I have an assignment to render a torus. This is my first time with matlab and i've managed to struggle along and get 2/3 parts done with some horrible kludged code.
The first step of the assignment is to render a circle as a set of 20 points. For which i produced:
Then the next step is to rotate and translate that circle and draw it 20 times to represent a torus shape, so i got this:
torus points (IMG)
The next step is to render a 3d representation of this torus from the list of vertices.
What I have is massive a list of a vertices in a 400x3 matrix like so:
7.66478245119846 -1.84059939326890 0.292371704722737 7.53434247103331 -1.79821687453702 0.573576436351046 7.32764268084884 -1.73105604149887 0.798635510047293 7.06491629627043 -1.64569106442929 0.945518575599317 6.77188080634298 -1.55047806205660 0.999847695156391 6.47722056651889 -1.45473714644104 0.956304755963036 ... ... ...
where each subsequent 20 rows is another circle.
The assignment recommends that I use the surf function in order to render this but I can't figure out how. All the examples I've seen use surf to represent 2 dimensional planes that get distorted by a height value. Which doesn't seem appropriate for rendering this kind of 3 dimensional shape at all.
The approach I'm trying is to build a list of faces and then using the patch function to render the circle. Where the first 2 points of each circle makes a square with the corresponding 2 points of the next circle, then rendering.
Using something like this:
for i=1:400 face = [(i) (i+1) (i+21) (i+20)]; patch('Faces',face,'Vertices',torus_vertices,'FaceColor','r'); %Should do this at the end end
For which i get something like this:
3d Torus (IMG)
It twists and and some of the side and inner side faces are messed up. I think it might have something to do with the ordering of the vertices flipping around at some point.
What would be the best way to approach this problem? If at all possible i want to do it with the surf function.
%Initial positions position = [2 0 0]; normal = [0 1 0]; %Rotation matrix rotate18 = [cos(todeg(18)) -sin(todeg(18)) 0; sin(todeg(18)) cos(todeg(18)) 0; 0 0 1]; % translate along the x axis by 5 translate = [5 0 0]; %% iterate 20 times to get a list of all the vertices taurus_vertices = zeros(0, 3); for i=0:20 %rotate translation by 18 degrees translate = translate * rotate18; %translate position = position + translate; %rotate the normal so it faces the right direction normal = normal * rotate18; %Get vertices for the circle and append to vertices list circle_vertices = circle_3D(1, position, normal); taurus_vertices = cat(1, taurus_vertices, circle_vertices); %translate back to original position position = position - translate; end %scatter3(taurus_vertices(1:end, 1), taurus_vertices(1:end, 2), taurus_vertices(1:end, 3)); %% Render each face for i=1:400 face = [(i) (i+1) (i+21) (i+20)]; patch('Faces',face,'Vertices',taurus_vertices,'FaceColor','r'); end
function h_circle=circle_3D(r, M, n) %% Prepare input parameters if size(n,2)>size(n,1) n=n'; end if size(M,2)>size(M,1) M=M'; end %% Define unit vectors u and v % u and v define a new coordinate system in a plane perpendicular to n a=[1;0;0]; b=[0;1;0]; if isempty(find(cross(a,n), 1))==1 a=[0;0;1]; elseif isempty(find(cross(b,n), 1))==1 b=[0;0;1]; end alpha=dot(n,a)/dot(n,n); u=a-alpha*n; v=cross(u,n);%b-beta*n-gamma*u; u=u/sqrt(sum(u.*u)); v=v/sqrt(sum(v.*v)); %% Plot the circle hold on axis equal degs = 0; points = 0; verts = zeros(20, 3); for phi=0: pi()/180 : 2*pi() degs=degs+1; if (mod(degs,18) == 0 ) points = points + 1; verts(points,1)=M(1,1)+r*cos(phi)*u(1,1)+r*sin(phi)*v(1,1); verts(points,2)=M(2,1)+r*cos(phi)*u(2,1)+r*sin(phi)*v(2,1); verts(points,3)=M(3,1)+r*cos(phi)*u(3,1)+r*sin(phi)*v(3,1); end end h_circle= verts;