The issue is that you want the noise to have a certain characteristic. You have many samples along the curve, and you'd like it to stay "connected". You'd like fairly smooth results, and you want the curve to stay closed. So, in order: random walk noise will keep the points connected. Low-pass-filtered noise will keep the curve smooth. And fix the noise endpoint to be zero (smoothly) to ensure a closed result. Here's some code that generates 16 different kinds of noise (4x4), varying the overall scale and the overall amount of filtering. You'll have to adjust both of these choices based on the "sample rate" of your data, and the overall scale of the shape.

```
% Generate sample data
[x,y] = pol2cart(0:0.01:2*pi, 1);
% Pick a set of 4 noise scale, and noise filter values
scales = [.01 .05 .1 .5];
filterstrength = [.1 .5 .9 .98];
% Plot a 4x4 grid, picking a different type of noise for each one
for i=1:4
for j=1:4
scale = scales(i);
f = filterstrength(j);
% Generate noise for x and y, by filtering a std 1 gaussian random
% walk
nx = filter(scale*(1-f), [1 -f], cumsum(randn(size(x))));
ny = filter(scale*(1-f), [1 -f], cumsum(randn(size(y))));
% We want a closed polygon, so "detrend" the result so that
% the last point is the same as the first point
nx = nx - linspace(0,1,length(nx)).*(nx(end)-nx(1));
ny = ny - linspace(0,1,length(ny)).*(ny(end)-ny(1));
subplot(4,4,4*(i-1)+j);
% Add the noise
plot(x+nx,y+ny);
end
end
```

Other things you could vary: You have nearly infinite choices for the filter shape, which will affect the style of deformation.

`coord = coord + A*rand(1)`

.`A`

is defined as your confidence interval: the higher`A`

, the higher the noise, the larger the deformation. In this way you limit the movement of your particle, as if you are setting a leash. THis is done for both the coordinates, so as to make the particle move in the neighborhood. – Eleanore Jul 25 '13 at 13:35