Diss/01_tex/figures/tikz/Plot_nurbs_gewichte.m

%% Skript zum Plot Interpolieren

%Skript f<EFBFBD>r Plotbasics
basics_plot

%Kontrollpunkte definieren:
fig_Res = figure(1); % figure handle erzeugen



clf(fig_Res)

grid on

strNurbBasic = struct('p',[],'pj',[],'u',[]);

nurbs = strNurbBasic;

nurbs.u = [0,0,0,1,1,1];

nurbs.p = [2];

for i = 1:5
    
    switch i
        case 1
            wi = 0.2;
            lineStyle = myLineTwo;
        case 2
            wi = 0.6;
            lineStyle = myLineThree;
        case 3
            wi = 1;
            lineStyle = myLineOne;
        case 4
            wi = 2;
            lineStyle = myLineFour;
        case 5
            wi = 4;
            lineStyle = myLineFive;
    end
            
            

nurbs.pj = [0 wi*1 1;0 wi*0 1;1 wi 1];


ui = 0:0.01:1;

vek = zeros(2,numel(ui));


for j = 1:numel(ui)
    vek(:,j) = berechneAbleitungenAnPunkt(ui(j),nurbs.p,nurbs.u,nurbs.pj,0);
end

plot(vek(1,:),vek(2,:),'Color',lineStyle)


hold on



end

plot(nurbs.pj(1,1:end)./nurbs.pj(end,1:end),nurbs.pj(2,1:end)./nurbs.pj(end,1:end),'LineStyle','none','Marker','x','MarkerSize',8,'Color',myLineOne,'LineWidth',1.1)
grid on


xlabel('\figureXLabel')
ylabel('\figureYLabel')

set(gca,'XLim',[0,1])
set(gca,'YLim',[0,1])

% 
% % scatter(P(1,:),P(2,:),'x','MarkerEdgeColor','black','LineWidth',1.5,'SizeData',400)
% 
% % axis off 
% 
% axis equal
% hold on
% 
% text(P(1,1)+0.2,P(2,1)+0.1,'$\mv{p}_{i-1}$','Interpreter','none')
% text(P(1,2)+0.1,P(2,2)+0.4,'$\mv{p}_i$','Interpreter','none')
% text(P(1,3)+0.1,P(2,3)-0.3,'$\mv{p}_{i+1}$','Interpreter','none')
% text(P(1,4)-0.9,P(2,4)+0.3,'$\mv{p}_{i+2}$','Interpreter','none')
% 
% 
% 
% %% Polynomfit
% % 
% % a = polyfit(P(1,:),P(2,:),3);
% % y = polyval(a,[-5:0.01:5]);
% % plot([-5:0.01:5],y,'LineStyle','--','Color',myLineThree)
% 
% 
% %% Lineare Interpolation mit zirkularer Blende
% 
% % Winkelhalbierende berechnen
% 
% 
% delta = [0,1.2,0.7,0];
% 
% for i = 2:size(P,2)-1
%     
%     n1 = (P(:,i-1)-P(:,i))/norm(P(:,i-1)-P(:,i));
%     n2 = (P(:,i+1)-P(:,i))/norm(P(:,i+1)-P(:,i));
%     
%     nWH = (n1+n2)/norm(n1+n2);  %Richtungsvektor der Winkelhalbierenden
%     
%     % WH plotten
%     
%     WH = P(:,i)+[-1:0.01:4].*nWH;
%     plot(WH(1,:),WH(2,:),'LineStyle','-.','Color',myGray50)
%       
%     
%     % Kreimittelpunkt berechnen
%     
%     
%     SP1 = P(:,i)+delta(i).*n1;
%     SP2 = P(:,i)+delta(i).*n2;
%     
%     nSenk1 = [0 1;-1 0]*n1;
%     nSenk2 = [0 1;-1 0]*n2;
%     
%     lambda = [-nSenk1 nSenk2]\(SP1-SP2);
%     
%     MP = SP1+lambda(1).*nSenk1;
%     MP2 = SP2+lambda(2).*nSenk2;
%     
% %     plot(SP1(1),SP1(2),'Marker','o','Color',myLineOne,'MarkerEdgeColor','black','MarkerFaceColor','black')
% %     plot(SP2(1),SP2(2),'Marker','o','Color',myLineOne,'MarkerEdgeColor','black','MarkerFaceColor','black')  
%     
%     %Kreis Plotten
%     plot(MP(1),MP(2),'Marker','o','Color',myLineOne,'MarkerEdgeColor','black','MarkerFaceColor','black')
%     
%     xval = SP1(1);
%     yval = SP1(2);
%     x = xval;
%     y = yval;
%     while xval < SP2(1)
%         xval = xval + 0.01;
%         if yval > MP(1)
%             yval = +sqrt(lambda(1)^2-(xval-MP(1))^2)+MP(2);
%         else
%             yval = -sqrt(lambda(1)^2-(xval-MP(1))^2)+MP(2);
%         end
%         
%         if imag(yval) == 0
%             x = [x, xval];
%             y = [y, yval];
%         end
%     end
%     x = [x,SP2(1)];
%     y = [y,SP2(2)];
%     
%     plot(x,y,'LineStyle','-','Color',myLineTwo)
%     
%     
%             
%             
% %     plot(MP2(1),MP2(2),'Marker','o','Color',myLineOne,'MarkerEdgeColor','black','MarkerFaceColor','black')
%     
% end
% 
% text(P(1,2)-0.7,P(2,2)-0.2,'$\delta_i$','Interpreter','none')
% text(P(1,3)-1.1,P(2,3)+0.3,'$\delta_{i+1}$','Interpreter','none')
% 
% plot(P(1,:),P(2,:),'LineStyle','-','Marker','o','Color',myLineOne,'MarkerEdgeColor','black','MarkerFaceColor','black','LineWidth',1,'MarkerSize',5)
% 
% xlabel('\figureXLabel')
% ylabel('\figureYLabel')
% 
% %%
% % a2 = polyfit(P(1,:),P(2,:),4);
% % y2 = polyval(a2,[-5:0.01:5]);
% % plot([-5:0.01:5],y2,'LineStyle','--','Color','red')
% 
% box on

matlab2tikz('filename','plot_nurbsgewichte.tex',...
     'height', '\figureheight', 'width', '\figurewidth', 'encoding', 'UTF8', 'showInfo', false, 'checkForUpdates', false, ...
     'parseStrings', false, ... % switch off LaTeX parsing by matlab2tikz for titles, axes labels etc. ("greater flexibility", "use straight LaTeX for your labels")
     'floatFormat', '%.4g', ... % limit precision to get smaller .tikz files
     'noSize', false);



hold off
% box off % Box um die figure herum ausblenden