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Let's say that I know the probability of a "success" is P. I run the test N times, and I see S successes. The test is akin to tossing an unevenly weighted coin (perhaps heads is a success, tails is a failure).

I want to know the approximate probability of seeing either S successes, or a number of successes less likely than S successes.

So for example, if P is 0.3, N is 100, and I get 20 successes, I'm looking for the probability of getting 20 or fewer successes.

If, on the other hadn, P is 0.3, N is 100, and I get 40 successes, I'm looking for the probability of getting 40 our more successes.

I'm aware that this problem relates to finding the area under a binomial curve, however:

  1. My math-fu is not up to the task of translating this knowledge into efficient code
  2. While I understand a binomial curve would give an exact result, I get the impression that it would be inherently inefficient. A fast method to calculate an approximate result would suffice.

I should stress that this computation has to be fast, and should ideally be determinable with standard 64 or 128 bit floating point computation.

I'm looking for a function that takes P, S, and N - and returns a probability. As I'm more familiar with code than mathematical notation, I'd prefer that any answers employ pseudo-code or code.

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Why are big numbers a problem? If you're using a binomial distribution for large values, it must mean that you can't accept the error that results from approximating the binomial distribution with a continuous distribution, so you should be willing to sacrifice speed for accuracy by using a bignum library like GMP. –  user57368 Jul 8 '09 at 1:38
I'm happy to approximate it –  sanity Jul 8 '09 at 1:59
In that case use the Gaussian error function (en.wikipedia.org/wiki/Error_function), or rather an approximation to it. –  Steve Jessop Jul 8 '09 at 2:04
Or there are some bounds given here: en.wikipedia.org/wiki/Q-function –  Steve Jessop Jul 8 '09 at 2:08

7 Answers 7

up vote 13 down vote accepted

Exact Binomial Distribution

def factorial(n): 
    if n < 2: return 1
    return reduce(lambda x, y: x*y, xrange(2, int(n)+1))

def prob(s, p, n):
    x = 1.0 - p

    a = n - s
    b = s + 1

    c = a + b - 1

    prob = 0.0

    for j in xrange(a, c + 1):
        prob += factorial(c) / (factorial(j)*factorial(c-j)) \
                * x**j * (1 - x)**(c-j)

    return prob

>>> prob(20, 0.3, 100)

>>> 1-prob(40-1, 0.3, 100)

Normal Estimate, good for large n

import math
def erf(z):
        t = 1.0 / (1.0 + 0.5 * abs(z))
        # use Horner's method
        ans = 1 - t * math.exp( -z*z -  1.26551223 +
                                                t * ( 1.00002368 +
                                                t * ( 0.37409196 + 
                                                t * ( 0.09678418 + 
                                                t * (-0.18628806 + 
                                                t * ( 0.27886807 + 
                                                t * (-1.13520398 + 
                                                t * ( 1.48851587 + 
                                                t * (-0.82215223 + 
                                                t * ( 0.17087277))))))))))
        if z >= 0.0:
                return ans
                return -ans

def normal_estimate(s, p, n):
    u = n * p
    o = (u * (1-p)) ** 0.5

    return 0.5 * (1 + erf((s-u)/(o*2**0.5)))

>>> normal_estimate(20, 0.3, 100)

>>> 1-normal_estimate(40-1, 0.3, 100)

Poisson Estimate: Good for large n and small p

import math

def poisson(s,p,n):
    L = n*p

    sum = 0
    for i in xrange(0, s+1):
        sum += L**i/factorial(i)

    return sum*math.e**(-L)

>>> poisson(20, 0.3, 100)
>>> 1-poisson(40-1, 0.3, 100)
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I think you want to evaluate the incomplete beta function.

There's a nice implementation using a continued fraction representation in "Numerical Recipes In C", chapter 6: 'Special Functions'.

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Can you explain how the incomplete beta function solves this problem? –  sanity Jul 11 '09 at 19:02
The probability P of an event occurring with probability p, k or more time in n trials, is the cumulative binomial probability. It's related to the incomplete beta function. Have a look at equation 6.4.12 on page 229 of "Numerical Recipes in C". –  duffymo Jul 11 '09 at 19:45
see also en.wikipedia.org/wiki/… –  Jason S Dec 11 '09 at 19:08
As a note to others who might become confused like I was: Wolfram Alpha refers to this function as the "regularized incomplete beta function" with the function name BetaRegularized. So with a probability of p, trials t and successful trials s, you want to evaluate: BetaRegularized(p, s, t - s + 1) –  James Dec 7 '11 at 0:04

I can't totally vouch for the efficiency, but Scipy has a module for this

from scipy.stats.distributions import binom
binom.cdf(successes, attempts, chance_of_success_per_attempt)
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From the portion of your question "getting at least S heads" you want the cummulative binomial distribution function. See http://en.wikipedia.org/wiki/Binomial_distribution for the equation, which is described as being in terms of the "regularized incomplete beta function" (as already answered). If you just want to calculate the answer without having to implement the entire solution yourself, the GNU Scientific Library provides the function: gsl_cdf_binomial_P and gsl_cdf_binomial_Q.

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An efficient and, more importantly, numerical stable algorithm exists in the domain of Bezier Curves used in Computer Aided Design. It is called de Casteljau's algorithm used to evaluate the Bernstein Polynomials used to define Bezier Curves.

I believe that I am only allowed one link per answer so start with Wikipedia - Bernstein Polynomials

Notice the very close relationship between the Binomial Distribution and the Bernstein Polynomials. Then click through to the link on de Casteljau's algorithm.

Lets say I know the probability of throwing a heads with a particular coin is P. What is the probability of me throwing the coin T times and getting at least S heads?

  • Set n = T
  • Set beta[i] = 0 for i = 0, ... S - 1
  • Set beta[i] = 1 for i = S, ... T
  • Set t = p
  • Evaluate B(t) using de Casteljau

or at most S heads?

  • Set n = T
  • Set beta[i] = 1 for i = 0, ... S
  • Set beta[i] = 0 for i = S + 1, ... T
  • Set t = p
  • Evaluate B(t) using de Casteljau

Open source code probably exists already. NURBS Curves (Non-Uniform Rational B-spline Curves) are a generalization of Bezier Curves and are widely used in CAD. Try openNurbs (the license is very liberal) or failing that Open CASCADE (a somewhat less liberal and opaque license). Both toolkits are in C++, though, IIRC, .NET bindings exist.

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The DCDFLIB Project has C# functions (wrappers around C code) to evaluate many CDF functions, including the binomial distribution. You can find the original C and FORTRAN code here. This code is well tested and accurate.

If you want to write your own code to avoid being dependent on an external library, you could use the normal approximation to the binomial mentioned in other answers. Here are some notes on how good the approximation is under various circumstances. If you go that route and need code to compute the normal CDF, here's Python code for doing that. It's only about a dozen lines of code and could easily be ported to any other language. But if you want high accuracy and efficient code, you're better off using third party code like DCDFLIB. Several man-years went into producing that library.

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Try this one, used in GMP. Another reference is this.

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My bad for not explaining it better, but the title did a poor job of explaining what I needed. Please refer to the coin tossing problem I mention in the body of the question. –  sanity Jul 8 '09 at 1:32
Hm... someone just upvoted the 2nd google hit for "binomial coefficient algorithm"... –  Dervin Thunk Jul 8 '09 at 1:42

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