2019-12-11 17:09:32 +01:00
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#+TITLE: Matlab Functions used for the NASS Project
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2020-04-17 10:25:44 +02:00
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#+SETUPFILE: ./setup/org-setup-file.org
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2019-12-11 17:09:32 +01:00
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2020-04-15 10:56:18 +02:00
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* describeNassSetup
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:PROPERTIES:
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:header-args:matlab+: :tangle ..//src/describeNassSetup.m
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:header-args:matlab+: :comments none :mkdirp yes :eval no
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:END:
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<<sec:describeNassSetup>>
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** Function description
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:PROPERTIES:
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:UNNUMBERED: t
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:END:
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#+begin_src matlab
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function [] = describeNassSetup()
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% describeNassSetup -
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%
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% Syntax: [] = describeNassSetup()
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%
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% Inputs:
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% - -
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%
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% Outputs:
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% - -
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#+end_src
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** Simscape Configuration
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:PROPERTIES:
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:UNNUMBERED: t
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:END:
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#+begin_src matlab
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load('./mat/conf_simscape.mat', 'conf_simscape');
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#+end_src
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#+begin_src matlab
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fprintf('Simscape Configuration:\n');
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if conf_simscape.type == 1
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fprintf('- Gravity is included\n');
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else
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fprintf('- Gravity is not included\n');
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end
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fprintf('\n');
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#+end_src
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** Disturbances
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:PROPERTIES:
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:UNNUMBERED: t
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:END:
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#+begin_src matlab
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load('./mat/nass_disturbances.mat', 'args');
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#+end_src
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#+begin_src matlab
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fprintf('Disturbances:\n');
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if ~args.enable
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fprintf('- No disturbance is included\n');
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else
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if args.Dwx && args.Dwy && args.Dwz
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fprintf('- Ground motion\n');
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end
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if args.Fty_x && args.Fty_z
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fprintf('- Vibrations of the Translation Stage\n');
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end
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if args.Frz_z
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fprintf('- Vibrations of the Spindle\n');
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end
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end
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fprintf('\n');
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#+end_src
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** References
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:PROPERTIES:
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:UNNUMBERED: t
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:END:
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#+begin_src matlab
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load('./mat/nass_references.mat', 'args');
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#+end_src
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#+begin_src matlab
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fprintf('Reference Tracking:\n');
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fprintf('- Translation Stage:\n');
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switch args.Dy_type
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case 'constant'
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fprintf(' - Constant Position\n');
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fprintf(' - Dy = %.0f [mm]\n', args.Dy_amplitude*1e3);
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case 'triangular'
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fprintf(' - Triangular Path\n');
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fprintf(' - Amplitude = %.0f [mm]\n', args.Dy_amplitude*1e3);
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fprintf(' - Period = %.0f [s]\n', args.Dy_period);
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case 'sinusoidal'
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fprintf(' - Sinusoidal Path\n');
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fprintf(' - Amplitude = %.0f [mm]\n', args.Dy_amplitude*1e3);
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fprintf(' - Period = %.0f [s]\n', args.Dy_period);
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end
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fprintf('- Tilt Stage:\n');
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switch args.Ry_type
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case 'constant'
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fprintf(' - Constant Position\n');
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fprintf(' - Ry = %.0f [mm]\n', args.Ry_amplitude*1e3);
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case 'triangular'
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fprintf(' - Triangular Path\n');
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fprintf(' - Amplitude = %.0f [mm]\n', args.Ry_amplitude*1e3);
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fprintf(' - Period = %.0f [s]\n', args.Ry_period);
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case 'sinusoidal'
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fprintf(' - Sinusoidal Path\n');
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fprintf(' - Amplitude = %.0f [mm]\n', args.Ry_amplitude*1e3);
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fprintf(' - Period = %.0f [s]\n', args.Ry_period);
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end
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fprintf('- Spindle:\n');
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switch args.Rz_type
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case 'constant'
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fprintf(' - Constant Position\n');
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fprintf(' - Rz = %.0f [deg]\n', 180/pi*args.Rz_amplitude);
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case { 'rotating', 'rotating-not-filtered' }
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fprintf(' - Rotating\n');
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fprintf(' - Speed = %.0f [rpm]\n', 60/Rz_period);
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end
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fprintf('- Micro Hexapod:\n');
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switch args.Dh_type
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case 'constant'
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fprintf(' - Constant Position\n');
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fprintf(' - Dh = %.0f, %.0f, %.0f [mm]\n', args.Dh_pos(1), args.Dh_pos(2), args.Dh_pos(3));
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fprintf(' - Rh = %.0f, %.0f, %.0f [deg]\n', args.Dh_pos(4), args.Dh_pos(5), args.Dh_pos(6));
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end
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fprintf('\n');
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#+end_src
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** Controller
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:PROPERTIES:
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:UNNUMBERED: t
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:END:
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#+begin_src matlab
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load('./mat/controller.mat', 'controller');
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#+end_src
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#+begin_src matlab
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fprintf('Controller:\n');
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fprintf('- %s\n', controller.name);
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fprintf('\n');
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#+end_src
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** Micro-Station
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:PROPERTIES:
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:UNNUMBERED: t
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:END:
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#+begin_src matlab
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load('./mat/stages.mat', 'ground', 'granite', 'ty', 'ry', 'rz', 'micro_hexapod', 'axisc');
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#+end_src
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#+begin_src matlab
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fprintf('Micro Station:\n');
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if granite.type == 1 && ...
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ty.type == 1 && ...
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ry.type == 1 && ...
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rz.type == 1 && ...
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micro_hexapod.type == 1;
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fprintf('- All stages are rigid\n');
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elseif granite.type == 2 && ...
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ty.type == 2 && ...
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ry.type == 2 && ...
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rz.type == 2 && ...
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micro_hexapod.type == 2;
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fprintf('- All stages are flexible\n');
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else
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if granite.type == 1 || granite.type == 4
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fprintf('- Granite is rigid\n');
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else
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fprintf('- Granite is flexible\n');
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end
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if ty.type == 1 || ty.type == 4
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fprintf('- Translation Stage is rigid\n');
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else
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fprintf('- Translation Stage is flexible\n');
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end
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if ry.type == 1 || ry.type == 4
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fprintf('- Tilt Stage is rigid\n');
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else
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fprintf('- Tilt Stage is flexible\n');
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end
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if rz.type == 1 || rz.type == 4
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fprintf('- Spindle is rigid\n');
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else
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fprintf('- Spindle is flexible\n');
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end
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if micro_hexapod.type == 1 || micro_hexapod.type == 4
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fprintf('- Micro Hexapod is rigid\n');
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else
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fprintf('- Micro Hexapod is flexible\n');
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end
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end
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fprintf('\n');
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#+end_src
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** Metrology
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:PROPERTIES:
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:UNNUMBERED: t
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:END:
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#+begin_src matlab
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load('./mat/stages.mat', 'mirror');
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#+end_src
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#+begin_src matlab
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fprintf('Reference Mirror:\n');
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if mirror.type == 2;
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fprintf('- flexible fixation\n');
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fprintf('- w = %.0f [Hz]\n', mirror.freq(1));
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else
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fprintf('- rigidly attached to the nano-hexapod\n');
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end
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fprintf('- m = %.0f [kg]\n', mirror.mass);
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fprintf('\n');
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#+end_src
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** Nano Hexapod
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:PROPERTIES:
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:UNNUMBERED: t
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:END:
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#+begin_src matlab
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load('./mat/stages.mat', 'nano_hexapod');
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#+end_src
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#+begin_src matlab
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fprintf('Nano Hexapod:\n');
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if nano_hexapod.type == 0;
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fprintf('- no included\n');
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elseif nano_hexapod.type == 1 || nano_hexapod.type == 3;
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fprintf('- rigid\n');
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elseif nano_hexapod.type == 2;
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fprintf('- flexible\n');
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fprintf('- Ki = %.0g [N/m]\n', nano_hexapod.Ki(1));
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end
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fprintf('\n');
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#+end_src
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** Sample
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:PROPERTIES:
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:UNNUMBERED: t
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:END:
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#+begin_src matlab
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load('./mat/stages.mat', 'sample');
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#+end_src
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#+begin_src matlab
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fprintf('Sample:\n');
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if sample.type == 0;
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fprintf('- no included\n');
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elseif sample.type == 1 || sample.type == 3;
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fprintf('- rigid\n');
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fprintf('- mass = %.0f [kg]\n', sample.mass);
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fprintf('- moment of inertia = %.2f, %.2f, %.2f [kg m2]\n', sample.inertia(1), sample.inertia(2), sample.inertia(3));
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elseif sample.type == 2;
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fprintf('- flexible\n');
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fprintf('- mass = %.0f [kg]\n', sample.mass);
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fprintf('- moment of inertia = %.2f, %.2f, %.2f [kg m2]\n', sample.inertia(1), sample.inertia(2), sample.inertia(3));
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% fprintf('- Kt = %.0g, %.0g, %.0g [N/m]\n', sample.K(1), sample.K(2), sample.K(3));
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% fprintf('- Kr = %.0g, %.0g, %.0g [Nm/rad]\n', sample.K(4), sample.K(5), sample.K(6));
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fprintf('- wt(x,y,z) = %.0f, %.0f, %.0f [Hz]\n', 1/2/pi*sqrt(sample.K(1)/sample.mass), 1/2/pi*sqrt(sample.K(1)/sample.mass), 1/2/pi*sqrt(sample.K(1)/sample.mass));
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fprintf('- wr(x,y,z) = %.0f, %.0f, %.0f [Hz]\n', 1/2/pi*sqrt(sample.K(4)/sample.inertia(1)), 1/2/pi*sqrt(sample.K(5)/sample.inertia(2)), 1/2/pi*sqrt(sample.K(6)/sample.inertia(3)));
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end
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fprintf('\n');
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#+end_src
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2020-01-29 20:25:59 +01:00
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* computeReferencePose
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2019-12-11 17:33:45 +01:00
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:PROPERTIES:
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:header-args:matlab+: :tangle ../src/computeReferencePose.m
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:header-args:matlab+: :comments none :mkdirp yes :eval no
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:END:
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<<sec:computeReferencePose>>
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2020-03-23 10:04:09 +01:00
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This Matlab function is accessible [[file:..//src/computeReferencePose.m][here]].
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2019-12-11 17:33:45 +01:00
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#+begin_src matlab
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function [WTr] = computeReferencePose(Dy, Ry, Rz, Dh, Dn)
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% computeReferencePose - Compute the homogeneous transformation matrix corresponding to the wanted pose of the sample
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%
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% Syntax: [WTr] = computeReferencePose(Dy, Ry, Rz, Dh, Dn)
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%
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% Inputs:
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% - Dy - Reference of the Translation Stage [m]
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% - Ry - Reference of the Tilt Stage [rad]
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% - Rz - Reference of the Spindle [rad]
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% - Dh - Reference of the Micro Hexapod (Pitch, Roll, Yaw angles) [m, m, m, rad, rad, rad]
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% - Dn - Reference of the Nano Hexapod [m, m, m, rad, rad, rad]
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%
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% Outputs:
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% - WTr -
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%% Translation Stage
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Rty = [1 0 0 0;
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0 1 0 Dy;
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0 0 1 0;
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0 0 0 1];
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%% Tilt Stage - Pure rotating aligned with Ob
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Rry = [ cos(Ry) 0 sin(Ry) 0;
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0 1 0 0;
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-sin(Ry) 0 cos(Ry) 0;
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0 0 0 1];
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%% Spindle - Rotation along the Z axis
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Rrz = [cos(Rz) -sin(Rz) 0 0 ;
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sin(Rz) cos(Rz) 0 0 ;
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0 0 1 0 ;
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0 0 0 1 ];
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%% Micro-Hexapod
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Rhx = [1 0 0;
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0 cos(Dh(4)) -sin(Dh(4));
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0 sin(Dh(4)) cos(Dh(4))];
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Rhy = [ cos(Dh(5)) 0 sin(Dh(5));
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0 1 0;
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-sin(Dh(5)) 0 cos(Dh(5))];
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Rhz = [cos(Dh(6)) -sin(Dh(6)) 0;
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sin(Dh(6)) cos(Dh(6)) 0;
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0 0 1];
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Rh = [1 0 0 Dh(1) ;
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0 1 0 Dh(2) ;
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0 0 1 Dh(3) ;
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0 0 0 1 ];
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Rh(1:3, 1:3) = Rhz*Rhy*Rhx;
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%% Nano-Hexapod
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Rnx = [1 0 0;
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0 cos(Dn(4)) -sin(Dn(4));
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0 sin(Dn(4)) cos(Dn(4))];
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Rny = [ cos(Dn(5)) 0 sin(Dn(5));
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0 1 0;
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-sin(Dn(5)) 0 cos(Dn(5))];
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Rnz = [cos(Dn(6)) -sin(Dn(6)) 0;
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sin(Dn(6)) cos(Dn(6)) 0;
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0 0 1];
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Rn = [1 0 0 Dn(1) ;
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0 1 0 Dn(2) ;
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0 0 1 Dn(3) ;
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0 0 0 1 ];
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2020-02-25 17:49:08 +01:00
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Rn(1:3, 1:3) = Rnz*Rny*Rnx;
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2019-12-11 17:33:45 +01:00
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%% Total Homogeneous transformation
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WTr = Rty*Rry*Rrz*Rh*Rn;
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end
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#+end_src
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2020-03-23 10:04:09 +01:00
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2020-01-29 20:25:59 +01:00
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* Compute the Sample Position Error w.r.t. the NASS
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2019-12-17 08:28:20 +01:00
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:PROPERTIES:
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:header-args:matlab+: :tangle ../src/computeSampleError.m
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:header-args:matlab+: :comments none :mkdirp yes :eval no
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:END:
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<<sec:computeSampleError>>
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2020-03-23 10:04:09 +01:00
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This Matlab function is accessible [[file:..//src/computeSampleError.m][here]].
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2019-12-17 08:28:20 +01:00
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#+begin_src matlab
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function [MTr] = computeSampleError(WTm, WTr)
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% computeSampleError -
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%
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% Syntax: [MTr] = computeSampleError(WTm, WTr)
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%
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% Inputs:
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% - WTm - Homoegeneous transformation that represent the
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% wanted pose of the sample with respect to the granite
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% - WTr - Homoegeneous transformation that represent the
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% measured pose of the sample with respect to the granite
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%
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% Outputs:
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% - MTr - Homoegeneous transformation that represent the
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% wanted pose of the sample expressed in a frame
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% attached to the top platform of the nano-hexapod
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MTr = zeros(4,4);
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MTr = [WTm(1:3,1:3)', -WTm(1:3,1:3)'*WTm(1:3,4) ; 0 0 0 1]*WTr;
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end
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#+end_src
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