In machine learning task. We should get a group of random w.r.t normal distribution with bound. We can get a normal distribution number with np.random.normal()
but it does't offer any bound parameter. I want to know how to do that?

5Shouldn't random samples of normally distributed data by definition be unbounded? – Tom Apr 27 '16 at 15:31

Possible duplicate of How to specify upper and lower limits when using numpy.random.normal – Goyo Sep 16 '18 at 14:42
The parametrization of truncnorm
is complicated, so here is a function that translates the parametrization to something more intuitive:
from scipy.stats import truncnorm
def get_truncated_normal(mean=0, sd=1, low=0, upp=10):
return truncnorm(
(low  mean) / sd, (upp  mean) / sd, loc=mean, scale=sd)
How to use it?
Instance the generator with the parameters: mean, standard deviation, and truncation range:
>>> X = get_truncated_normal(mean=8, sd=2, low=1, upp=10)
Then, you can use X to generate a value:
>>> X.rvs() 6.0491227353928894
Or, a numpy array with N generated values:
>>> X.rvs(10) array([ 7.70231607, 6.7005871 , 7.15203887, 6.06768994, 7.25153472, 5.41384242, 7.75200702, 5.5725888 , 7.38512757, 7.47567455])
A Visual Example
Here is the plot of three different truncated normal distributions:
X1 = get_truncated_normal(mean=2, sd=1, low=1, upp=10)
X2 = get_truncated_normal(mean=5.5, sd=1, low=1, upp=10)
X3 = get_truncated_normal(mean=8, sd=1, low=1, upp=10)
import matplotlib.pyplot as plt
fig, ax = plt.subplots(3, sharex=True)
ax[0].hist(X1.rvs(10000), normed=True)
ax[1].hist(X2.rvs(10000), normed=True)
ax[2].hist(X3.rvs(10000), normed=True)
plt.show()

3

+1. It's worth noting, though, that the function gets much quicker if
get_truncated_normal.rvs( )
is used immediately inside the function, instead of calling it outside. Of course, this helps only if you want random draws – KenHBS Nov 16 '17 at 13:54
If you're looking for the Truncated normal distribution, SciPy has a function for it called truncnorm
The standard form of this distribution is a standard normal truncated to the range [a, b] — notice that a and b are defined over the domain of the standard normal. To convert clip values for a specific mean and standard deviation, use:
a, b = (myclip_a  my_mean) / my_std, (myclip_b  my_mean) / my_std
truncnorm takes a and b as shape parameters.
>>> from scipy.stats import truncnorm
>>> truncnorm(a=2/3., b=2/3., scale=3).rvs(size=10)
array([1.83136675, 0.77599978, 0.01276925, 1.87043384, 1.25024188,
0.59336279, 0.39343176, 1.9449987 , 1.97674358, 0.31944247])
The above example is bounded by 2 and 2 and returns 10 random variates (using the .rvs()
method)
>>> min(truncnorm(a=2/3., b=2/3., scale=3).rvs(size=10000))
1.9996074381484044
>>> max(truncnorm(a=2/3., b=2/3., scale=3).rvs(size=10000))
1.9998486576228549
Here's a histogram plot for 6, 6:


3Just to make it clear that a and b are shape parameters otherwise a reader might try 2, 2 with a scale different than 1, and then get random values outside [2, 2] – bakkal Apr 27 '16 at 16:00
Besides @bakkal suggestion (+1) you might also want to take a look into Vincent Mazet recipe for achieving this, rewritten as pyrtnorm module by Christoph Lassner.
If you just want to work with numpy
you could also do something like this:
int(np.clip(int(np.random.normal(mean,std)),min_size,max_size)
This will just clip smaller and larger values to your specified min
and max