Algorithm to generate random 2D polygon

I'm not sure how to approach this problem. I'm not sure how complex a task it is. My aim is to have an algorithm that generates any polygon. My only requirement is that the polygon is not complex (i.e. sides do not intersect). I'm using Matlab for doing the maths but anything abstract is welcome.

Any aid/direction?

EDIT:

I was thinking more of code that could generate any polygon even things like this:

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What do you mean by "random?" Do you know anything about the distribution you're trying to generate? –  templatetypedef Jan 25 '12 at 2:18
@templatetypedef Apparently he wants an algorithm that produces random simple polygons, since in general taking an arbitrary order of n points will also produce self-intersecting polygons. –  Jorge Jan 25 '12 at 2:45
put random number of points in random positions on circle with random radius and connect them consecutive? –  dfens Jan 25 '12 at 11:18
Such a polygon has a name - simple polygon, actually. –  Sibbs Gambling Jul 1 '14 at 18:52

Note: I've updated my answer with a solution that simply takes as input a desired number of sides for the polygon, instead of a couple of non-intuitive "magic numbers" like I had before...

There's a neat way to do what you want by taking advantage of the MATLAB classes DelaunayTri and TriRep and the various methods they employ for handling triangular meshes. The code below follows these steps to create an arbitrary simple polygon:

• Generate a number of random points equal to the desired number of sides plus a fudge factor. The fudge factor ensures that, regardless of the result of the triangulation, we should have enough facets to be able to trim the triangular mesh down to a polygon with the desired number of sides.

• Create a Delaunay triangulation of the points, resulting in a convex polygon that is constructed from a series of triangular facets.

• If the boundary of the triangulation has more edges than desired, pick a random triangular facet on the edge that has a unique vertex (i.e. the triangle only shares one edge with the rest of the triangulation). Removing this triangular facet will reduce the number of boundary edges.

• If the boundary of the triangulation has fewer edges than desired, or the previous step was unable to find a triangle to remove, pick a random triangular facet on the edge that has only one of its edges on the triangulation boundary. Removing this triangular facet will increase the number of boundary edges.

• If no triangular facets can be found matching the above criteria, post a warning that a polygon with the desired number of sides couldn't be found and return the x and y coordinates of the current triangulation boundary. Otherwise, keep removing triangular facets until the desired number of edges is met, then return the x and y coordinates of triangulation boundary.

Here's the resulting function:

``````function [x, y, dt] = simple_polygon(numSides)

if numSides < 3
x = [];
y = [];
dt = DelaunayTri();
return
end

oldState = warning('off', 'MATLAB:TriRep:PtsNotInTriWarnId');

fudge = ceil(numSides/10);
x = rand(numSides+fudge, 1);
y = rand(numSides+fudge, 1);
dt = DelaunayTri(x, y);
boundaryEdges = freeBoundary(dt);
numEdges = size(boundaryEdges, 1);

while numEdges ~= numSides
if numEdges > numSides
triIndex = vertexAttachments(dt, boundaryEdges(:,1));
triIndex = triIndex(randperm(numel(triIndex)));
keep = (cellfun('size', triIndex, 2) ~= 1);
end
if (numEdges < numSides) || all(keep)
triIndex = edgeAttachments(dt, boundaryEdges);
triIndex = triIndex(randperm(numel(triIndex)));
triPoints = dt([triIndex{:}], :);
keep = all(ismember(triPoints, boundaryEdges(:,1)), 2);
end
if all(keep)
warning('Couldn''t achieve desired number of sides!');
break
end
triPoints = dt.Triangulation;
triPoints(triIndex{find(~keep, 1)}, :) = [];
dt = TriRep(triPoints, x, y);
boundaryEdges = freeBoundary(dt);
numEdges = size(boundaryEdges, 1);
end

boundaryEdges = [boundaryEdges(:,1); boundaryEdges(1,1)];
x = dt.X(boundaryEdges, 1);
y = dt.X(boundaryEdges, 2);

warning(oldState);

end
``````

And here are some sample results:

The generated polygons could be either convex or concave, but for larger numbers of desired sides they will almost certainly be concave. The polygons are also generated from points randomly generated within a unit square, so polygons with larger numbers of sides will generally look like they have a "squarish" boundary (such as the lower right example above with the 50-sided polygon). To modify this general bounding shape, you can change the way the initial `x` and `y` points are randomly chosen (i.e. from a Gaussian distribution, etc.).

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+1 As it's a good answer though there's another condition you have to check. If you are removing a triangle with just one edge on the hull, you have to make sure that the opposing vertex is not on the hull, or you'll end up with two polygons with one common point. –  Shane MacLaughlin Sep 10 '12 at 14:37
@Shane: That situation is already accounted for in the code above. The line `keep = all(ismember(triPoints, boundaryEdges(:,1)), 2);` marks a triangle to be kept if all of its vertices lie on the free boundary, which is the case if a triangle has both one edge and the opposing vertex on the free boundary. This kind of triangle will never be removed from the triangulation, avoiding splitting of the polygon in two. –  gnovice Sep 10 '12 at 15:22

For a convex 2D polygon (totally off the top of my head):

1. Generate a random radius, R

2. Generate N random points on the circumference of a circle of Radius R

3. Move around the circle and draw straight lines between adjacent points on the circle.

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To generate more arbitrary polygons, pick a center point, a random set of angles, and for each angle a radius, then connect these points in sequence. –  templatetypedef Jan 25 '12 at 3:06
I might also add that in general, the problem is finding a non intersecting hamiltonian cycle on a graph. Apparently there are (n-1)!/2 such cycles for a n-vertex graph, meaning that n random points define (n-1)!/2 different polygons. If you have a function that detects whether two edges intersect (which is very easy), then you can randomly pick up a point, randomly pick another, test whether this edges intersects with existing edges or not and keep/reject the point and so on. This way you can create general random polygons on the plane. –  Jorge Jan 25 '12 at 3:39

As @templatetypedef and @MitchWheat said, it is easy to do so by generating `N` random angles and radii. It is important to sort the angles, otherwise it will not be a simple polygon. Note that I am using a neat trick to draw closed curves - I described it in here. By the way, the polygons might be concave.

Note that all of these polygons will be star shaped. Generating a more general polygon is not a simple problem at all. Just to give you a taste of the problem - check out http://www.cosy.sbg.ac.at/~held/projects/rpg/rpg.html and http://compgeom.cs.uiuc.edu/~jeffe/open/randompoly.html.

``````function CreateRandomPoly()
figure();
colors = {'r','g','b','k'};
for i=1:5
[x,y]=CreatePoly();
c = colors{ mod(i-1,numel(colors))+1};
plotc(x,y,c);
hold on;
end
end

function [x,y]=CreatePoly()
numOfPoints = randi(30);
theta = randi(360,[1 numOfPoints]);
theta = theta * pi / 180;
theta = sort(theta);
rho = randi(200,size(theta));
[x,y] = pol2cart(theta,rho);
xCenter = randi([-1000 1000]);
yCenter = randi([-1000 1000]);
x = x + xCenter;
y = y + yCenter;
end

function plotc(x,y,varargin)
x = [x(:) ; x(1)];
y = [y(:) ; y(1)];
plot(x,y,varargin{:})
end
``````
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Although it's a great answer and I upvote it, I doubt it can produce the polygon in OP's example, when mass center might be outside of polygon area. –  yuk Jan 25 '12 at 16:36
@yuk, you are definitely right. I've updated my answer –  Andrey Jan 25 '12 at 17:53

I took @MitchWheat and @templatetypedef's idea of sampling points on a circle and took it a bit farther.

In my application I need to be able to control how weird the polygons are, ie start with regular polygons and as I crank up the parameters they get increasingly chaotic. The basic idea is as stated by @templatetypedef; walk around the circle taking a random angular step each time, and at each step put a point at a random radius. In equations I'm generating the angular steps as

where theta_i and r_i give the angle and radius of each point relative to the centre, U(min, max) pulls a random number from a uniform distribution, and N(mu, sigma) pulls a random number from a Gaussian distribution, and clip(x, min, max) thresholds a value into a range. This gives us two really nice parameters to control how wild the polygons are - epsilon which I'll call irregularity controls whether or not the points are uniformly space angularly around the circle, and sigma which I'll call spikeyness which controls how much the points can vary from the circle of radius r_ave. If you set both of these to 0 then you get perfectly regular polygons, if you crank them up then the polygons get crazier.

I whipped this up quickly in python and got stuff like this:

Here's the full python code:

``````import math, random

def generatePolygon( ctrX, ctrY, aveRadius, irregularity, spikeyness, numVerts ) :
then creates the polygon by sampling points on a circle around the centre.
Randon noise is added by varying the angular spacing between sequential points,
and by varying the radial distance of each point from the centre.

Params:
ctrX, ctrY - coordinates of the "centre" of the polygon
aveRadius - in px, the average radius of this polygon, this roughly controls how large the polygon is, really only useful for order of magnitude.
irregularity - [0,1] indicating how much variance there is in the angular spacing of vertices. [0,1] will map to [0, 2pi/numberOfVerts]
spikeyness - [0,1] indicating how much variance there is in each vertex from the circle of radius aveRadius. [0,1] will map to [0, aveRadius]
numVerts - self-explanatory

Returns a list of vertices, in CCW order.
'''

irregularity = clip( irregularity, 0,1 ) * 2*math.pi / numVerts
spikeyness = clip( spikeyness, 0,1 ) * aveRadius

# generate n angle steps
angleSteps = []
lower = (2*math.pi / numVerts) - irregularity
upper = (2*math.pi / numVerts) + irregularity
sum = 0
for i in range(numVerts) :
tmp = random.uniform(lower, upper)
angleSteps.append( tmp )
sum = sum + tmp

# normalize the steps so that point 0 and point n+1 are the same
k = sum / (2*math.pi)
for i in range(numVerts) :
angleSteps[i] = angleSteps[i] / k

# now generate the points
points = []
angle = random.uniform(0, 2*math.pi)
for i in range(numVerts) :
x = ctrX + r_i*math.cos(angle)
y = ctrY + r_i*math.sin(angle)
points.append( (int(x),int(y)) )

angle = angle + angleSteps[i]

return points

def clip(x, min, max) :
if( min > max ) :  return x
elif( x < min ) :  return min
elif( x > max ) :  return max
else :             return x
``````
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This is great ! –  user2179021 Dec 28 '14 at 12:14