation stage measured by the encoders - Zoom
We also plot the current as function of the time on figure 14.
figure; hold on; plot(data(:, 1), data(:, 3)); hold off; xlim([0, 5]); ylim([-10, 10]); xlabel('Time [s]'); ylabel('Current [A]');
Figure 14: Current going through the actuator of the translation stage
Figure 15: Current going through the actuator of the translation stage - Zoom
2.8 Conclusion
- The acquisition is done using the Speedgoat as well as using ELMO. The two acquisition are not synchronize
- The value of the translation stage encoder can also be read with the speedgoat, this could permit to synchronize the measurements