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.