# How do I simulate flip of biased coin in python?

In unbiased coin flip H or T occurs 50% of times.

But I want to simulate coin which gives H with probability 'p' and T with probability '(1-p)'.

something like this:

``````def flip(p):
'''this function return H with probability p'''
# do something
return result

>> [flip(0.8) for i in xrange(10)]
[H,H,T,H,H,H,T,H,H,H]
``````
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`random.random()` returns a uniformly distributed pseudo-random floating point number in the range [0, 1). This number is less than a given number `p` in the range [0,1) with probability `p`. Thus:

``````def flip(p):
return 'H' if random.random() < p else 'T'
``````

Some experiments:

``````>>> N = 100
>>> flips = [flip(0.2) for i in xrange(N)]
>>> float(flips.count('H'))/N
0.17999999999999999  # Approximately 20% of the coins are heads

>>> N = 10000
>>> flips = [flip(0.2) for i in xrange(N)]
>>> float(flips.count('H'))/N
0.20549999999999999  # Better approximation
``````
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+1: if better than `{True:'H', False:'T'}[random.random()<p] – S.Lott Jan 25 '09 at 14:13

Do you want the "bias" to be based in symmetric distribuition? Or maybe exponential distribution? Gaussian anyone?

Well, here are all the methods, extracted from random documentation itself.

First, an example of triangular distribution:

``````print random.triangular(0, 1, 0.7)
``````

`random.triangular(low, high, mode)`:

Return a random floating point number `N` such that `low <= N < high` and with the specified mode between those bounds. The `low` and `high` bounds default to zero and one. The `mode` argument defaults to the midpoint between the bounds, giving a symmetric distribution.

`random.betavariate(alpha, beta)`:

Beta distribution. Conditions on the parameters are `alpha > 0` and `beta > 0`. Returned values range between `0` and `1`.

`random.expovariate(lambd)`:

Exponential distribution. `lambd` is `1.0` divided by the desired mean. It should be nonzero. (The parameter would be called “`lambda`”, but that is a reserved word in Python.) Returned values range from `0` to positive infinity if `lambd` is positive, and from negative infinity to `0` if `lambd` is negative.

`random.gammavariate(alpha, beta)`:

Gamma distribution. (Not the gamma function!) Conditions on the parameters are `alpha > 0` and `beta > 0`.

`random.gauss(mu, sigma)`:

Gaussian distribution. `mu` is the mean, and `sigma` is the standard deviation. This is slightly faster than the `normalvariate()` function defined below.

`random.lognormvariate(mu, sigma)`:

Log normal distribution. If you take the natural logarithm of this distribution, you’ll get a normal distribution with mean `mu` and standard deviation `sigma`. `mu` can have any value, and `sigma` must be greater than zero.

`random.normalvariate(mu, sigma)`:

Normal distribution. `mu` is the mean, and `sigma` is the standard deviation.

`random.vonmisesvariate(mu, kappa)`:

`mu` is the mean angle, expressed in radians between `0` and `2*pi`, and `kappa` is the concentration parameter, which must be greater than or equal to zero. If `kappa` is equal to zero, this distribution reduces to a uniform random angle over the range `0` to `2*pi`.

`random.paretovariate(alpha)`:

Pareto distribution. `alpha` is the shape parameter.

`random.weibullvariate(alpha, beta)`

Weibull distribution. `alpha` is the scale parameter and `beta` is the shape parameter.

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Very informative. – Evan Fosmark Jan 28 '09 at 4:21
``````import random
def flip(p):
return (random.random() < p)
``````

That returns a boolean which you can then use to choose H or T (or choose between any two values) you want. You could also include the choice in the method:

``````def flip(p):
if random.random() < p:
return 'H'
else:
return 'T'
``````

but it'd be less generally useful that way.

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• Import a random number between 0 - 1 (you can use randrange function)

• If the number is above (1-p), return tails.

``````import numpy as np