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 ) :
'''Start with the centre of the polygon at ctrX, ctrY,
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) :
r_i = clip( random.gauss(aveRadius, spikeyness), 0, 2*aveRadius )
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
```

simplepolygons, since in general taking an arbitrary order of n points will also produce self-intersecting polygons. – Jorge Jan 25 '12 at 2:45