147 lines
4.6 KiB
Mathematica
147 lines
4.6 KiB
Mathematica
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function Res = Tilt_Spindle_error(dataX, dataX2,NbTurn, texte, path)
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L = length(dataX);
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res_per_rev = L/NbTurn;
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P = 0: (res_per_rev * NbTurn)-1;
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Pos = P'*360/res_per_rev;
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Theta = deg2rad(Pos)';
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D = 76.2; %distance entre les deux balls en milimetres
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x1 = myfit2(Pos, dataX);
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y1 = myfit2(Pos, dataX2);
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%Convert data to frequency domain and scale accordingly
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X2 = 2/(res_per_rev*NbTurn)*fft(x1);
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f2 = (0:L-1)./NbTurn;
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Y2 = 2/(res_per_rev*NbTurn)*fft(y1);
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% Separate the fft integers and not-integers
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for i = 1:length(f2)
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if mod(f2(i), 1) == 0
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X2dec(i) = 0;
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X2int(i) = X2(i);
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Y2dec(i) = 0;
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Y2int(i) = Y2(i);
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else
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X2dec(i) = X2(i);
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X2int(i) = 0;
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Y2dec(i) = Y2(i);
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Y2int(i) = 0;
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end
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end
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if mod(length(f2),2) == 1 % Case length(f2) is odd -> the mirror image of the FFT is reflected between 2 harmonique
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for i = length(f2)/2+1.5:length(f2)
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if mod(f2(i-1), 1) == 0
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X2dec(i) = 0;
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X2int(i) = X2(i);
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Y2dec(i) = 0;
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Y2int(i) = Y2(i);
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else
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X2dec(i) = X2(i);
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X2int(i) = 0;
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Y2dec(i) = Y2(i);
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Y2int(i) = 0;
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end
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end
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else % Case length(f2) is even -> the mirror image of the FFT is reflected at the Nyquist frequency
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for i = length(f2)/2+1:length(f2)
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if mod(f2(i), 1) == 0;
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X2dec(i) = 0;
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X2int(i) = X2(i);
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Y2dec(i) = 0;
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Y2int(i) = Y2(i);
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else
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X2dec(i) = X2(i);
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X2int(i) = 0;
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Y2dec(i) = Y2(i);
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Y2int(i) = 0;
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end
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end
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end
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X2int(1) = 0; %remove the data average/dc component
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X2int(NbTurn+1) = 0; %Remove fondamental/eccentricity
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% X2int(length(f2)) = 0; %remove the data average/dc component
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X2int(length(f2)-NbTurn+1) = 0; %Remove eccentricity
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Y2int(1) = 0; %remove the data average/dc component
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Y2int(NbTurn+1) = 0; %Remove fondamental/eccentricity
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% Y2int(length(f2)) = 0; %remove the data average/dc component
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Y2int(length(f2)-NbTurn+1) = 0; %Remove eccentricity
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% Extract the fondamentale-> exentricity
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for i = 1:length(f2)
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if i == NbTurn+1 || i== length(f2)-NbTurn + 1
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X2fond(i) = X2(i);
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Y2fond(i) = Y2(i);
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else
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X2fond(i) = 0;
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Y2fond(i) = 0;
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end
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end
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X2tot = X2int + X2dec;
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Y2tot = Y2int + Y2dec;
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%Convert data to "time" domain and scale accordingly
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Wxint = real((res_per_rev*NbTurn)/2*ifft(X2int));
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Wxdec = real((res_per_rev*NbTurn)/2*ifft(X2dec));
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Wxtot = real((res_per_rev*NbTurn)/2*ifft(X2tot));
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%Convert data to "time" domain and scale accordingly
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Wyint = real((res_per_rev*NbTurn)/2*ifft(Y2int));
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Wydec = real((res_per_rev*NbTurn)/2*ifft(Y2dec));
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Wytot = real((res_per_rev*NbTurn)/2*ifft(Y2tot));
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Tint = atan((Wyint - Wxint)/(D*1000));
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Tdec = atan((Wydec - Wxdec)/(D*1000));
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Ttot = atan((Wytot - Wxtot)/(D*1000));
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%%
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fig = figure();
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% total error motion
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Total_Error = max(Ttot)- min(Ttot);
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%lsc X synchronous
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Synchronous_Error = max(Tint)- min(Tint);
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%lsc X Asynchronous
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var = reshape(Tdec,length(Tdec)/NbTurn,NbTurn);
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for i = 1:length(Tdec)/NbTurn
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Asynch(i) = max(var(i,:)) - min(var(i,:)) ;
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end
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Asynchronous_Error = max(Asynch)- min(Asynch);
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% Raw Error Motion without Exentricity (sync +asynch)
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subplot(2, 2, 2);
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polar2(Theta,Ttot, 'b');
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title('Total error');
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% Residual Synchronous Error Motion without Exentricity (ie fondamental sync err motion)
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subplot(2, 2, 3);
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polar2(Theta,Tint,'b');
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title('Residual synchronous error');
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% Asynchronous Error Motion
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subplot(2, 2, 4);
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polar2(Theta,Tdec, 'b');
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title ('Asynchronous error');
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%%
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strmin1 = ['Total error = ', num2str(Total_Error*1000000), ' \murad'];
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strmin2 = ['Residual synchronous error = ', num2str(Synchronous_Error*1000000), ' \murad' ];
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strmin3 = ['Asynchronous error = ', num2str(Asynchronous_Error*1000000), ' \murad'];
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dim0 =[0.04 0.5 0.3 .3];%x y w h basgauche to hautdroite
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dim1 =[0.15 0.65 0.3 .3];
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annotation('textbox',dim0, 'String',{ strmin1 , strmin2, strmin3}, 'FitBoxToText', 'on')
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annotation('textbox',dim1, 'String',texte, 'FitBoxToText', 'on')
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saveas(fig,fullfile(path,char(texte)),'jpg');
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Res = 1;
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close all;
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end
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