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I was wondering which is the simplest and most configurable way to obtain what I need in the following situation:

  • I have a counter, let's call it X that will be used to extract one of the sets
  • I have a variable number of sets S1, S2, .. which can be considered total ordered between themselves
  • I want to mix these sets in a fuzzy way so that for X = 0 it will give me S1, for, let's say, X = 20 it will give me S1 with 70% chance, and S2 with 30% chance
  • Increasing X will decrease probability of S1 until 0% while increasing S2 up to 100%, then there can be a zone in which it will always give me S2 until a new threshold for which S2 will start to decrease and S3 will start getting its chance and so on

I know how to do it by hardcoding everything, but since it will need some tweaking I would like to apply a solution which easily allows me to configure how many sets I have and the single thresholds (start/end of increasing probability and start/end of decreasing prob). Of course I don't need any intersection between more than 2 sets each and a linear increase/decrease of probability is ok.. any good clues?

Thanks in advance!

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up vote 1 down vote accepted

To assign the distribution of your probabilities, you could use Bernstein polynomials:


These can be efficiently computed using de Casteljau's algorithm (basically it does DP on the recursion in the obvious way):



What you get as a result will be a set of weights on the distributions. To select one of your sets, you just generate a uniform random variable in [0,1] then choose the set it lands in based on these weights.

Here is some code in python which does this:

import random

#Selects one of the n sets with a weight based on x
def pick_a_set(n, x):

    #Compute bernstein polynomials
    weights = [ [ float(i == j)  for j in range(n) ] for i in range(n) ]
    for k in range(n):
        for j in range(n-k-1):
            for i in range(n):
                weights[j][i] = weights[j][i] * (1.0 - x) + weights[j+1][i] * x

    #Select using weights
    u = random.random()
    for k in range(n):
        if u < weights[0][k]:
            return k
        u -= weights[0][k]
    return 0
share|improve this answer
Seems an elegant solution, let me try it.. thanks in the meanwhile! – Jack Jun 25 '11 at 3:11
@Jack: Let me know how it works! – Mikola Jun 25 '11 at 5:08
I adapted it to my language and situation, by tweaking x I'm able to spread differently over the various sets but I don't have too much clear how to manage different spreads, should I use different xs? I promise to take a deeper look to the maths, I'm just too lazy in these days ;) – Jack Jun 28 '11 at 4:04
If you want to tweak the spreads, you basically have to tweak the knot vector of the spline. Again from that web page I linked: cs.mtu.edu/~shene/COURSES/cs3621/NOTES/spline/B-spline/… – Mikola Jun 28 '11 at 4:20
And for more local control of the spread, you could switch to B-spline basis functions (which are basically localized versions of the Bernstein polynomials). All the relevant material is again on that web page. :) cs.mtu.edu/~shene/COURSES/cs3621/NOTES – Mikola Jun 28 '11 at 4:22

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