How do I shade the xy plane at z=0 of my plot and how to stop the plot after it passes z=0?

1 vue (au cours des 30 derniers jours)
Noah Wilson
Noah Wilson le 9 Déc 2019
Modifié(e) : Adam Danz le 9 Déc 2019
I have the following code:
t = 0:0.0001:20; %time
m = 0.4; %mass (kg)
g = 9.8; %gravitational accel. (m/s^2)
b = 0.44; %drag coefficient
w_1 = 10; %Angular Velocity
w_2 = 8; %Angular Velocity
w_3 = 5; %Angular Velocity
x_t_1 = (2349.*m)./(100.*b) - (2349.*m.*exp(-(b.*t)./m))./(100.*b);
y_t_1 = (g.*m.*t.*w_1)./(b.^2 + w_1.^2) - (171.*b.^2.*m.*w_1)./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) - (171.*m.*w_1.^3)./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) - (2.*b.*g.*m.^2.*w_1)./(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4) + (171.*b.^3.*m.*exp(-(b.*t)./m).*sin((t.*w_1)./m))./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) + (171.*m.*w_1.^3.*exp(-(b.*t)./m).*cos((t.*w_1)./m))./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) + (171.*b.^2.*m.*w_1.*exp(-(b.*t)./m).*cos((t.*w_1)./m))./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) + (171.*b.*m.*w_1.^2.*exp(-(b.*t)./m).*sin((t.*w_1)./m))./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) + (b.^2.*g.*m.^2.*exp(-(b.*t)./m).*sin((t.*w_1)./m))./(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4) - (g.*m.^2.*w_1.^2.*exp(-(b.*t)./m).*sin((t.*w_1)./m))./(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4) + (2.*b.*g.*m.^2.*w_1.*exp(-(b.*t)./m).*cos((t.*w_1)./m))./(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4);
z_t_1 = (171.*b.^3.*m)./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) + (171.*b.*m.*w_1.^2)./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) + (b.^2.*g.*m.^2)./(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4) - (g.*m.^2.*w_1.^2)./(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4) - (b.*g.*m.*t)./(b.^2 + w_1.^2) - (171.*b.^3.*m.*exp(-(b.*t)./m).*cos((t.*w_1)./m))./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) + (171.*m.*w_1.^3.*exp(-(b.*t)./m).*sin((t.*w_1)./m))./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) - (171.*b.*m.*w_1.^2.*exp(-(b.*t)./m).*cos((t.*w_1)./m))./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) + (171.*b.^2.*m.*w_1.*exp(-(b.*t)./m).*sin((t.*w_1)./m))./(20.*(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4)) - (b.^2.*g.*m.^2.*exp(-(b.*t)./m).*cos((t.*w_1)./m))./(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4) + (g.*m.^2.*w_1.^2.*exp(-(b.*t)./m).*cos((t.*w_1)./m))./(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4) + (2.*b.*g.*m.^2.*w_1.*exp(-(b.*t)./m).*sin((t.*w_1)./m))./(b.^4 + 2.*b.^2.*w_1.^2 + w_1.^4);
x_t_2 = (2349.*m)./(100.*b) - (2349.*m.*exp(-(b.*t)./m))./(100.*b);
y_t_2 = (g.*m.*t.*w_2)./(b.^2 + w_2.^2) - (171.*b.^2.*m.*w_2)./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) - (171.*m.*w_2.^3)./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) - (2.*b.*g.*m.^2.*w_2)./(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4) + (171.*b.^3.*m.*exp(-(b.*t)./m).*sin((t.*w_2)./m))./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) + (171.*m.*w_2.^3.*exp(-(b.*t)./m).*cos((t.*w_2)./m))./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) + (171.*b.^2.*m.*w_2.*exp(-(b.*t)./m).*cos((t.*w_2)./m))./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) + (171.*b.*m.*w_2.^2.*exp(-(b.*t)./m).*sin((t.*w_2)./m))./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) + (b.^2.*g.*m.^2.*exp(-(b.*t)./m).*sin((t.*w_2)./m))./(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4) - (g.*m.^2.*w_2.^2.*exp(-(b.*t)./m).*sin((t.*w_2)./m))./(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4) + (2.*b.*g.*m.^2.*w_2.*exp(-(b.*t)./m).*cos((t.*w_2)./m))./(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4);
z_t_2 = (171.*b.^3.*m)./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) + (171.*b.*m.*w_2.^2)./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) + (b.^2.*g.*m.^2)./(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4) - (g.*m.^2.*w_2.^2)./(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4) - (b.*g.*m.*t)./(b.^2 + w_2.^2) - (171.*b.^3.*m.*exp(-(b.*t)./m).*cos((t.*w_2)./m))./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) + (171.*m.*w_2.^3.*exp(-(b.*t)./m).*sin((t.*w_2)./m))./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) - (171.*b.*m.*w_2.^2.*exp(-(b.*t)./m).*cos((t.*w_2)./m))./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) + (171.*b.^2.*m.*w_2.*exp(-(b.*t)./m).*sin((t.*w_2)./m))./(20.*(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4)) - (b.^2.*g.*m.^2.*exp(-(b.*t)./m).*cos((t.*w_2)./m))./(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4) + (g.*m.^2.*w_2.^2.*exp(-(b.*t)./m).*cos((t.*w_2)./m))./(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4) + (2.*b.*g.*m.^2.*w_2.*exp(-(b.*t)./m).*sin((t.*w_2)./m))./(b.^4 + 2.*b.^2.*w_2.^2 + w_2.^4);
x_t_3 = (2349.*m)./(100.*b) - (2349.*m.*exp(-(b.*t)./m))./(100.*b);
y_t_3 = (g.*m.*t.*w_3)./(b.^2 + w_3.^2) - (171.*b.^2.*m.*w_3)./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) - (171.*m.*w_3.^3)./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) - (2.*b.*g.*m.^2.*w_3)./(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4) + (171.*b.^3.*m.*exp(-(b.*t)./m).*sin((t.*w_3)./m))./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) + (171.*m.*w_3.^3.*exp(-(b.*t)./m).*cos((t.*w_3)./m))./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) + (171.*b.^2.*m.*w_3.*exp(-(b.*t)./m).*cos((t.*w_3)./m))./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) + (171.*b.*m.*w_3.^2.*exp(-(b.*t)./m).*sin((t.*w_3)./m))./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) + (b.^2.*g.*m.^2.*exp(-(b.*t)./m).*sin((t.*w_3)./m))./(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4) - (g.*m.^2.*w_3.^2.*exp(-(b.*t)./m).*sin((t.*w_3)./m))./(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4) + (2.*b.*g.*m.^2.*w_3.*exp(-(b.*t)./m).*cos((t.*w_3)./m))./(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4);
z_t_3 = (171.*b.^3.*m)./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) + (171.*b.*m.*w_3.^2)./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) + (b.^2.*g.*m.^2)./(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4) - (g.*m.^2.*w_3.^2)./(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4) - (b.*g.*m.*t)./(b.^2 + w_3.^2) - (171.*b.^3.*m.*exp(-(b.*t)./m).*cos((t.*w_3)./m))./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) + (171.*m.*w_3.^3.*exp(-(b.*t)./m).*sin((t.*w_3)./m))./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) - (171.*b.*m.*w_3.^2.*exp(-(b.*t)./m).*cos((t.*w_3)./m))./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) + (171.*b.^2.*m.*w_3.*exp(-(b.*t)./m).*sin((t.*w_3)./m))./(20.*(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4)) - (b.^2.*g.*m.^2.*exp(-(b.*t)./m).*cos((t.*w_3)./m))./(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4) + (g.*m.^2.*w_3.^2.*exp(-(b.*t)./m).*cos((t.*w_3)./m))./(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4) + (2.*b.*g.*m.^2.*w_3.*exp(-(b.*t)./m).*sin((t.*w_3)./m))./(b.^4 + 2.*b.^2.*w_3.^2 + w_3.^4);
plot3(x_t_1, y_t_1, z_t_1)
hold on
plot3(x_t_2, y_t_2, z_t_2)
plot3(x_t_3, y_t_3, z_t_3)
xlabel('X')
ylabel('Y')
zlabel('Z')
legend('\omega = 10 rad/s', '\omega = 8 rad/s', '\omega = 5 rad/s')
hold off
I would like to shade the xy plane at z=0 to make the plot more visually appealing but I am not sure how to do this. I also only need the portion of each individual plot that appears before it goes below z=0 again. This plot is the trajectory of a soccer ball and at z=0 is the ground so mathematically the plots continue below z=0 but realistically this is not the case and I am not sure how to set this limit. Thank you in advanced for your help!

Connectez-vous pour répondre à cette question.

Réponse acceptée

Adam Danz
Adam Danz le 9 Déc 2019
Modifié(e) : Adam Danz le 9 Déc 2019
The easiest solution is simply
zlim([0,inf])
I also added grid on so we can see the 3D coordinates better. However, the data below z=0 still exist; you just can't see it.
Another approach would be to simply replace unwanted data with NaN.
idx = z_t_1 > 0;
x_t_1(~idx) = NaN;
x_t_1(~idx) = NaN;
z_t_1(~idx) = NaN;
plot3(x_t_1, y_t_1, z_t_1)
And another approach is to split the data up into groups that 'bounce' above the z=0 axis. There's more than one way to do that. This appoach requires the image processing toolbox due to the use of bwlabel().
bwidx = bwlabel(z_t_1 > 0); % group the sections above z=0
splitGroups = @(data)splitapply(@(x){x},data(bwidx>0).',findgroups(bwidx(bwidx>0)).'); % Function that splits the data
axes();
hold on
cellfun(@plot3, splitGroups(x_t_1), splitGroups(y_t_1), splitGroups(z_t_1))
view(3)

Plus de réponses (0)

Catégories

En savoir plus sur Line Plots dans Help Center et File Exchange

Tags

Produits


Version

R2019a

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by