Remove badly tangled files

2020-02-25 18:31:33 +01:00 · 2020-02-25 18:31:33 +01:00 · f1dd11c3a4
commit f1dd11c3a4
parent e3e6043810
9 changed files with 2 additions and 1313 deletions
--- a/org/active_damping.org
+++ b/org/active_damping.org
@ -3383,7 +3383,7 @@ Window used for =pwelch= function.
 * Useful Functions
 ** prepareLinearizeIdentification
 :PROPERTIES:
-:header-args:matlab+: :tangle src/prepareLinearizeIdentification.m
+:header-args:matlab+: :tangle ../src/prepareLinearizeIdentification.m
 :header-args:matlab+: :comments none :mkdirp yes :eval no
 :END:
 <<sec:prepareLinearizeIdentification>>
@ -3455,7 +3455,7 @@ We do not need to log any signal.
 ** prepareTomographyExperiment
 :PROPERTIES:
-:header-args:matlab+: :tangle src/prepareTomographyExperiment.m
+:header-args:matlab+: :tangle ../src/prepareTomographyExperiment.m
 :header-args:matlab+: :comments none :mkdirp yes :eval no
 :END:
 <<sec:prepareTomographyExperiment>>
--- a/org/functions.org
+++ b/org/functions.org
@ -41,249 +41,6 @@
 #+PROPERTY: header-args:latex+ :output-dir figs
 :END:
 * TODO computePsdDispl
 :PROPERTIES:
 :header-args:matlab+: :tangle ../src/computePsdDispl.m
 :header-args:matlab+: :comments none :mkdirp yes :eval no
 :END:
 <<sec:computePsdDispl>>
 This Matlab function is accessible [[file:../src/computePsdDispl.m][here]].
 #+begin_src matlab
  function [psd_object] = computePsdDispl(sys_data, t_init, n_av)
      i_init = find(sys_data.time > t_init, 1);
      han_win = hanning(ceil(length(sys_data.Dx(i_init:end, :))/n_av));
      Fs = 1/sys_data.time(2);
      [pdx, f] = pwelch(sys_data.Dx(i_init:end, :), han_win, [], [], Fs);
      [pdy, ~] = pwelch(sys_data.Dy(i_init:end, :), han_win, [], [], Fs);
      [pdz, ~] = pwelch(sys_data.Dz(i_init:end, :), han_win, [], [], Fs);
      [prx, ~] = pwelch(sys_data.Rx(i_init:end, :), han_win, [], [], Fs);
      [pry, ~] = pwelch(sys_data.Ry(i_init:end, :), han_win, [], [], Fs);
      [prz, ~] = pwelch(sys_data.Rz(i_init:end, :), han_win, [], [], Fs);
      psd_object = struct(...
          'f',  f,   ...
          'dx', pdx, ...
          'dy', pdy, ...
          'dz', pdz, ...
          'rx', prx, ...
          'ry', pry, ...
          'rz', prz);
  end
 #+end_src
 * TODO computeSetpoint
 :PROPERTIES:
 :header-args:matlab+: :tangle ../src/computeSetpoint.m
 :header-args:matlab+: :comments none :mkdirp yes :eval no
 :END:
 <<sec:computeSetpoint>>
 This Matlab function is accessible [[file:../src/computeSetpoint.m][here]].
 #+begin_src matlab
  function setpoint = computeSetpoint(ty, ry, rz)
  %%
  setpoint = zeros(6, 1);
  %% Ty
  Ty = [1 0 0 0  ;
        0 1 0 ty ;
        0 0 1 0  ;
        0 0 0 1 ];
  % Tyinv = [1 0 0  0  ;
  %          0 1 0 -ty ;
  %          0 0 1  0  ;
  %          0 0 0  1 ];
  %% Ry
  Ry = [ cos(ry) 0 sin(ry) 0 ;
        0       1 0       0 ;
        -sin(ry) 0 cos(ry) 0 ;
        0        0 0       1 ];
  % TMry = Ty*Ry*Tyinv;
  %% Rz
  Rz = [cos(rz) -sin(rz) 0 0 ;
        sin(rz)  cos(rz) 0 0 ;
        0        0       1 0 ;
        0        0       0 1 ];
  % TMrz = Ty*TMry*Rz*TMry'*Tyinv;
  %% All stages
  % TM = TMrz*TMry*Ty;
  TM = Ty*Ry*Rz;
  [thetax, thetay, thetaz] = RM2angle(TM(1:3, 1:3));
  setpoint(1:3) = TM(1:3, 4);
  setpoint(4:6) = [thetax, thetay, thetaz];
  %% Custom Functions
  function [thetax, thetay, thetaz] = RM2angle(R)
      if abs(abs(R(3, 1)) - 1) > 1e-6 % R31 != 1 and R31 != -1
          thetay = -asin(R(3, 1));
          thetax = atan2(R(3, 2)/cos(thetay), R(3, 3)/cos(thetay));
          thetaz = atan2(R(2, 1)/cos(thetay), R(1, 1)/cos(thetay));
      else
          thetaz = 0;
          if abs(R(3, 1)+1) < 1e-6 % R31 = -1
              thetay = pi/2;
              thetax = thetaz + atan2(R(1, 2), R(1, 3));
          else
              thetay = -pi/2;
              thetax = -thetaz + atan2(-R(1, 2), -R(1, 3));
          end
      end
  end
  end
 #+end_src
 * TODO converErrorBasis
 :PROPERTIES:
 :header-args:matlab+: :tangle ../src/converErrorBasis.m
 :header-args:matlab+: :comments none :mkdirp yes :eval no
 :END:
 <<sec:converErrorBasis>>
 This Matlab function is accessible [[file:../src/converErrorBasis.m][here]].
 #+begin_src matlab
  function error_nass = convertErrorBasis(pos, setpoint, ty, ry, rz)
  % convertErrorBasis -
  %
  % Syntax: convertErrorBasis(p_error, ty, ry, rz)
  %
  % Inputs:
  %    - p_error - Position error of the sample w.r.t. the granite [m, rad]
  %    - ty - Measured translation of the Ty stage [m]
  %    - ry - Measured rotation of the Ry stage [rad]
  %    - rz - Measured rotation of the Rz stage [rad]
  %
  % Outputs:
  %    - P_nass - Position error of the sample w.r.t. the NASS base [m]
  %    - R_nass - Rotation error of the sample w.r.t. the NASS base [rad]
  %
  % Example:
  %
  %% If line vector => column vector
  if size(pos, 2) == 6
      pos = pos';
  end
  if size(setpoint, 2) == 6
      setpoint = setpoint';
  end
  %% Position of the sample in the frame fixed to the Granite
  P_granite = [pos(1:3); 1]; % Position [m]
  R_granite = [setpoint(1:3); 1]; % Reference [m]
  %% Transformation matrices of the stages
  % T-y
  TMty = [1 0 0 0  ;
          0 1 0 ty ;
          0 0 1 0  ;
          0 0 0 1 ];
  % R-y
  TMry = [ cos(ry) 0 sin(ry) 0 ;
          0       1 0       0 ;
          -sin(ry) 0 cos(ry) 0 ;
          0        0 0       1 ];
  % R-z
  TMrz = [cos(rz) -sin(rz) 0 0 ;
          sin(rz)  cos(rz) 0 0 ;
          0        0       1 0 ;
          0        0       0 1 ];
  %% Compute Point coordinates in the new reference fixed to the NASS base
  % P_nass = TMrz*TMry*TMty*P_granite;
  P_nass = TMrz\TMry\TMty\P_granite;
  R_nass = TMrz\TMry\TMty\R_granite;
  dx = R_nass(1)-P_nass(1);
  dy = R_nass(2)-P_nass(2);
  dz = R_nass(3)-P_nass(3);
  %% Compute new basis vectors linked to the NASS base
  % ux_nass = TMrz*TMry*TMty*[1; 0; 0; 0];
  % ux_nass = ux_nass(1:3);
  % uy_nass = TMrz*TMry*TMty*[0; 1; 0; 0];
  % uy_nass = uy_nass(1:3);
  % uz_nass = TMrz*TMry*TMty*[0; 0; 1; 0];
  % uz_nass = uz_nass(1:3);
  ux_nass = TMrz\TMry\TMty\[1; 0; 0; 0];
  ux_nass = ux_nass(1:3);
  uy_nass = TMrz\TMry\TMty\[0; 1; 0; 0];
  uy_nass = uy_nass(1:3);
  uz_nass = TMrz\TMry\TMty\[0; 0; 1; 0];
  uz_nass = uz_nass(1:3);
  %% Rotations error w.r.t. granite Frame
  % Rotations error w.r.t. granite Frame
  rx_nass = pos(4);
  ry_nass = pos(5);
  rz_nass = pos(6);
  % Rotation matrices of the Sample w.r.t. the Granite
  Mrx_error = [1 0              0 ;
              0 cos(-rx_nass) -sin(-rx_nass) ;
              0 sin(-rx_nass)  cos(-rx_nass)];
  Mry_error = [ cos(-ry_nass) 0 sin(-ry_nass) ;
                0             1 0 ;
              -sin(-ry_nass) 0 cos(-ry_nass)];
  Mrz_error = [cos(-rz_nass) -sin(-rz_nass) 0 ;
              sin(-rz_nass)  cos(-rz_nass) 0 ;
              0              0             1];
  % Rotation matrix of the Sample w.r.t. the Granite
  Mr_error = Mrz_error*Mry_error*Mrx_error;
  %% Use matrix to solve
  R = Mr_error/[ux_nass, uy_nass, uz_nass]; % Rotation matrix from NASS base to Sample
  [thetax, thetay, thetaz] = RM2angle(R);
  error_nass = [dx; dy; dz; thetax; thetay; thetaz];
  %% Custom Functions
  function [thetax, thetay, thetaz] = RM2angle(R)
      if abs(abs(R(3, 1)) - 1) > 1e-6 % R31 != 1 and R31 != -1
          thetay = -asin(R(3, 1));
          % thetaybis = pi-thetay;
          thetax = atan2(R(3, 2)/cos(thetay), R(3, 3)/cos(thetay));
          % thetaxbis = atan2(R(3, 2)/cos(thetaybis), R(3, 3)/cos(thetaybis));
          thetaz = atan2(R(2, 1)/cos(thetay), R(1, 1)/cos(thetay));
          % thetazbis = atan2(R(2, 1)/cos(thetaybis), R(1, 1)/cos(thetaybis));
      else
          thetaz = 0;
          if abs(R(3, 1)+1) < 1e-6 % R31 = -1
              thetay = pi/2;
              thetax = thetaz + atan2(R(1, 2), R(1, 3));
          else
              thetay = -pi/2;
              thetax = -thetaz + atan2(-R(1, 2), -R(1, 3));
          end
      end
  end
  end
 #+end_src
 * computeReferencePose
 :PROPERTIES:
 :header-args:matlab+: :tangle ../src/computeReferencePose.m
--- a/org/matlab/modal_frf_coh.m
+++ b/org/matlab/modal_frf_coh.m
@ -1,398 +0,0 @@
 %% Clear Workspace and Close figures
 clear; close all; clc;
 %% Intialize Laplace variable
 s = zpk('s');
 % Simscape Model
 % The simulink file for the identification is =sim_micro_station_id.slx=.
 open('identification/matlab/sim_micro_station_id.slx')
 % We load the configuration and we set a small =StopTime=.
 load('mat/conf_simulink.mat');
 set_param(conf_simulink, 'StopTime', '0.5');
 % We initialize all the stages.
 initializeGround();
 initializeGranite();
 initializeTy();
 initializeRy();
 initializeRz();
 initializeMicroHexapod();
 initializeAxisc();
 initializeMirror();
 initializeNanoHexapod('actuator', 'piezo');
 initializeSample('mass', 50);
 % Compute the transfer functions
 % We first define some parameters for the identification.
 %% Options for Linearized
 options = linearizeOptions;
 options.SampleTime = 0;
 %% Name of the Simulink File
 mdl = 'sim_micro_station_id';
 %% Micro-Hexapod
 % Input/Output definition
 io(1) = linio([mdl, '/Micro-Station/Fm_ext'],1,'openinput');
 io(2) = linio([mdl, '/Micro-Station/Fg_ext'],1,'openinput');
 io(3) = linio([mdl, '/Micro-Station/Dm_inertial'],1,'output');
 io(4) = linio([mdl, '/Micro-Station/Ty_inertial'],1,'output');
 io(5) = linio([mdl, '/Micro-Station/Ry_inertial'],1,'output');
 io(6) = linio([mdl, '/Micro-Station/Dg_inertial'],1,'output');
 % Run the linearization
 G_ms = linearize(mdl, io, 0);
 % Input/Output names
 G_ms.InputName  = {'Fmx', 'Fmy', 'Fmz',...
                   'Fgx', 'Fgy', 'Fgz'};
 G_ms.OutputName = {'Dmx', 'Dmy', 'Dmz', ...
                   'Tyx', 'Tyy', 'Tyz', ...
                   'Ryx', 'Ryy', 'Ryz', ...
                   'Dgx', 'Dgy', 'Dgz'};
 %% Save the obtained transfer functions
 save('./mat/id_micro_station.mat', 'G_ms');
 %% Clear Workspace and Close figures
 clear; close all; clc;
 %% Intialize Laplace variable
 s = zpk('s');
 % Simscape Model
 % The simulink file for the analysis is =sim_micro_station_modal_analysis.slx=.
 open('identification/matlab/sim_micro_station_modal_analysis.slx')
 % We load the configuration and we set a small =StopTime=.
 load('mat/conf_simulink.mat');
 set_param(conf_simulink, 'StopTime', '0.5');
 % We initialize all the stages.
 initializeGround();
 initializeGranite();
 initializeTy();
 initializeRy();
 initializeRz();
 initializeMicroHexapod();
 initializeAxisc();
 initializeMirror();
 initializeNanoHexapod('actuator', 'piezo');
 initializeSample('mass', 50);
 % Identification
 %% Options for Linearized
 options = linearizeOptions;
 options.SampleTime = 0;
 %% Name of the Simulink File
 mdl = 'sim_micro_station_modal_analysis';
 %% Micro-Hexapod
 % Input/Output definition
 io(1) = linio([mdl, '/Micro-Station/F_hammer'],1,'openinput');
 io(2) = linio([mdl, '/Micro-Station/acc9'],1,'output');
 io(3) = linio([mdl, '/Micro-Station/acc10'],1,'output');
 io(4) = linio([mdl, '/Micro-Station/acc11'],1,'output');
 io(5) = linio([mdl, '/Micro-Station/acc12'],1,'output');
 % Run the linearization
 G_ms = linearize(mdl, io, 0);
 % Input/Output names
 G_ms.InputName  = {'Fx', 'Fy', 'Fz'};
 G_ms.OutputName = {'x9', 'y9', 'z9', ...
                   'x10', 'y10', 'z10', ...
                   'x11', 'y11', 'z11', ...
                   'x12', 'y12', 'z12'};
 % Plot Results
 figure;
 hold on;
 plot(freqs, abs(squeeze(freqresp(G_ms('x9', 'Fx'), freqs, 'Hz'))));
 set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');
 ylabel('Amplitude [m/N]');
 hold off;
 % Compare with measurements
 load('../meas/modal-analysis/mat/frf_coh_matrices.mat', 'FRFs', 'COHs', 'freqs');
 dirs = {'x', 'y', 'z'};
 n_acc = 9;
 n_dir = 1; % x, y, z
 n_exc = 1; % x, y, z
 figure;
 hold on;
 plot(freqs, abs(squeeze(FRFs(3*(n_acc-1) + n_dir, n_exc, :)))./((2*pi*freqs).^2)');
 plot(freqs, abs(squeeze(freqresp(G_ms([dirs{n_dir}, num2str(n_acc)], ['F', dirs{n_dir}]), freqs, 'Hz'))));
 set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');
 ylabel('Amplitude [m/N]');
 hold off;
 %% Clear Workspace and Close figures
 clear; close all; clc;
 %% Intialize Laplace variable
 s = zpk('s');
 % Prepare the Simulation
 open('nass_model.slx')
 % We load the configuration.
 load('mat/conf_simulink.mat');
 % We set a small =StopTime=.
 set_param(conf_simulink, 'StopTime', '0.5');
 % We initialize all the stages.
 initializeGround(      'type', 'rigid');
 initializeGranite(     'type', 'modal-analysis');
 initializeTy(          'type', 'modal-analysis');
 initializeRy(          'type', 'modal-analysis');
 initializeRz(          'type', 'modal-analysis');
 initializeMicroHexapod('type', 'modal-analysis');
 initializeAxisc(       'type', 'flexible');
 initializeMirror(      'type', 'none');
 initializeNanoHexapod( 'type', 'none');
 initializeSample(      'type', 'none');
 initializeController(  'type', 'open-loop');
 initializeLoggingConfiguration('log', 'none');
 initializeReferences();
 initializeDisturbances('enable', false);
 % Estimate the position of the CoM of each solid and compare with the one took for the Measurement Analysis
 % Thanks to the [[https://fr.mathworks.com/help/physmod/sm/ref/inertiasensor.html][Inertia Sensor]] simscape block, it is possible to estimate the position of the Center of Mass of a solid body with respect to a defined frame.
 sim('nass_model')
 % Create a frame at the CoM of each solid body
 % Now we use one =inertiasensor= block connected on each solid body that measured the center of mass of this solid with respect to the same connected frame.
 % We do that in order to position an accelerometer on the Simscape model at this particular point.
 open('identification/matlab/sim_micro_station_com_estimation.slx')
 sim('sim_micro_station_com_estimation')
 % #+RESULTS:
 % |        | granite bot | granite top |    ty |     ry |    rz |  hexa |
 % |--------+-------------+-------------+-------+--------+-------+-------|
 % | X [mm] |         0.0 |        51.7 |   0.9 |   -0.1 |   0.0 |  -0.0 |
 % | Y [mm] |         0.0 |       753.2 |   0.7 |    5.2 |  -0.0 |   0.1 |
 % | Z [mm] |      -250.0 |        22.9 | -17.1 | -146.5 | -23.2 | -47.1 |
 % We now same this for further use:
 granite_bot_com = granite_bot_com.Data(end, :)';
 granite_top_com = granite_top_com.Data(end, :)';
 ty_com = ty_com.Data(end, :)';
 ry_com = ry_com.Data(end, :)';
 rz_com = rz_com.Data(end, :)';
 hexa_com = hexa_com.Data(end, :)';
 save('mat/solids_com.mat', 'granite_bot_com', 'granite_top_com', 'ty_com', 'ry_com', 'rz_com', 'hexa_com');
 % Identification of the dynamics of the Simscape Model
 % We now use a new Simscape Model where 6DoF inertial sensors are located at the Center of Mass of each solid body.
 % load('mat/solids_com.mat', 'granite_bot_com', 'granite_top_com', 'ty_com', 'ry_com', 'rz_com', 'hexa_com');
 open('nass_model.slx')
 % We use the =linearize= function in order to estimate the dynamics from forces applied on the Translation stage at the same position used for the real modal analysis to the inertial sensors.
 %% Options for Linearized
 options = linearizeOptions;
 options.SampleTime = 0;
 %% Name of the Simulink File
 mdl = 'nass_model';
 %% Input/Output definition
 clear io; io_i = 1;
 io(io_i) = linio([mdl, '/Micro-Station/Translation Stage/Modal Analysis/F_hammer'],          1, 'openinput');  io_i = io_i + 1;
 io(io_i) = linio([mdl, '/Micro-Station/Granite/Modal Analysis/accelerometer'],               1, 'openoutput'); io_i = io_i + 1;
 io(io_i) = linio([mdl, '/Micro-Station/Translation Stage/Modal Analysis/accelerometer'],     1, 'openoutput'); io_i = io_i + 1;
 io(io_i) = linio([mdl, '/Micro-Station/Tilt Stage/Modal Analysis/accelerometer'],            1, 'openoutput'); io_i = io_i + 1;
 io(io_i) = linio([mdl, '/Micro-Station/Spindle/Modal Analysis/accelerometer'],               1, 'openoutput'); io_i = io_i + 1;
 io(io_i) = linio([mdl, '/Micro-Station/Micro Hexapod/Modal Analysis/accelerometer'],         1, 'openoutput'); io_i = io_i + 1;
 % Run the linearization
 G_ms = linearize(mdl, io, 0);
 %% Input/Output definition
 clear io; io_i = 1;
 G_ms.InputName  = {'Fx', 'Fy', 'Fz'};
 G_ms.OutputName = {'gtop_x', 'gtop_y', 'gtop_z', 'gtop_rx', 'gtop_ry', 'gtop_rz', ...
                   'ty_x', 'ty_y', 'ty_z', 'ty_rx', 'ty_ry', 'ty_rz', ...
                   'ry_x', 'ry_y', 'ry_z', 'ry_rx', 'ry_ry', 'ry_rz', ...
                   'rz_x', 'rz_y', 'rz_z', 'rz_rx', 'rz_ry', 'rz_rz', ...
                   'hexa_x', 'hexa_y', 'hexa_z', 'hexa_rx', 'hexa_ry', 'hexa_rz'};
 % The output of =G_ms= is the acceleration of each solid body.
 % In order to obtain a displacement, we divide the obtained transfer function by $1/s^{2}$;
 G_ms = G_ms/s^2;
 % Compare with measurements
 % We now load the Frequency Response Functions measurements during the Modal Analysis (accessible [[file:../../meas/modal-analysis/index.org][here]]).
 load('../meas/modal-analysis/mat/frf_coh_matrices.mat', 'freqs');
 load('../meas/modal-analysis/mat/frf_com.mat', 'FRFs_CoM');
 % We then compare the measurements with the identified transfer functions using the Simscape Model.
 dirs = {'x', 'y', 'z', 'rx', 'ry', 'rz'};
 stages = {'gbot', 'gtop', 'ty', 'ry', 'rz', 'hexa'}
 n_stg = 3;
 n_dir = 6; % x, y, z, Rx, Ry, Rz
 n_exc = 2; % x, y, z
 f = logspace(0, 3, 1000);
 figure;
 hold on;
 plot(freqs, abs(squeeze(FRFs_CoM(6*(n_stg-1) + n_dir, n_exc, :)))./((2*pi*freqs).^2)');
 plot(f, abs(squeeze(freqresp(G_ms([stages{n_stg}, '_', dirs{n_dir}], ['F', dirs{n_exc}]), f, 'Hz'))));
 set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');
 ylabel('Amplitude [m/N]');
 hold off;
 xlim([1, 200]);
 dirs = {'x', 'y', 'z', 'rx', 'ry', 'rz'};
 stages = {'gtop', 'ty', 'ry', 'rz', 'hexa'}
 f = logspace(1, 3, 1000);
 figure;
 for n_stg = 1:2
  for n_dir = 1:3
    subplot(3, 2, (n_dir-1)*2 + n_stg);
    title(['F ', dirs{n_dir}, ' to ', stages{n_stg}, ' ', dirs{n_dir}]);
    hold on;
    plot(freqs, abs(squeeze(FRFs_CoM(6*(n_stg) + n_dir, n_dir, :)))./((2*pi*freqs).^2)');
    plot(f, abs(squeeze(freqresp(G_ms([stages{n_stg}, '_', dirs{n_dir}], ['F', dirs{n_dir}]), f, 'Hz'))));
    set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');
    ylabel('Amplitude [m/N]');
    if n_dir == 3
      xlabel('Frequency [Hz]');
    end
    hold off;
    xlim([10, 1000]);
    ylim([1e-12, 1e-6]);
  end
 end
 % #+NAME: fig:identification_comp_bot_stages
 % #+CAPTION: caption ([[./figs/identification_comp_bot_stages.png][png]], [[./figs/identification_comp_bot_stages.pdf][pdf]])
 % [[file:figs/identification_comp_bot_stages.png]]
 dirs = {'x', 'y', 'z', 'rx', 'ry', 'rz'};
 stages = {'ry', 'rz', 'hexa'}
 f = logspace(1, 3, 1000);
 figure;
 for n_stg = 1:2
  for n_dir = 1:3
    subplot(3, 2, (n_dir-1)*2 + n_stg);
    title(['F ', dirs{n_dir}, ' to ', stages{n_stg}, ' ', dirs{n_dir}]);
    hold on;
    plot(freqs, abs(squeeze(FRFs_CoM(6*(n_stg+2) + n_dir, n_dir, :)))./((2*pi*freqs).^2)');
    plot(f, abs(squeeze(freqresp(G_ms([stages{n_stg}, '_', dirs{n_dir}], ['F', dirs{n_dir}]), f, 'Hz'))));
    set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');
    ylabel('Amplitude [m/N]');
    if n_dir == 3
      xlabel('Frequency [Hz]');
    end
    hold off;
    xlim([10, 1000]);
    ylim([1e-12, 1e-6]);
  end
 end
 % #+NAME: fig:identification_comp_mid_stages
 % #+CAPTION: caption ([[./figs/identification_comp_mid_stages.png][png]], [[./figs/identification_comp_mid_stages.pdf][pdf]])
 % [[file:figs/identification_comp_mid_stages.png]]
 dirs = {'x', 'y', 'z', 'rx', 'ry', 'rz'};
 stages = {'hexa'}
 f = logspace(1, 3, 1000);
 figure;
 for n_stg = 1
  for n_dir = 1:3
    subplot(3, 1, (n_dir-1) + n_stg);
    title(['F ', dirs{n_dir}, ' to ', stages{n_stg}, ' ', dirs{n_dir}]);
    hold on;
    plot(freqs, abs(squeeze(FRFs_CoM(6*(n_stg+4) + n_dir, n_dir, :)))./((2*pi*freqs).^2)');
    plot(f, abs(squeeze(freqresp(G_ms([stages{n_stg}, '_', dirs{n_dir}], ['F', dirs{n_dir}]), f, 'Hz'))));
    set(gca, 'XScale', 'log'); set(gca, 'YScale', 'log');
    ylabel('Amplitude [m/N]');
    if n_dir == 3
      xlabel('Frequency [Hz]');
    end
    hold off;
    xlim([10, 1000]);
    ylim([1e-12, 1e-6]);
  end
 end
--- a/org/matlab/tomo_exp.m
+++ b/org/matlab/tomo_exp.m
@ -1,407 +0,0 @@
 %% Clear Workspace and Close figures
 clear; close all; clc;
 %% Intialize Laplace variable
 s = zpk('s');
 % Simscape Model
 % <<sec:simscape_model>>
 open('nass_model.slx');
 % We load the shared simulink configuration and we set the =StopTime=.
 load('mat/conf_simulink.mat');
 set_param(conf_simulink, 'StopTime', '5');
 % We first initialize all the stages.
 initializeGround();
 initializeGranite();
 initializeTy();
 initializeRy();
 initializeRz();
 initializeMicroHexapod();
 initializeAxisc();
 initializeMirror();
 initializeNanoHexapod('actuator', 'piezo');
 initializeSample('mass', 1);
 % We initialize the reference path for all the stages.
 % All stage is set to its zero position except the Spindle which is rotating at 60rpm.
 initializeReferences('Rz_type', 'rotating', 'Rz_period', 1);
 % Simulation Setup
 % And we initialize the disturbances to be equal to zero.
 initializeDisturbances(...
    'Dwx', false, ... % Ground Motion - X direction
    'Dwy', false, ... % Ground Motion - Y direction
    'Dwz', false, ... % Ground Motion - Z direction
    'Fty_x', false, ... % Translation Stage - X direction
    'Fty_z', false, ... % Translation Stage - Z direction
    'Frz_z', false  ... % Spindle - Z direction
    );
 % We simulate the model.
 sim('nass_model');
 % And we save the obtained data.
 tomo_align_no_dist = struct('t', t, 'MTr', MTr);
 save('experiment_tomography/mat/experiment.mat', 'tomo_align_no_dist', '-append');
 % Analysis
 load('experiment_tomography/mat/experiment.mat', 'tomo_align_no_dist');
 t = tomo_align_no_dist.t;
 MTr = tomo_align_no_dist.MTr;
 Edx = squeeze(MTr(1, 4, :));
 Edy = squeeze(MTr(2, 4, :));
 Edz = squeeze(MTr(3, 4, :));
 % The angles obtained are u-v-w Euler angles (rotations in the moving frame)
 Ery = atan2( squeeze(MTr(1, 3, :)),           squeeze(sqrt(MTr(1, 1, :).^2 + MTr(1, 2, :).^2)));
 Erx = atan2(-squeeze(MTr(2, 3, :))./cos(Ery), squeeze(MTr(3, 3, :))./cos(Ery));
 Erz = atan2(-squeeze(MTr(1, 2, :))./cos(Ery), squeeze(MTr(1, 1, :))./cos(Ery));
 figure;
 ax1 = subplot(1, 3, 1);
 plot(t, Edx, 'DisplayName', '$\epsilon_{x}$')
 ylabel('Displacement [m]');
 legend('location', 'northeast');
 ax2 = subplot(1, 3, 2);
 plot(t, Edy, 'DisplayName', '$\epsilon_{y}$')
 xlabel('Time [s]');
 legend('location', 'northeast');
 ax3 = subplot(1, 3, 3);
 plot(t, Edz, 'DisplayName', '$\epsilon_{z}$')
 legend('location', 'northeast');
 linkaxes([ax1,ax2,ax3],'x');
 xlim([2, inf]);
 % #+NAME: fig:exp_tomo_without_dist_trans
 % #+CAPTION: X-Y-Z translation of the sample w.r.t. granite when performing tomography experiment with no disturbances ([[./figs/exp_tomo_without_dist_trans.png][png]], [[./figs/exp_tomo_without_dist_trans.pdf][pdf]])
 % [[file:figs/exp_tomo_without_dist_trans.png]]
 figure;
 ax1 = subplot(1, 3, 1);
 plot(t, Erx, 'DisplayName', '$\epsilon_{\theta x}$')
 ylabel('Rotation [rad]');
 legend('location', 'northeast');
 ax2 = subplot(1, 3, 2);
 plot(t, Ery, 'DisplayName', '$\epsilon_{\theta y}$')
 xlabel('Time [s]');
 legend('location', 'northeast');
 ax3 = subplot(1, 3, 3);
 plot(t, Erz, 'DisplayName', '$\epsilon_{\theta z}$')
 legend('location', 'northeast');
 linkaxes([ax1,ax2,ax3],'x');
 xlim([2, inf]);
 % Simulation Setup
 % We now activate the disturbances.
 initializeDisturbances(...
    'Dwx', true, ... % Ground Motion - X direction
    'Dwy', true, ... % Ground Motion - Y direction
    'Dwz', true, ... % Ground Motion - Z direction
    'Fty_x', true, ... % Translation Stage - X direction
    'Fty_z', true, ... % Translation Stage - Z direction
    'Frz_z', true  ... % Spindle - Z direction
    );
 % We simulate the model.
 sim('nass_model');
 % And we save the obtained data.
 tomo_align_dist = struct('t', t, 'MTr', MTr);
 save('experiment_tomography/mat/experiment.mat', 'tomo_align_dist', '-append');
 % Analysis
 load('experiment_tomography/mat/experiment.mat', 'tomo_align_dist');
 t = tomo_align_dist.t;
 MTr = tomo_align_dist.MTr;
 Edx = squeeze(MTr(1, 4, :));
 Edy = squeeze(MTr(2, 4, :));
 Edz = squeeze(MTr(3, 4, :));
 % The angles obtained are u-v-w Euler angles (rotations in the moving frame)
 Ery = atan2( squeeze(MTr(1, 3, :)),           squeeze(sqrt(MTr(1, 1, :).^2 + MTr(1, 2, :).^2)));
 Erx = atan2(-squeeze(MTr(2, 3, :))./cos(Ery), squeeze(MTr(3, 3, :))./cos(Ery));
 Erz = atan2(-squeeze(MTr(1, 2, :))./cos(Ery), squeeze(MTr(1, 1, :))./cos(Ery));
 figure;
 ax1 = subplot(1, 3, 1);
 plot(t, Edx, 'DisplayName', '$\epsilon_{x}$')
 ylabel('Displacement [m]');
 legend('location', 'northeast');
 ax2 = subplot(1, 3, 2);
 plot(t, Edy, 'DisplayName', '$\epsilon_{y}$')
 xlabel('Time [s]');
 legend('location', 'northeast');
 ax3 = subplot(1, 3, 3);
 plot(t, Edz, 'DisplayName', '$\epsilon_{z}$')
 legend('location', 'northeast');
 linkaxes([ax1,ax2,ax3],'x');
 xlim([2, inf]);
 % #+NAME: fig:exp_tomo_dist_trans
 % #+CAPTION: X-Y-Z translation of the sample w.r.t. the granite when performing tomography experiment with disturbances ([[./figs/exp_tomo_dist_trans.png][png]], [[./figs/exp_tomo_dist_trans.pdf][pdf]])
 % [[file:figs/exp_tomo_dist_trans.png]]
 figure;
 ax1 = subplot(1, 3, 1);
 plot(t, Erx, 'DisplayName', '$\epsilon_{\theta x}$')
 ylabel('Rotation [rad]');
 legend('location', 'northeast');
 ax2 = subplot(1, 3, 2);
 plot(t, Ery, 'DisplayName', '$\epsilon_{\theta y}$')
 xlabel('Time [s]');
 legend('location', 'northeast');
 ax3 = subplot(1, 3, 3);
 plot(t, Erz, 'DisplayName', '$\epsilon_{\theta z}$')
 legend('location', 'northeast');
 linkaxes([ax1,ax2,ax3],'x');
 xlim([2, inf]);
 % Simulation Setup
 % We first set the wanted translation of the Micro Hexapod.
 P_micro_hexapod = [0.01; 0; 0]; % [m]
 % We initialize the reference path.
 initializeReferences('Dh_pos', [P_micro_hexapod; 0; 0; 0], 'Rz_type', 'rotating', 'Rz_period', 1);
 % We initialize the stages.
 initializeMicroHexapod('AP', P_micro_hexapod);
 % And we initialize the disturbances to zero.
 initializeDisturbances(...
    'Dwx', false, ... % Ground Motion - X direction
    'Dwy', false, ... % Ground Motion - Y direction
    'Dwz', false, ... % Ground Motion - Z direction
    'Fty_x', false, ... % Translation Stage - X direction
    'Fty_z', false, ... % Translation Stage - Z direction
    'Frz_z', false  ... % Spindle - Z direction
    );
 % We simulate the model.
 sim('nass_model');
 % And we save the obtained data.
 tomo_not_align = struct('t', t, 'MTr', MTr);
 save('experiment_tomography/mat/experiment.mat', 'tomo_not_align', '-append');
 % Analysis
 load('experiment_tomography/mat/experiment.mat', 'tomo_not_align');
 t = tomo_not_align.t;
 MTr = tomo_not_align.MTr;
 Edx = squeeze(MTr(1, 4, :));
 Edy = squeeze(MTr(2, 4, :));
 Edz = squeeze(MTr(3, 4, :));
 % The angles obtained are u-v-w Euler angles (rotations in the moving frame)
 Ery = atan2( squeeze(MTr(1, 3, :)),           squeeze(sqrt(MTr(1, 1, :).^2 + MTr(1, 2, :).^2)));
 Erx = atan2(-squeeze(MTr(2, 3, :))./cos(Ery), squeeze(MTr(3, 3, :))./cos(Ery));
 Erz = atan2(-squeeze(MTr(1, 2, :))./cos(Ery), squeeze(MTr(1, 1, :))./cos(Ery));
 figure;
 ax1 = subplot(1, 3, 1);
 plot(t, Edx, 'DisplayName', '$\epsilon_{x}$')
 ylabel('Displacement [m]');
 legend('location', 'northeast');
 ax2 = subplot(1, 3, 2);
 plot(t, Edy, 'DisplayName', '$\epsilon_{y}$')
 xlabel('Time [s]');
 legend('location', 'northeast');
 ax3 = subplot(1, 3, 3);
 plot(t, Edz, 'DisplayName', '$\epsilon_{z}$')
 legend('location', 'northeast');
 linkaxes([ax1,ax2,ax3],'x');
 xlim([2, inf]);
 % #+NAME: fig:exp_tomo_offset_trans
 % #+CAPTION: X-Y-Z translation of the sample w.r.t. granite when performing tomography experiment with no disturbances ([[./figs/exp_tomo_offset_trans.png][png]], [[./figs/exp_tomo_offset_trans.pdf][pdf]])
 % [[file:figs/exp_tomo_offset_trans.png]]
 figure;
 ax1 = subplot(1, 3, 1);
 plot(t, Erx, 'DisplayName', '$\epsilon_{\theta x}$')
 ylabel('Rotation [rad]');
 legend('location', 'northeast');
 ax2 = subplot(1, 3, 2);
 plot(t, Ery, 'DisplayName', '$\epsilon_{\theta y}$')
 xlabel('Time [s]');
 legend('location', 'northeast');
 ax3 = subplot(1, 3, 3);
 plot(t, Erz, 'DisplayName', '$\epsilon_{\theta z}$')
 legend('location', 'northeast');
 linkaxes([ax1,ax2,ax3],'x');
 xlim([2, inf]);
 % Simulation Setup
 % We set the reference path.
 initializeReferences('Dy_type', 'triangular', 'Dy_amplitude', 10e-3, 'Dy_period', 1);
 % We initialize the stages.
 initializeGround();
 initializeGranite();
 initializeTy();
 initializeRy();
 initializeRz();
 initializeMicroHexapod();
 initializeAxisc();
 initializeMirror();
 initializeNanoHexapod('actuator', 'piezo');
 initializeSample('mass', 1);
 % And we initialize the disturbances to zero.
 initializeDisturbances(...
    'Dwx', false, ... % Ground Motion - X direction
    'Dwy', false, ... % Ground Motion - Y direction
    'Dwz', false, ... % Ground Motion - Z direction
    'Fty_x', false, ... % Translation Stage - X direction
    'Fty_z', false, ... % Translation Stage - Z direction
    'Frz_z', false  ... % Spindle - Z direction
    );
 % We simulate the model.
 sim('nass_model');
 % And we save the obtained data.
 ty_scan = struct('t', t, 'MTr', MTr);
 save('experiment_tomography/mat/experiment.mat', 'ty_scan', '-append');
 % Analysis
 load('experiment_tomography/mat/experiment.mat', 'ty_scan');
 t = ty_scan.t;
 MTr = ty_scan.MTr;
 Edx = squeeze(MTr(1, 4, :));
 Edy = squeeze(MTr(2, 4, :));
 Edz = squeeze(MTr(3, 4, :));
 % The angles obtained are u-v-w Euler angles (rotations in the moving frame)
 Ery = atan2( squeeze(MTr(1, 3, :)),           squeeze(sqrt(MTr(1, 1, :).^2 + MTr(1, 2, :).^2)));
 Erx = atan2(-squeeze(MTr(2, 3, :))./cos(Ery), squeeze(MTr(3, 3, :))./cos(Ery));
 Erz = atan2(-squeeze(MTr(1, 2, :))./cos(Ery), squeeze(MTr(1, 1, :))./cos(Ery));
 figure;
 ax1 = subplot(1, 3, 1);
 plot(t, Edx, 'DisplayName', '$\epsilon_{x}$')
 ylabel('Displacement [m]');
 legend('location', 'northeast');
 ax2 = subplot(1, 3, 2);
 plot(t, Edy, 'DisplayName', '$\epsilon_{y}$')
 xlabel('Time [s]');
 legend('location', 'northeast');
 ax3 = subplot(1, 3, 3);
 plot(t, Edz, 'DisplayName', '$\epsilon_{z}$')
 legend('location', 'northeast');
 linkaxes([ax1,ax2,ax3],'x');
 xlim([2, inf]);
 % #+NAME: fig:exp_ty_scan_trans
 % #+CAPTION: X-Y-Z translation of the sample w.r.t. granite when performing tomography experiment with no disturbances ([[./figs/exp_ty_scan_trans.png][png]], [[./figs/exp_ty_scan_trans.pdf][pdf]])
 % [[file:figs/exp_ty_scan_trans.png]]
 figure;
 ax1 = subplot(1, 3, 1);
 plot(t, Erx, 'DisplayName', '$\epsilon_{\theta x}$')
 ylabel('Rotation [rad]');
 legend('location', 'northeast');
 ax2 = subplot(1, 3, 2);
 plot(t, Ery, 'DisplayName', '$\epsilon_{\theta y}$')
 xlabel('Time [s]');
 legend('location', 'northeast');
 ax3 = subplot(1, 3, 3);
 plot(t, Erz, 'DisplayName', '$\epsilon_{\theta z}$')
 legend('location', 'northeast');
 linkaxes([ax1,ax2,ax3],'x');
 xlim([2, inf]);
--- a/org/src/prepareLinearizeIdentification.m
+++ b/org/src/prepareLinearizeIdentification.m
@ -1,27 +0,0 @@
 function [] = prepareLinearizeIdentification(args)
 arguments
    args.nass_actuator       char   {mustBeMember(args.nass_actuator,{'piezo', 'lorentz'})} = 'piezo'
    args.sample_mass   (1,1) double {mustBeNumeric, mustBePositive} = 50 % [kg]
 end
 initializeGround();
 initializeGranite();
 initializeTy();
 initializeRy();
 initializeRz();
 initializeMicroHexapod();
 initializeAxisc();
 initializeMirror();
 initializeNanoHexapod('actuator', args.nass_actuator);
 initializeSample('mass', args.sample_mass);
 initializeReferences();
 initializeDisturbances('enable', false);
 initializeController('type', 'open-loop');
 initializeSimscapeConfiguration('gravity', true);
 initializeLoggingConfiguration('log', 'none');
--- a/org/src/prepareTomographyExperiment.m
+++ b/org/src/prepareTomographyExperiment.m
@ -1,29 +0,0 @@
 function [] = prepareTomographyExperiment(args)
 arguments
    args.nass_actuator       char   {mustBeMember(args.nass_actuator,{'piezo', 'lorentz'})} = 'piezo'
    args.sample_mass   (1,1) double {mustBeNumeric, mustBePositive} = 50 % [kg]
    args.Rz_period     (1,1) double {mustBeNumeric, mustBePositive} = 1 % [s]
 end
 initializeGround();
 initializeGranite();
 initializeTy();
 initializeRy();
 initializeRz();
 initializeMicroHexapod();
 initializeAxisc();
 initializeMirror();
 initializeNanoHexapod('actuator', args.nass_actuator);
 initializeSample('mass', args.sample_mass);
 initializeReferences('Rz_type', 'rotating', 'Rz_period', args.Rz_period);
 initializeDisturbances();
 initializeController('type', 'open-loop');
 initializeSimscapeConfiguration('gravity', true);
 initializeLoggingConfiguration('log', 'all');
--- a/src/computePsdDispl.m
+++ b/src/computePsdDispl.m
@ -1,23 +0,0 @@
 function [psd_object] = computePsdDispl(sys_data, t_init, n_av)
    i_init = find(sys_data.time > t_init, 1);
    han_win = hanning(ceil(length(sys_data.Dx(i_init:end, :))/n_av));
    Fs = 1/sys_data.time(2);
    [pdx, f] = pwelch(sys_data.Dx(i_init:end, :), han_win, [], [], Fs);
    [pdy, ~] = pwelch(sys_data.Dy(i_init:end, :), han_win, [], [], Fs);
    [pdz, ~] = pwelch(sys_data.Dz(i_init:end, :), han_win, [], [], Fs);
    [prx, ~] = pwelch(sys_data.Rx(i_init:end, :), han_win, [], [], Fs);
    [pry, ~] = pwelch(sys_data.Ry(i_init:end, :), han_win, [], [], Fs);
    [prz, ~] = pwelch(sys_data.Rz(i_init:end, :), han_win, [], [], Fs);
    psd_object = struct(...
        'f',  f,   ...
        'dx', pdx, ...
        'dy', pdy, ...
        'dz', pdz, ...
        'rx', prx, ...
        'ry', pry, ...
        'rz', prz);
 end
--- a/src/computeSetpoint.m
+++ b/src/computeSetpoint.m
@ -1,59 +0,0 @@
 function setpoint = computeSetpoint(ty, ry, rz)
 %%
 setpoint = zeros(6, 1);
 %% Ty
 Ty = [1 0 0 0  ;
      0 1 0 ty ;
      0 0 1 0  ;
      0 0 0 1 ];
 % Tyinv = [1 0 0  0  ;
 %          0 1 0 -ty ;
 %          0 0 1  0  ;
 %          0 0 0  1 ];
 %% Ry
 Ry = [ cos(ry) 0 sin(ry) 0 ;
      0       1 0       0 ;
      -sin(ry) 0 cos(ry) 0 ;
      0        0 0       1 ];
 % TMry = Ty*Ry*Tyinv;
 %% Rz
 Rz = [cos(rz) -sin(rz) 0 0 ;
      sin(rz)  cos(rz) 0 0 ;
      0        0       1 0 ;
      0        0       0 1 ];
 % TMrz = Ty*TMry*Rz*TMry'*Tyinv;
 %% All stages
 % TM = TMrz*TMry*Ty;
 TM = Ty*Ry*Rz;
 [thetax, thetay, thetaz] = RM2angle(TM(1:3, 1:3));
 setpoint(1:3) = TM(1:3, 4);
 setpoint(4:6) = [thetax, thetay, thetaz];
 %% Custom Functions
 function [thetax, thetay, thetaz] = RM2angle(R)
    if abs(abs(R(3, 1)) - 1) > 1e-6 % R31 != 1 and R31 != -1
        thetay = -asin(R(3, 1));
        thetax = atan2(R(3, 2)/cos(thetay), R(3, 3)/cos(thetay));
        thetaz = atan2(R(2, 1)/cos(thetay), R(1, 1)/cos(thetay));
    else
        thetaz = 0;
        if abs(R(3, 1)+1) < 1e-6 % R31 = -1
            thetay = pi/2;
            thetax = thetaz + atan2(R(1, 2), R(1, 3));
        else
            thetay = -pi/2;
            thetax = -thetaz + atan2(-R(1, 2), -R(1, 3));
        end
    end
 end
 end
--- a/src/converErrorBasis.m
+++ b/src/converErrorBasis.m
@ -1,125 +0,0 @@
 function error_nass = convertErrorBasis(pos, setpoint, ty, ry, rz)
 % convertErrorBasis -
 %
 % Syntax: convertErrorBasis(p_error, ty, ry, rz)
 %
 % Inputs:
 %    - p_error - Position error of the sample w.r.t. the granite [m, rad]
 %    - ty - Measured translation of the Ty stage [m]
 %    - ry - Measured rotation of the Ry stage [rad]
 %    - rz - Measured rotation of the Rz stage [rad]
 %
 % Outputs:
 %    - P_nass - Position error of the sample w.r.t. the NASS base [m]
 %    - R_nass - Rotation error of the sample w.r.t. the NASS base [rad]
 %
 % Example:
 %
 %% If line vector => column vector
 if size(pos, 2) == 6
    pos = pos';
 end
 if size(setpoint, 2) == 6
    setpoint = setpoint';
 end
 %% Position of the sample in the frame fixed to the Granite
 P_granite = [pos(1:3); 1]; % Position [m]
 R_granite = [setpoint(1:3); 1]; % Reference [m]
 %% Transformation matrices of the stages
 % T-y
 TMty = [1 0 0 0  ;
        0 1 0 ty ;
        0 0 1 0  ;
        0 0 0 1 ];
 % R-y
 TMry = [ cos(ry) 0 sin(ry) 0 ;
        0       1 0       0 ;
        -sin(ry) 0 cos(ry) 0 ;
        0        0 0       1 ];
 % R-z
 TMrz = [cos(rz) -sin(rz) 0 0 ;
        sin(rz)  cos(rz) 0 0 ;
        0        0       1 0 ;
        0        0       0 1 ];
 %% Compute Point coordinates in the new reference fixed to the NASS base
 % P_nass = TMrz*TMry*TMty*P_granite;
 P_nass = TMrz\TMry\TMty\P_granite;
 R_nass = TMrz\TMry\TMty\R_granite;
 dx = R_nass(1)-P_nass(1);
 dy = R_nass(2)-P_nass(2);
 dz = R_nass(3)-P_nass(3);
 %% Compute new basis vectors linked to the NASS base
 % ux_nass = TMrz*TMry*TMty*[1; 0; 0; 0];
 % ux_nass = ux_nass(1:3);
 % uy_nass = TMrz*TMry*TMty*[0; 1; 0; 0];
 % uy_nass = uy_nass(1:3);
 % uz_nass = TMrz*TMry*TMty*[0; 0; 1; 0];
 % uz_nass = uz_nass(1:3);
 ux_nass = TMrz\TMry\TMty\[1; 0; 0; 0];
 ux_nass = ux_nass(1:3);
 uy_nass = TMrz\TMry\TMty\[0; 1; 0; 0];
 uy_nass = uy_nass(1:3);
 uz_nass = TMrz\TMry\TMty\[0; 0; 1; 0];
 uz_nass = uz_nass(1:3);
 %% Rotations error w.r.t. granite Frame
 % Rotations error w.r.t. granite Frame
 rx_nass = pos(4);
 ry_nass = pos(5);
 rz_nass = pos(6);
 % Rotation matrices of the Sample w.r.t. the Granite
 Mrx_error = [1 0              0 ;
            0 cos(-rx_nass) -sin(-rx_nass) ;
            0 sin(-rx_nass)  cos(-rx_nass)];
 Mry_error = [ cos(-ry_nass) 0 sin(-ry_nass) ;
              0             1 0 ;
            -sin(-ry_nass) 0 cos(-ry_nass)];
 Mrz_error = [cos(-rz_nass) -sin(-rz_nass) 0 ;
            sin(-rz_nass)  cos(-rz_nass) 0 ;
            0              0             1];
 % Rotation matrix of the Sample w.r.t. the Granite
 Mr_error = Mrz_error*Mry_error*Mrx_error;
 %% Use matrix to solve
 R = Mr_error/[ux_nass, uy_nass, uz_nass]; % Rotation matrix from NASS base to Sample
 [thetax, thetay, thetaz] = RM2angle(R);
 error_nass = [dx; dy; dz; thetax; thetay; thetaz];
 %% Custom Functions
 function [thetax, thetay, thetaz] = RM2angle(R)
    if abs(abs(R(3, 1)) - 1) > 1e-6 % R31 != 1 and R31 != -1
        thetay = -asin(R(3, 1));
        % thetaybis = pi-thetay;
        thetax = atan2(R(3, 2)/cos(thetay), R(3, 3)/cos(thetay));
        % thetaxbis = atan2(R(3, 2)/cos(thetaybis), R(3, 3)/cos(thetaybis));
        thetaz = atan2(R(2, 1)/cos(thetay), R(1, 1)/cos(thetay));
        % thetazbis = atan2(R(2, 1)/cos(thetaybis), R(1, 1)/cos(thetaybis));
    else
        thetaz = 0;
        if abs(R(3, 1)+1) < 1e-6 % R31 = -1
            thetay = pi/2;
            thetax = thetaz + atan2(R(1, 2), R(1, 3));
        else
            thetay = -pi/2;
            thetax = -thetaz + atan2(-R(1, 2), -R(1, 3));
        end
    end
 end
 end