nass-micro-station-measurem.../modal-analysis/matlab/modal_frf_coh.m

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%% Clear Workspace and Close figures
clear; close all; clc;
%% Intialize Laplace variable
s = zpk('s');
% We then import that on =matlab=, and sort them.
acc_pos = readtable('mat/acc_pos.txt', 'ReadVariableNames', false);
acc_pos = table2array(acc_pos(:, 1:4));
[~, i] = sort(acc_pos(:, 1));
acc_pos = acc_pos(i, 2:4);
% Windowing
% Windowing is used on the force and response signals.
% A boxcar window (figure [[fig:windowing_force_signal]]) is used for the force signal as once the impact on the structure is done, the measured signal is meaningless.
% The parameters are:
% - *Start*: $3\%$
% - *Stop*: $7\%$
figure;
plot(100*[0, 0.03, 0.03, 0.07, 0.07, 1], [0, 0, 1, 1, 0, 0]);
xlabel('Time [%]'); ylabel('Amplitude');
xlim([0, 100]); ylim([0, 1]);
% #+NAME: fig:windowing_force_signal
% #+CAPTION: Window used for the force signal
% [[file:figs/windowing_force_signal.png]]
% An exponential window (figure [[fig:windowing_response_signal]]) is used for the response signal as we are measuring transient signals and most of the information is located at the beginning of the signal.
% The parameters are:
% - FlatTop:
% - *Start*: $3\%$
% - *Stop*: $2.96\%$
% - Decreasing point:
% - *X*: $60.4\%$
% - *Y*: $14.7\%$
x0 = 0.296;
xd = 0.604;
yd = 0.147;
alpha = log(yd)/(x0 - xd);
t = x0:0.01:1.01;
y = exp(-alpha*(t-x0));
figure;
plot(100*[0, 0.03, 0.03, x0, t], [0, 0, 1, 1, y]);
xlabel('Time [%]'); ylabel('Amplitude');
xlim([0, 100]); ylim([0, 1]);
% Force and Response signals
% Let's load some obtained data to look at the force and response signals.
meas1_raw = load('mat/meas_raw_1.mat');
% Raw Force Data
% The force input for the first measurement is shown on figure [[fig:raw_data_force]]. We can see 10 impacts, one zoom on one impact is shown on figure [[fig:raw_data_force_zoom]].
% The Fourier transform of the force is shown on figure [[fig:fourier_transfor_force_impact]]. This has been obtained without any windowing.
time = linspace(0, meas1_raw.Track1_X_Resolution*length(meas1_raw.Track1), length(meas1_raw.Track1));
figure;
plot(time, meas1_raw.Track1);
xlabel('Time [s]');
ylabel('Force [N]');
% #+NAME: fig:raw_data_force
% #+CAPTION: Raw Force Data from Hammer Blow
% [[file:figs/raw_data_force.png]]
figure;
plot(time, meas1_raw.Track1);
xlabel('Time [s]');
ylabel('Force [N]');
xlim([22.1, 22.3]);
% #+NAME: fig:raw_data_force_zoom
% #+CAPTION: Raw Force Data from Hammer Blow - Zoom
% [[file:figs/raw_data_force_zoom.png]]
Fs = 1/meas1_raw.Track1_X_Resolution; % Sampling Frequency [Hz]
impacts = [5.9, 11.2, 16.6, 22.2, 27.3, 32.7, 38.1, 43.8, 50.4]; % Time just before the impact occurs [s]
L = 8194;
f = Fs*(0:(L/2))/L; % Frequency vector [Hz]
F_fft = zeros((8193+1)/2+1, length(impacts));
for i = 1:length(impacts)
t0 = impacts(i);
[~, i_start] = min(abs(time-t0));
i_end = i_start + 8193;
Y = fft(meas1_raw.Track1(i_start:i_end));
P2 = abs(Y/L);
P1 = P2(1:L/2+1);
P1(2:end-1) = 2*P1(2:end-1);
F_fft(:, i) = P1;
end
figure;
hold on;
for i = 1:length(impacts)
plot(f, F_fft(:, i), '-k');
end
hold off;
xlim([0, 200]);
xlabel('Frequency [Hz]'); ylabel('Force [N]');
% Raw Response Data
% The response signal for the first measurement is shown on figure [[fig:raw_data_acceleration]]. One zoom on one response is shown on figure [[fig:raw_data_acceleration_zoom]].
% The Fourier transform of the response signals is shown on figure [[fig:fourier_transform_response_signals]]. This has been obtained without any windowing.
figure;
plot(time, meas1_raw.Track2);
xlabel('Time [s]');
ylabel('Acceleration [m/s2]');
% #+NAME: fig:raw_data_acceleration
% #+CAPTION: Raw Acceleration Data from Accelerometer
% [[file:figs/raw_data_acceleration.png]]
figure;
plot(time, meas1_raw.Track2);
xlabel('Time [s]');
ylabel('Acceleration [m/s2]');
xlim([22.1, 22.5]);
% #+NAME: fig:raw_data_acceleration_zoom
% #+CAPTION: Raw Acceleration Data from Accelerometer - Zoom
% [[file:figs/raw_data_acceleration_zoom.png]]
X_fft = zeros((8193+1)/2+1, length(impacts));
for i = 1:length(impacts)
t0 = impacts(i);
[~, i_start] = min(abs(time-t0));
i_end = i_start + 8193;
Y = fft(meas1_raw.Track2(i_start:i_end));
P2 = abs(Y/L);
P1 = P2(1:L/2+1);
P1(2:end-1) = 2*P1(2:end-1);
X_fft(:, i) = P1;
end
figure;
hold on;
for i = 1:length(impacts)
plot(f, X_fft(:, i), '-k');
end
hold off;
xlim([0, 200]);
set(gca, 'Yscale', 'log');
xlabel('Frequency [Hz]'); ylabel('Acceleration [$m/s^2$]');
% Computation of one Frequency Response Function
% Now that we have obtained the Fourier transform of both the force input and the response signal, we can compute the Frequency Response Function from the force to the acceleration.
% We then compare the result obtained with the FRF computed by the modal software (figure [[fig:frf_comparison_software]]).
% The slight difference can probably be explained by the use of windows.
% In the following analysis, FRF computed from the software will be used.
meas1 = load('mat/meas_frf_coh_1.mat');
figure;
hold on;
for i = 1:length(impacts)
plot(f, X_fft(:, i)./F_fft(:, i), '-k');
end
plot(meas1.FFT1_AvSpc_2_RMS_X_Val, meas1.FFT1_AvSpc_2_RMS_Y_Val)
hold off;
xlim([0, 200]);
set(gca, 'Yscale', 'log');
xlabel('Frequency [Hz]'); ylabel('Acceleration/Force [$m/s^2/N$]');
% Frequency Response Functions and Coherence Results
% Let's see one computed Frequency Response Function and one coherence in order to attest the quality of the measurement.
% First, we load the data.
meas1 = load('mat/meas_frf_coh_1.mat');
% And we plot on figure [[fig:frf_result_example]] the frequency response function from the force applied in the $X$ direction at the location of the accelerometer number 11 to the acceleration in the $X$ direction as measured by the first accelerometer located on the top platform of the hexapod.
% The coherence associated is shown on figure [[fig:frf_result_example]].
figure;
ax1 = subplot(2, 1, 1);
plot(meas1.FFT1_AvSpc_2_RMS_X_Val, meas1.FFT1_AvXSpc_2_1_RMS_Y_Mod);
set(gca, 'Yscale', 'log');
set(gca, 'XTickLabel',[]);
ylabel('Magnitude');
ax2 = subplot(2, 1, 2);
plot(meas1.FFT1_AvSpc_2_RMS_X_Val, meas1.FFT1_AvXSpc_2_1_RMS_Y_Phas);
ylim([-180, 180]);
yticks([-180, -90, 0, 90, 180]);
xlabel('Frequency [Hz]'); ylabel('Phase [deg]');
linkaxes([ax1,ax2],'x');
% #+NAME: fig:frf_result_example
% #+CAPTION: Example of one measured FRF
% [[file:figs/frf_result_example.png]]
figure;
plot(meas1.FFT1_AvSpc_2_RMS_X_Val, meas1.FFT1_Coh_2_1_RMS_Y_Val);
xlabel('Frequency [Hz]');
ylabel('Coherence');
% Generation of a FRF matrix and a Coherence matrix from the measurements
% We want here to combine all the Frequency Response Functions measured into one big array called the *Frequency Response Matrix*.
% The frequency response matrix is an $n \times p \times q$:
% - $n$ is the number of measurements: $23 \times 3$ (23 accelerometers measuring 3 directions each)
% - $p$ is the number of excitation inputs: $3$
% - $q$ is the number of frequency points $\omega_i$
% Thus, the FRF matrix is an $69 \times 3 \times 801$ matrix.
% #+begin_important
% For each frequency point $\omega_i$, we obtain a 2D matrix:
% \begin{equation}
% \text{FRF}(\omega_i) = \begin{bmatrix}
% \frac{D_{1_x}}{F_x}(\omega_i) & \frac{D_{1_x}}{F_y}(\omega_i) & \frac{D_{1_x}}{F_z}(\omega_i) \\
% \frac{D_{1_y}}{F_x}(\omega_i) & \frac{D_{1_y}}{F_y}(\omega_i) & \frac{D_{1_y}}{F_z}(\omega_i) \\
% \frac{D_{1_z}}{F_x}(\omega_i) & \frac{D_{1_z}}{F_y}(\omega_i) & \frac{D_{1_z}}{F_z}(\omega_i) \\
% \frac{D_{2_x}}{F_x}(\omega_i) & \frac{D_{2_x}}{F_y}(\omega_i) & \frac{D_{2_x}}{F_z}(\omega_i) \\
% \vdots & \vdots & \vdots \\
% \frac{D_{23_z}}{F_x}(\omega_i) & \frac{D_{23_z}}{F_y}(\omega_i) & \frac{D_{23_z}}{F_z}(\omega_i) \\
% \end{bmatrix}
% \end{equation}
% #+end_important
% We generate such FRF matrix from the measurements using the following script.
n_meas = 24;
n_acc = 23;
dirs = 'XYZ';
% Number of Accelerometer * DOF for each acccelerometer / Number of excitation / frequency points
FRFs = zeros(3*n_acc, 3, 801);
COHs = zeros(3*n_acc, 3, 801);
% Loop through measurements
for i = 1:n_meas
% Load the measurement file
meas = load(sprintf('mat/meas_frf_coh_%i.mat', i));
% First: determine what is the exitation (direction and sign)
exc_dir = meas.FFT1_AvXSpc_2_1_RMS_RfName(end);
exc_sign = meas.FFT1_AvXSpc_2_1_RMS_RfName(end-1);
% Determine what is the correct excitation sign
exc_factor = str2num([exc_sign, '1']);
if exc_dir ~= 'Z'
exc_factor = exc_factor*(-1);
end
% Then: loop through the nine measurements and store them at the correct location
for j = 2:10
% Determine what is the accelerometer and direction
[indices_acc_i] = strfind(meas.(sprintf('FFT1_H1_%i_1_RpName', j)), '.');
acc_i = str2num(meas.(sprintf('FFT1_H1_%i_1_RpName', j))(indices_acc_i(1)+1:indices_acc_i(2)-1));
meas_dir = meas.(sprintf('FFT1_H1_%i_1_RpName', j))(end);
meas_sign = meas.(sprintf('FFT1_H1_%i_1_RpName', j))(end-1);
% Determine what is the correct measurement sign
meas_factor = str2num([meas_sign, '1']);
if meas_dir ~= 'Z'
meas_factor = meas_factor*(-1);
end
FRFs(find(dirs==meas_dir)+3*(acc_i-1), find(dirs==exc_dir), :) = exc_factor*meas_factor*meas.(sprintf('FFT1_H1_%i_1_Y_ReIm', j));
COHs(find(dirs==meas_dir)+3*(acc_i-1), find(dirs==exc_dir), :) = meas.(sprintf('FFT1_Coh_%i_1_RMS_Y_Val', j));
end
end
freqs = meas.FFT1_Coh_10_1_RMS_X_Val;
% And we save the obtained FRF matrix and Coherence matrix in a =.mat= file.
save('./mat/frf_coh_matrices.mat', 'FRFs', 'COHs', 'freqs');
% Plot showing the coherence of all the measurements
% Now that we have defined a Coherence matrix, we can plot each of its elements to have an idea of the overall coherence and thus, quality of the measurement.
% The result is shown on figure [[fig:all_coherence]].
n_acc = 23;
figure;
hold on;
for i = 1:3*n_acc
plot(freqs, squeeze(COHs(i, 1, :)), 'color', [0, 0, 0, 0.2]);
end
hold off;
xlabel('Frequency [Hz]');
ylabel('Coherence [\%]');
% Solid Bodies considered for further analysis
% We consider the following solid bodies for further analysis:
% - Bottom Granite
% - Top Granite
% - Translation Stage
% - Tilt Stage
% - Spindle
% - Hexapod
% We create a =matlab= structure =solids= that contains the accelerometers ID connected to each solid bodies (as shown on figure [[fig:nass-modal-test]]).
solids = {};
solids.gbot = [17, 18, 19, 20];
solids.gtop = [13, 14, 15, 16];
solids.ty = [9, 10, 11, 12];
solids.ry = [5, 6, 7, 8];
solids.rz = [21, 22, 23];
solids.hexa = [1, 2, 3, 4];
solid_names = fields(solids);
% Finally, we save that into a =.mat= file.
save('mat/geometry.mat', 'solids', 'solid_names', 'acc_pos');
% #+name: fig:aligned_accelerometers
% #+caption: Aligned measurement of the motion of a solid body
% #+RESULTS:
% [[file:figs/aligned_accelerometers.png]]
% The motion of the rigid body of figure [[fig:aligned_accelerometers]] is defined by the velocity $\vec{v}$ and rotation $\vec{\Omega}$ with respect to the reference frame $\{O\}$.
% The motions at points $1$ and $2$ are:
% \begin{align*}
% v_1 &= v + \Omega \times p_1 \\
% v_2 &= v + \Omega \times p_2
% \end{align*}
% Taking only the $x$ direction:
% \begin{align*}
% v_{x1} &= v + \Omega_y p_{z1} - \Omega_z p_{y1} \\
% v_{x2} &= v + \Omega_y p_{z2} - \Omega_z p_{y2}
% \end{align*}
% However, we have $p_{1y} = p_{2y}$ and $p_{1z} = p_{2z}$ because of the co-linearity of the two sensors in the $x$ direction, and thus we obtain
% \begin{equation}
% v_{x1} = v_{x2}
% \end{equation}
% #+begin_important
% Two sensors that are measuring the motion of a rigid body in the direction of the line linking the two sensors should measure the same quantity.
% #+end_important
% We can verify that the rigid body assumption is correct by comparing the measurement of the sensors.
% From the table [[tab:position_accelerometers]], we can guess which sensors will give the same results in the X and Y directions.
% Comparison of such measurements in the X direction is shown on figure [[fig:compare_acc_x_dir]] and in the Y direction on figure [[fig:compare_acc_y_dir]].
meas_dir = 1;
exc_dir = 1;
acc_i = [1 , 4 ;
2 , 3 ;
5 , 8 ;
6 , 7 ;
9 , 12;
10, 11;
14, 15;
18, 19;
21, 23];
figure;
for i = 1:size(acc_i, 1)
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subplot(3, 3, i);
hold on;
plot(freqs, abs(squeeze(FRFs(meas_dir+3*(acc_i(i, 1)-1), exc_dir, :))))
plot(freqs, abs(squeeze(FRFs(meas_dir+3*(acc_i(i, 2)-1), exc_dir, :))))
hold off;
set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');
if i > 6
xlabel('Frequency [Hz]');
else
set(gca, 'XTickLabel',[]);
end
if rem(i, 3) == 1
ylabel('Amplitude');
end
xlim([1, 200]);
title(sprintf('Acc %i and %i - X', acc_i(i, 1), acc_i(i, 2)));
end
% #+NAME: fig:compare_acc_x_dir
% #+CAPTION: Compare accelerometers align in the X direction
% [[file:figs/compare_acc_x_dir.png]]
meas_dir = 2;
exc_dir = 1;
acc_i = [1, 2;
5, 6;
7, 8;
9, 10;
11, 12;
13, 14;
15, 16;
17, 18;
19, 20];
figure;
for i = 1:size(acc_i, 1)
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subplot(3, 3, i);
hold on;
plot(freqs, abs(squeeze(FRFs(meas_dir+3*(acc_i(i, 1)-1), exc_dir, :))))
plot(freqs, abs(squeeze(FRFs(meas_dir+3*(acc_i(i, 2)-1), exc_dir, :))))
hold off;
set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');
if i > 6
xlabel('Frequency [Hz]');
else
set(gca, 'XTickLabel',[]);
end
if rem(i, 3) == 1
ylabel('Amplitude');
end
xlim([1, 200]);
title(sprintf('Acc %i and %i - Y', acc_i(i, 1), acc_i(i, 2)));
end