# scipy.stats.qmc.LatinHypercube.integers#

LatinHypercube.integers(l_bounds, *, u_bounds=None, n=1, endpoint=False, workers=1)[source]#

Draw n integers from l_bounds (inclusive) to u_bounds (exclusive), or if endpoint=True, l_bounds (inclusive) to u_bounds (inclusive).

Parameters:
l_boundsint or array-like of ints

Lowest (signed) integers to be drawn (unless u_bounds=None, in which case this parameter is 0 and this value is used for u_bounds).

u_boundsint or array-like of ints, optional

If provided, one above the largest (signed) integer to be drawn (see above for behavior if u_bounds=None). If array-like, must contain integer values.

nint, optional

Number of samples to generate in the parameter space. Default is 1.

endpointbool, optional

If true, sample from the interval [l_bounds, u_bounds] instead of the default [l_bounds, u_bounds). Defaults is False.

workersint, optional

Number of workers to use for parallel processing. If -1 is given all CPU threads are used. Only supported when using Halton Default is 1.

Returns:
samplearray_like (n, d)

QMC sample.

Notes

It is safe to just use the same [0, 1) to integer mapping with QMC that you would use with MC. You still get unbiasedness, a strong law of large numbers, an asymptotically infinite variance reduction and a finite sample variance bound.

To convert a sample from $$[0, 1)$$ to $$[a, b), b>a$$, with $$a$$ the lower bounds and $$b$$ the upper bounds, the following transformation is used:

$\text{floor}((b - a) \cdot \text{sample} + a)$