This can do the job..

```
t = 0:4/5*pi:4*pi;
x = sin(t);
y = cos(t) ;
y = y-mean(y);
x = x-mean(x); % # barycentric coordinates
% # rotation and translation
trasl = @(dx,dy) [dy; dx]; % # this vector will be rigidly added to each point of the system
rot = @(theta) [cos(theta) -sin(theta); sin(theta) cos(theta)]; % # this will provide rotation of angle theta
for i = 1:50
% # application of the roto-translation
% # a diagonal translation of x = i*.1 , y = i*.1 is added to the star
% # once a rotation of angle i*pi/50 is performed
x_t = bsxfun(@plus,rot(i*pi/50)*([x;y]), trasl(i*.1,i*.1) );
star = plot(x_t(1,:), x_t(2,:));
axis([-1 11 -1 11])
pause(.1)
end
```

In principle, **homogeneous coordinates** (in this case in the *2D projective space*) allow one to do the same job in a neater way; in fact, they would allow one to use just one linear operator (3x3 matrix).

Homogeneous coordinates version:

```
Op = @(theta,dx,dy) [ rot(theta) , trasl(dx,dy) ; 0 0 1];
for i = 1:50
x_t = Op(i*pi/50,i*.1,i*.1)*[x;y;ones(size(x))];
star = plot(x_t(1,:), x_t(2,:));
axis([-1 11 -1 11])
pause(.1)
end
```