phd-nass-uniaxial-model/matlab/uniaxial_1_micro_station_model.m

%% Clear Workspace and Close figures
clear; close all; clc;

%% Intialize Laplace variable
s = zpk('s');

%% Path for functions, data and scripts
addpath('./mat/'); % Path for data

%% Colors for the figures
colors = colororder;

%% Uniaxial Simscape model name
mdl = 'nass_uniaxial_model';

%% Frequency Vector [Hz]
freqs = logspace(0, 3, 1000);


% #+name: fig:micro_station_uniaxial_model
% #+caption: Schematic of the Micro-Station measurement setup and uniaxial model.
% #+begin_figure
% #+attr_latex: :caption \subcaption{\label{fig:uniaxial_ustation_meas_dynamics_schematic}Measurement setup - Schematic}
% #+attr_latex: :options {0.69\textwidth}
% #+begin_subfigure
% #+attr_latex: :scale 1
% [[file:figs/uniaxial_ustation_meas_dynamics_schematic.png]]
% #+end_subfigure
% #+attr_latex: :caption \subcaption{\label{fig:uniaxial_model_micro_station}Uniaxial model of the micro-station}
% #+attr_latex: :options {0.29\textwidth}
% #+begin_subfigure
% #+attr_latex: :scale 1
% [[file:figs/uniaxial_model_micro_station.png]]
% #+end_subfigure
% #+end_figure

% Due to the bad coherence at low frequency, the frequency response functions will only be shown between 20 and 200Hz (solid lines in Figure ref:fig:uniaxial_comp_frf_meas_model).


%% Load measured FRF
load('meas_microstation_frf.mat');


% Masses are estimated from the CAD.

%% Parameters - Mass
mh = 15;   % Micro Hexapod [kg]
mt = 1200; % Ty + Ry + Rz [kg]
mg = 2500; % Granite [kg]


% And stiffnesses from the data-sheet of stage manufacturers.

%% Parameters - Stiffnesses
kh = 6.11e+07; % [N/m]
kt = 5.19e+08; % [N/m]
kg = 9.50e+08; % [N/m]


% The damping coefficients are tuned to match the identified damping from the measurements.

%% Parameters - damping
ch = 2*0.05*sqrt(kh*mh); % [N/(m/s)]
ct = 2*0.05*sqrt(kt*mt); % [N/(m/s)]
cg = 2*0.08*sqrt(kg*mg); % [N/(m/s)]

%% Save model parameters
save('./mat/uniaxial_micro_station_parameters.mat', 'mh', 'mt', 'mg', 'ch', 'ct', 'cg', 'kh', 'kt', 'kg')

%% Disable the Nano-Hexpod for now
model_config = struct();
model_config.nhexa = "none";
model_config.controller = "open_loop";

%% Identify the transfer function from u to taum
clear io; io_i = 1;
io(io_i) = linio([mdl, '/micro_station/Fg'], 1, 'openinput');  io_i = io_i + 1; % Hammer on Granite
io(io_i) = linio([mdl, '/micro_station/Fh'], 1, 'openinput');  io_i = io_i + 1; % Hammer on Hexapod
io(io_i) = linio([mdl, '/micro_station/xg'], 1, 'openoutput'); io_i = io_i + 1; % Absolute motion of Granite
io(io_i) = linio([mdl, '/micro_station/xh'], 1, 'openoutput'); io_i = io_i + 1; % Absolute motion of Hexapod

%% Perform the model extraction
G_id = linearize(mdl, io, 0.0);
G_id.InputName = {'Fg', 'Fh'};
G_id.OutputName = {'Dg', 'Dh'};

% Comparison of the model and measurements
% The comparison between the measurements and the model is shown in Figure ref:fig:uniaxial_comp_frf_meas_model.

% Only three modes are modelled with frequencies at 70Hz, 140Hz and 320Hz.

% As the model is simplistic, the goal is not to match exactly the measurement but to have a first approximation.
% More accurate models will be used later on.


%% Comparison of the measured FRF and identified ones from the uni-axial model
figure;
tiledlayout(3, 1, 'TileSpacing', 'Compact', 'Padding', 'None');

ax1 = nexttile([2,1]);
hold on;
plot(f(f>20), abs(frf_Fhz_to_Dhz(f>20)), '-', 'color', colors(1,:), 'DisplayName', '$D_{h,z}/F_{h,z}$');
plot(f(f>20), abs(frf_Fgz_to_Dhz(f>20)), '-', 'color', colors(2,:), 'DisplayName', '$D_{h,z}/F_{g,z}$');
plot(f(f>20), abs(frf_Fgz_to_Dgz(f>20)), '-', 'color', colors(3,:), 'DisplayName', '$D_{g,z}/F_{g,z}$');
plot(freqs, abs(squeeze(freqresp(G_id('Dh', 'Fh'), freqs, 'Hz'))), '--', 'color', colors(1,:), 'DisplayName', '$D_{h,z}/F_{h,z}$ (model)');
plot(freqs, abs(squeeze(freqresp(G_id('Dh', 'Fg'), freqs, 'Hz'))), '--', 'color', colors(2,:), 'DisplayName', '$D_{h,z}/F_{g,z}$ (model)');
plot(freqs, abs(squeeze(freqresp(G_id('Dg', 'Fg'), freqs, 'Hz'))), '--', 'color', colors(3,:), 'DisplayName', '$D_{g,z}/F_{g,z}$ (model)');
hold off;
set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');
ylabel('Amplitude [m/N]'); set(gca, 'XTickLabel',[]);
ylim([1e-10, 2e-7]);
legend('location', 'northwest', 'FontSize', 8, 'NumColumns', 2);

ax2 = nexttile;
hold on;
plot(freqs, 180/pi*unwrap(angle(squeeze(freqresp(G_id('Dh', 'Fh'), freqs, 'Hz')))), '--', 'color', colors(1,:));
plot(freqs, 180/pi*unwrap(angle(squeeze(freqresp(G_id('Dh', 'Fg'), freqs, 'Hz')))), '--', 'color', colors(2,:));
plot(freqs, 180/pi*unwrap(angle(squeeze(freqresp(G_id('Dg', 'Fg'), freqs, 'Hz')))), '--', 'color', colors(3,:));
plot(f(f>20), 180/pi*unwrap(angle(frf_Fhx_to_Dhx(f>20))), '-', 'color', colors(1,:));
plot(f(f>30), 180/pi*unwrap(angle(frf_Fgx_to_Dhx(f>30))), '-', 'color', colors(2,:));
plot(f(f>20), 180/pi*unwrap(angle(frf_Fgx_to_Dgx(f>20))), '-', 'color', colors(3,:));
hold off;
set(gca, 'XScale', 'log'); set(gca, 'YScale', 'lin');
xlabel('Frequency [Hz]'); ylabel('Phase [deg]');
hold off;
yticks(-360:90:360);
ylim([-360, 90]);

linkaxes([ax1,ax2],'x');
xlim([1, 500]);
Initial commit 2023-02-17 11:28:06 +01:00			`%% Clear Workspace and Close figures`
			`clear; close all; clc;`

			`%% Intialize Laplace variable`
			`s = zpk('s');`

			`%% Path for functions, data and scripts`
			`addpath('./mat/'); % Path for data`

			`%% Colors for the figures`
			`colors = colororder;`

			`%% Uniaxial Simscape model name`
			`mdl = 'nass_uniaxial_model';`

			`%% Frequency Vector [Hz]`
			`freqs = logspace(0, 3, 1000);`



Add two sections (payload dynamics and limited support compliance) 2023-06-30 20:01:22 +02:00			`% #+name: fig:micro_station_uniaxial_model`
			`% #+caption: Schematic of the Micro-Station measurement setup and uniaxial model.`
			`% #+begin_figure`
Update missing "." in path 2024-03-26 16:29:41 +01:00			`% #+attr_latex: :caption \subcaption{\label{fig:uniaxial_ustation_meas_dynamics_schematic}Measurement setup - Schematic}`
Add two sections (payload dynamics and limited support compliance) 2023-06-30 20:01:22 +02:00			`% #+attr_latex: :options {0.69\textwidth}`
			`% #+begin_subfigure`
			`% #+attr_latex: :scale 1`
Update missing "." in path 2024-03-26 16:29:41 +01:00			`% [[file:figs/uniaxial_ustation_meas_dynamics_schematic.png]]`
Add two sections (payload dynamics and limited support compliance) 2023-06-30 20:01:22 +02:00			`% #+end_subfigure`
			`% #+attr_latex: :caption \subcaption{\label{fig:uniaxial_model_micro_station}Uniaxial model of the micro-station}`
			`% #+attr_latex: :options {0.29\textwidth}`
			`% #+begin_subfigure`
			`% #+attr_latex: :scale 1`
			`% [[file:figs/uniaxial_model_micro_station.png]]`
			`% #+end_subfigure`
			`% #+end_figure`
Initial commit 2023-02-17 11:28:06 +01:00
Add two sections (payload dynamics and limited support compliance) 2023-06-30 20:01:22 +02:00			`% Due to the bad coherence at low frequency, the frequency response functions will only be shown between 20 and 200Hz (solid lines in Figure ref:fig:uniaxial_comp_frf_meas_model).`
Initial commit 2023-02-17 11:28:06 +01:00

			`%% Load measured FRF`
			`load('meas_microstation_frf.mat');`

Add two sections (payload dynamics and limited support compliance) 2023-06-30 20:01:22 +02:00
Initial commit 2023-02-17 11:28:06 +01:00
			`% Masses are estimated from the CAD.`

			`%% Parameters - Mass`
			`mh = 15; % Micro Hexapod [kg]`
			`mt = 1200; % Ty + Ry + Rz [kg]`
			`mg = 2500; % Granite [kg]`



			`% And stiffnesses from the data-sheet of stage manufacturers.`

			`%% Parameters - Stiffnesses`
			`kh = 6.11e+07; % [N/m]`
			`kt = 5.19e+08; % [N/m]`
			`kg = 9.50e+08; % [N/m]`



			`% The damping coefficients are tuned to match the identified damping from the measurements.`

			`%% Parameters - damping`
			`ch = 20.05sqrt(kh*mh); % [N/(m/s)]`
			`ct = 20.05sqrt(kt*mt); % [N/(m/s)]`
			`cg = 20.08sqrt(kg*mg); % [N/(m/s)]`

			`%% Save model parameters`
			`save('./mat/uniaxial_micro_station_parameters.mat', 'mh', 'mt', 'mg', 'ch', 'ct', 'cg', 'kh', 'kt', 'kg')`

			`%% Disable the Nano-Hexpod for now`
			`model_config = struct();`
			`model_config.nhexa = "none";`
			`model_config.controller = "open_loop";`

			`%% Identify the transfer function from u to taum`
			`clear io; io_i = 1;`
			`io(io_i) = linio([mdl, '/micro_station/Fg'], 1, 'openinput'); io_i = io_i + 1; % Hammer on Granite`
			`io(io_i) = linio([mdl, '/micro_station/Fh'], 1, 'openinput'); io_i = io_i + 1; % Hammer on Hexapod`
			`io(io_i) = linio([mdl, '/micro_station/xg'], 1, 'openoutput'); io_i = io_i + 1; % Absolute motion of Granite`
			`io(io_i) = linio([mdl, '/micro_station/xh'], 1, 'openoutput'); io_i = io_i + 1; % Absolute motion of Hexapod`

			`%% Perform the model extraction`
			`G_id = linearize(mdl, io, 0.0);`
			`G_id.InputName = {'Fg', 'Fh'};`
			`G_id.OutputName = {'Dg', 'Dh'};`

			`% Comparison of the model and measurements`
Add two sections (payload dynamics and limited support compliance) 2023-06-30 20:01:22 +02:00			`% The comparison between the measurements and the model is shown in Figure ref:fig:uniaxial_comp_frf_meas_model.`

			`% Only three modes are modelled with frequencies at 70Hz, 140Hz and 320Hz.`
Initial commit 2023-02-17 11:28:06 +01:00
			`% As the model is simplistic, the goal is not to match exactly the measurement but to have a first approximation.`
			`% More accurate models will be used later on.`


			`%% Comparison of the measured FRF and identified ones from the uni-axial model`
			`figure;`
			`tiledlayout(3, 1, 'TileSpacing', 'Compact', 'Padding', 'None');`

			`ax1 = nexttile([2,1]);`
			`hold on;`
			`plot(f(f>20), abs(frf_Fhz_to_Dhz(f>20)), '-', 'color', colors(1,:), 'DisplayName', '$D_{h,z}/F_{h,z}$');`
			`plot(f(f>20), abs(frf_Fgz_to_Dhz(f>20)), '-', 'color', colors(2,:), 'DisplayName', '$D_{h,z}/F_{g,z}$');`
			`plot(f(f>20), abs(frf_Fgz_to_Dgz(f>20)), '-', 'color', colors(3,:), 'DisplayName', '$D_{g,z}/F_{g,z}$');`
			`plot(freqs, abs(squeeze(freqresp(G_id('Dh', 'Fh'), freqs, 'Hz'))), '--', 'color', colors(1,:), 'DisplayName', '$D_{h,z}/F_{h,z}$ (model)');`
			`plot(freqs, abs(squeeze(freqresp(G_id('Dh', 'Fg'), freqs, 'Hz'))), '--', 'color', colors(2,:), 'DisplayName', '$D_{h,z}/F_{g,z}$ (model)');`
			`plot(freqs, abs(squeeze(freqresp(G_id('Dg', 'Fg'), freqs, 'Hz'))), '--', 'color', colors(3,:), 'DisplayName', '$D_{g,z}/F_{g,z}$ (model)');`
			`hold off;`
			`set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');`
			`ylabel('Amplitude [m/N]'); set(gca, 'XTickLabel',[]);`
			`ylim([1e-10, 2e-7]);`
			`legend('location', 'northwest', 'FontSize', 8, 'NumColumns', 2);`

			`ax2 = nexttile;`
			`hold on;`
			`plot(freqs, 180/pi*unwrap(angle(squeeze(freqresp(G_id('Dh', 'Fh'), freqs, 'Hz')))), '--', 'color', colors(1,:));`
			`plot(freqs, 180/pi*unwrap(angle(squeeze(freqresp(G_id('Dh', 'Fg'), freqs, 'Hz')))), '--', 'color', colors(2,:));`
			`plot(freqs, 180/pi*unwrap(angle(squeeze(freqresp(G_id('Dg', 'Fg'), freqs, 'Hz')))), '--', 'color', colors(3,:));`
			`plot(f(f>20), 180/pi*unwrap(angle(frf_Fhx_to_Dhx(f>20))), '-', 'color', colors(1,:));`
			`plot(f(f>30), 180/pi*unwrap(angle(frf_Fgx_to_Dhx(f>30))), '-', 'color', colors(2,:));`
			`plot(f(f>20), 180/pi*unwrap(angle(frf_Fgx_to_Dgx(f>20))), '-', 'color', colors(3,:));`
			`hold off;`
			`set(gca, 'XScale', 'log'); set(gca, 'YScale', 'lin');`
			`xlabel('Frequency [Hz]'); ylabel('Phase [deg]');`
			`hold off;`
			`yticks(-360:90:360);`
			`ylim([-360, 90]);`

			`linkaxes([ax1,ax2],'x');`
			`xlim([1, 500]);`