How to color a contour of two curves?

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Khadija el 4 de Dic. de 2024 a las 21:39

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Comentada: Star Strider el 11 de Dic. de 2024 a las 13:55

contourcolor1.m

Hi, I'm trying to color a contour between two function curves, the problem is that just the two curves appear, without a colored contour. And this message appears when i am running.

Warning: Function behaves unexpectedly on array inputs. To improve performance, properly vectorize

your function to return an output with the same size and shape as the input arguments.

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Answer 1

Star Strider el 4 de Dic. de 2024 a las 23:27

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I am not certain what you want.

Try this —

% Diagramme de coexistence avec des contours colorés

% clc; clear; close all;

% Définir les limites des axes

Rs_min = 0; Rs_max = 5; % Intervalle pour Rs

Rh_min = 0; Rh_max = 5; % Intervalle pour Rh

% Générer une grille de points dans le plan (Rs, Rh)

[Rs, Rh] = meshgrid(linspace(Rs_min, Rs_max, 500), linspace(Rh_min, Rh_max, 500));

% Définir les seuils critiques

Rs1 = 1; % Seuil critique pour Rs

Rh1 = 1; % Seuil critique pour Rh

% Calculer les régions :

extinction = (Rs <= Rs1) & (Rh <= Rh1); % Dominace E_0

region1 = (Rs > Rs1) & (Rh <= Rh1); % Domination E*_1

region2 = (Rh > Rh1) & (Rs <= Rs1); % Domination E*_2

coexistence = (Rs > Rs1) & (Rh > Rh1); % Coexistence E*

% Créer une matrice de catégories pour les régions

regions = zeros(size(Rs));

regions(region1) = 1; % Code 1 : Domination Espèce E*_1

regions(region2) = 2; % Code 2 : Domination Espèce E*_2

regions(coexistence) = 3; % Code 3 : Coexistence E*

regions(extinction) = 4; % Code 4 : E_0

% Ajouter une relation entre R1 et R2 (par exemple, R2 = 1 / R1)

delta = 0.0001; % Taux de mortalité

delta_S = 0.0005; % Taux de mort de Syphilis.

delta_H = 0.00004;

Lambda =4.04 *100;

gamma=1.7;

phi_S =0.0006;

phi_H =0.00002;

c1 = 1;

c2=2 ;

theta1 =11 ;

theta2 = 5;

alpha = 0.4;

beta = 0.11;

rho1 = 0.5;

rho2= 1.5;

rho3=1.5;

y_1=gamma+delta+delta_S;

y_2=alpha+delta+delta_H;

y_4=rho1*gamma+rho2*alpha+delta+delta_S+delta_H;

m=delta./(delta+delta_S);

%expression de Rh en fonction de Rs

f = @(Rs) (((theta1*(Rs-1)*m*y_1+y_2)*y_4 )-theta1*(Rs-1)*m*y_1*rho1*gamma)/(((y_2*y_4)./ Rs)+c1*theta1*theta2*Rs*(1- 1 ./ Rs)^2* m^2*y_1*y_2+c1*theta2*m*(y_2)^2*(1- 1 ./ Rs)+rho1*gamma*theta2*m*(1- 1 ./ Rs)+c1*theta1*m*y_1*y_2*(1- 1 ./ Rs));

g=@(Rs) Rs*(theta2*delta*(Rs- 1 )+y_1)*y_4*y_2/(y_1*y_2*y_4+theta1*c2*delta*y_1* (Rs- 1 )*(theta2*delta*(Rs-1)+y_1)+theta2*c2*delta*(Rs-1)*y_1*y_2);

%t=@(Rs) Rs;

f_values = f(Rs); % Valeurs de la fonction `f` sur les points `x`

Warning: Matrix is singular, close to singular or badly scaled. Results may be inaccurate. RCOND = NaN.

g_values = g(Rs);% Valeurs de la fonction `g` sur les points `x`

Warning: Matrix is singular to working precision.

X = [Rs, fliplr(Rs)];

Y = [f_values, fliplr(g_values)];

% Afficher la formule de la fonction symbolique

disp('La formule de la fonction est :');

La formule de la fonction est :

disp(f);

@(Rs)(((theta1*(Rs-1)*m*y_1+y_2)*y_4)-theta1*(Rs-1)*m*y_1*rho1*gamma)/(((y_2*y_4)./Rs)+c1*theta1*theta2*Rs*(1-1./Rs)^2*m^2*y_1*y_2+c1*theta2*m*(y_2)^2*(1-1./Rs)+rho1*gamma*theta2*m*(1-1./Rs)+c1*theta1*m*y_1*y_2*(1-1./Rs))

disp(g);

@(Rs)Rs*(theta2*delta*(Rs-1)+y_1)*y_4*y_2/(y_1*y_2*y_4+theta1*c2*delta*y_1*(Rs-1)*(theta2*delta*(Rs-1)+y_1)+theta2*c2*delta*(Rs-1)*y_1*y_2)

%disp(t);

figure(1);

hold on;

fill(X, Y, 'cyan', 'FaceAlpha', 0.5, 'EdgeColor', 'none'); % Remplissage de la région

fp1 = fplot( f, [1, Rs_max], 'k-', 'LineWidth', 0.5);% Courbe Rh en fonction de Rs

Warning: Function behaves unexpectedly on array inputs. To improve performance, properly vectorize your function to return an output with the same size and shape as the input arguments.

fp2 = fplot( g, [1, Rs_max], 'r--', 'LineWidth', 0.5);%courbe Rs en fct Rh( on adaptant meme nota pour tracer la recipro

Warning: Function behaves unexpectedly on array inputs. To improve performance, properly vectorize your function to return an output with the same size and shape as the input arguments.

x1 = fp1.XData;

y1 = fp1.YData;

x2 = fp2.XData;

y2 = fp2.YData;

patch([x1 flip(x2)], [y1 flip(y2)], 'g') % Plot Green ‘patch’

%fplot( t, [1, Rs_max], 'b-', 'LineWidth', 0.5);

% Ajouter des lignes critiques

plot([Rs1 Rs1], [Rh_min Rh_max], 'k--', 'LineWidth', 0.5); % Ligne verticale Rs1

plot([Rs_min Rs_max], [Rh1 Rh1], 'k--', 'LineWidth', 0.5); % Ligne horizontale Rh1

% Ajuster l'apparence

xlabel('R_s');

ylabel('R_h');

hold off

.

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Star Strider el 8 de Dic. de 2024 a las 18:31

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As always, my pleasure!

First, the ‘secret’ of using the patch function is to create a closed curve. This means that the ‘x’ values must go first in one direction, then turn back essentiially to the beginning So for example, that would be [1 2 3] for ‘x1’, and then the flip function would reverse ‘x2’. So [x1 flip(x2)] in this example would produce [1 2 3 5 4 2] for the ‘x’ vector argument to patch. The ‘y’ vector argument has to do the same sort of thing, for example [0 2 3] and then since those values would be expected to be different, the second vector would be the flipped version of [5 9 8] that being [8 9 5]. (None of the vectors need to have the same values as the others..) The patch function will connect any unconnected lines at the ends, so there is no need to do that specifically in your code.

To write someething in that region would use the text function. (I also use the compose function here.)

Combining both of those in this example —

x1 = [1 2 3];

y1 = [0 2 3];

x2 = [2 4 5];

y2 = [5 9 8];

figure

patch([x1 flip(x2)], [y1 flip(y2)], 'g')

grid

axis('padded')

c = compose('(%.1f, %.1f)', [[x1 flip(x2)]; [y1 flip(y2)]].') % Create A Cell Array To Use With ‘text’

c = 6x1 cell array

{'(1.0, 0.0)'} {'(2.0, 2.0)'} {'(3.0, 3.0)'} {'(5.0, 8.0)'} {'(4.0, 9.0)'} {'(2.0, 5.0)'}

text([x1 flip(x2)], [y1 flip(y2)], c, HorizontalAlignment='left', VerticalAlignment='middle')

text(2.2, 3.5, "Completed ‘patch’ Plot", FontWeight='bold', Color='r', Rotation=35)

xlabel('X')

ylabel('Y')

title('Example ‘patch’ Plot Also Using ‘text’')

This should give you an idea of how the patch function works, and how to print text on the patch.

.

Star Strider el 8 de Dic. de 2024 a las 23:57

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As always, my pleasure!

This comnand:

text([x1 flip(x2)], [y1 flip(y2)], c, HorizontalAlignment='left', VerticalAlignment='middle')

plots the coordinate values next to the plotted points.

Adding arrows makes the approach more understandable —

x1 = [1 2 3];

y1 = [0 2 3];

x2 = [2 4 5];

y2 = [5 9 8];

figure

patch([x1 flip(x2)], [y1 flip(y2)], 'g')

grid

axis('padded')

c = compose('(%.1f, %.1f)', [[x1 flip(x2)]; [y1 flip(y2)]].') % Create A Cell Array To Use With ‘text’

c = 6x1 cell array

{'(1.0, 0.0)'} {'(2.0, 2.0)'} {'(3.0, 3.0)'} {'(5.0, 8.0)'} {'(4.0, 9.0)'} {'(2.0, 5.0)'}

text([x1 flip(x2)], [y1 flip(y2)], c, HorizontalAlignment='left', VerticalAlignment='middle')

text(2.2, 3.5, "Completed ‘patch’ Plot", FontWeight='bold', Color='r', Rotation=35)

xlabel('X')

ylabel('Y')

title('Example ‘patch’ Plot Also Using ‘text’')

xapf = @(x,pos,xl) pos(3)*(x-min(xl))/diff(xl)+pos(1); % 'x' Annotation Position Function

yapf = @(y,pos,yl) pos(4)*(y-min(yl))/diff(yl)+pos(2); % 'y' Annotation Position Function

xl = xlim;

yl = ylim;

pos = gca().Position;

xv = [x1 flip(x2) x1(1)];

yv = [y1 flip(y2) y1(1)];

for k = 1:numel(xv)-1

annotation('arrow', xapf([xv(k) xv(k+1)],pos,xlim), yapf([yv(k) yv(k+1)],pos,ylim))

end

The annotation arrows demonstrate the approach to creating the patch object. This creates a continuous closed region, going in the direction of the arrows.

.

Star Strider el 9 de Dic. de 2024 a las 12:23

Editada: Star Strider el 9 de Dic. de 2024 a las 13:23

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As always, my pleasure!

For the circle (or ellipse), see Create Ellipse Annotation and use:

xapf = @(x,pos,xl) pos(3)*(x-min(xl))/diff(xl)+pos(1); % 'x' Annotation Position Function

yapf = @(y,pos,yl) pos(4)*(y-min(yl))/diff(yl)+pos(2); % 'y' Annotation Position Function

xl = xlim;

yl = ylim;

pos = gca().Position;

similarly to tthe way I did it to create the ellipse or circle.

Also see Ellipse Properties since the arguments are not as straightforward as I initially thought they would be.

Illustrating —

x1 = [1 2 3];

y1 = [0 2 3];

x2 = [2 4 5];

y2 = [5 9 8];

figure

patch([x1 flip(x2)], [y1 flip(y2)], 'g')

grid

axis('padded')

% c = compose('(%.1f, %.1f)', [[x1 flip(x2)]; [y1 flip(y2)]].') % Create A Cell Array To Use With ‘text’

% text([x1 flip(x2)], [y1 flip(y2)], c, HorizontalAlignment='left', VerticalAlignment='middle')

text(2.2, 3.5, "Completed ‘patch’ Plot", FontWeight='bold', Color='r', Rotation=35)

xlabel('X')

ylabel('Y')

title('Example ‘patch’ Plot Also Using ‘text’')

xapf = @(x,pos,xl) pos(3)*(x-min(xl))/diff(xl)+pos(1); % 'x' Annotation Position Function

yapf = @(y,pos,yl) pos(4)*(y-min(yl))/diff(yl)+pos(2); % 'y' Annotation Position Function

xl = xlim;

yl = ylim;

pos = gca().Position;

annotation('ellipse', [xapf(2.2,pos,xlim), yapf(2.0,pos,ylim) 0.4 0.2], Rotation=35, Color='r', LineWidth=2)

Note that the second argument to the annotation function to create an ellipse is:

[left x-coordinate, lower y-coordinate, width, height]

so you can use ‘xapf’ and ‘yapf’ for the first two (these are correct before rotating it), however you do not necessarily have to use them to create the last two. You will simply have to experiment with the last two to get the result you want. I suggest initially creating it without the rotatioon, then add the rotation and tweak the arguments to get the result you want. The last two elements in that vector control the aspect ratio, so make them equal to create a circle, and different to create an ellipse.

EDIT — (9 Dec 2024 at 13:23)

You can also use my functions to create a realistic aspect ratio, and to correct the coordinates iif you rotate it —

x1 = [1 2 3];

y1 = [0 2 3];

x2 = [2 4 5];

y2 = [5 9 8];

figure

patch([x1 flip(x2)], [y1 flip(y2)], 'g')

grid

axis('padded')

% c = compose('(%.1f, %.1f)', [[x1 flip(x2)]; [y1 flip(y2)]].') % Create A Cell Array To Use With ‘text’

% text([x1 flip(x2)], [y1 flip(y2)], c, HorizontalAlignment='left', VerticalAlignment='middle')

text(2.2, 3.5, "Completed ‘patch’ Plot", FontWeight='bold', Color='r', Rotation=35)

xlabel('X')

ylabel('Y')

title('Example ‘patch’ Plot Also Using ‘text’')

xapf = @(x,pos,xl) pos(3)*(x-min(xl))/diff(xl)+pos(1); % 'x' Annotation Position Function

yapf = @(y,pos,yl) pos(4)*(y-min(yl))/diff(yl)+pos(2); % 'y' Annotation Position Function

xl = xlim;

yl = ylim;

pos = gca().Position;

annotation('ellipse', [xapf(2.2,pos,xlim), yapf(3.5*sind(35),pos,ylim) diff(xapf([2.2 4.2]/cosd(35),pos,xlim)), diff(yapf([1 3]/cosd(35),pos,ylim))], Rotation=35, Color='r', LineWidth=2)

The trigonometric function arguments are the same as the Rotation argument.

If you do not rotate the ellipse, use this annotation call instead:

annotation('ellipse', [xapf(2.2,pos,xlim), yapf(3.5,pos,ylim) diff(xapf([2.2 4.0],pos,xlim)), diff(yapf([1 3],pos,ylim))], Color='r', LineWidth=2)

It may be necessary to tweak the first element of the vector( the x-coordinate of the ellipse) to positiion it correctly. The last two elements in the vector (that define the aspect ratio) are now defined in terms of the x and y units of the plot.

.

Star Strider el 10 de Dic. de 2024 a las 19:54

The ‘xapf’ and ‘yapf’ functions take the values derived from the figure and calculate normalised coordinate values that are calcualted from the ‘x’ and ‘y’ values you provide to them.

I defined the functions (anonymous functions) first, then some of their arguments. The ‘pos’ argument is determined by the Position property of the figure. The other two (‘xl’ and ‘yl’) are the respective axis limits, also derived from the figure. The annotation call then uses their results (outputs), calculated from the ‘x’ and ‘y’ values that you define. Once the ‘xapf’ and ‘yapf’ functions and their argumeents are defined, you only need to call the ‘xapf’ and ‘yapf’ functions in subsequent annotation calls for each figure.

Please consult the annotation documentation, because (as I learned while doing this), different annotation types have different argument requirements. Some simply require the relevant ‘x’ and ‘y’ values (normalised as calculated by ‘xapf’ and ‘yapf’) and others (such as 'ellipse'), require ‘x’ and ‘y’ values for the first two arguments, and width and height relative values for the last two.

.

Star Strider el 11 de Dic. de 2024 a las 0:55

As always, my pleasure!

You questions are definitely not stupid!

The ‘x’ and ‘y’ values the annotation('ellipse', ... ) call uses are the same as the starting position of the “Completed ‘patch’ plot” text object, however the resemblance ends there (and that does not always have to be the situation, it just works here). The ‘x’ and ‘y’ values and ‘pos’ are not the same.

The ‘pos’ argument provides the ‘Position’ property of the axes using the gca (get current axes) function. the xlim and ylim calls return the axis limits and provide them to the ‘xapf’ and ‘‘yapf’ as well, since the functions need all that information to calculate the normalizsed coordinates that the annotation object uses. You can see how the ‘xapf’ and ‘‘yapf’ functions use those arguments by looking at theiir codes (that are essentially the same). My functions scale the ‘x’ and ‘y’ values you give them, using the other arguments, to provide the normalised coordinates in the axes that the annotation function needs.

.

Khadija el 11 de Dic. de 2024 a las 13:29

Thank you so much!!

I solved the problem, your instructions were very helpful, you are an angel!!

Star Strider el 11 de Dic. de 2024 a las 13:55

As always, my pleasure!

I very much appreciate your compliment!

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How to color a contour of two curves?

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