Metadata-Version: 2.1
Name: lhsmdu
Version: 0.1
Summary: This is an implementation of Latin Hypercube Sampling with Multi-Dimensional Uniformity (LHS-MDU) from Deutsch and Deutsch, "Latin hypercube sampling with multidimensional uniformity.
Home-page: http://github.com/sahilm89/lhsmdu
Author: Sahil Moza
Author-email: sahil.moza@gmail.com
License: MIT
Platform: UNKNOWN
Requires-Dist: numpy
Requires-Dist: scipy

LHS-MDU
--------

Basics
======
This is a package for generating latin hypercube samples with multi-dimensional uniformity.

To use, simply do::

    >>> import lhsmdu 
    >>> k = lhsmdu.sample(2, 20) # Latin Hypercube Sampling with multi-dimensional uniformity 

This will generate a nested list with 2 variables, with 20 samples each.

To plot and see the difference between Monte Carlo and LHS-MDU sampling for a 2 dimensional system::

    >>> l = lhsmdu.createRandomStandardUniformMatrix(2, 20) # Monte Carlo sampling 
    >>> import matplotlib.pyplot as plt 
    >>> fig = plt.figure() 
    >>> ax = fig.gca()
    >>> ax.set_xticks(numpy.arange(0,1,0.1))
    >>> ax.set_yticks(numpy.arange(0,1,0.1))
    >>> plt.scatter(k[0], k[1], col="g", label="LHS-MDU") 
    >>> plt.scatter(l[0], l[1], col="r", label="MC") 
    >>> plt.grid()
    >>> plt.show() 

You can use the strata generated by the algorithm to sample again, if you so desire. For this, you can do::

    >>> m = lhsmdu.resample()
    >>> n = lhsmdu.resample()
    >>> o = lhsmdu.resample()

This will again generate the same number of samples as before, a nested list with 2 variables, with 20 samples each.

You can plot these together and see the sampling from the strata::

    >>> fig = plt.figure() 
    >>> ax = fig.gca()
    >>> ax.set_xticks(numpy.arange(0,1,0.1))
    >>> ax.set_yticks(numpy.arange(0,1,0.1))
    >>> plt.title("LHS-MDU") 
    >>> plt.scatter(k[0], k[1], c="g", label="sample 1") 
    >>> plt.scatter(m[0], m[1], c="r", label="resample 2") 
    >>> plt.scatter(n[0], n[1], c="b", label="resample 3") 
    >>> plt.scatter(o[0], o[1], c="y", label="resample 4") 
    >>> plt.grid()
    >>> plt.show() 

Alternatively, you can choose to get new strata each time, and see the sampling hence::

    >>> p = lhsmdu.sample(2, 20) # Latin Hypercube Sampling with multi-dimensional uniformity 
    >>> q = lhsmdu.sample(2, 20) # Latin Hypercube Sampling with multi-dimensional uniformity 
    >>> r = lhsmdu.sample(2, 20) # Latin Hypercube Sampling with multi-dimensional uniformity 
    >>> fig = plt.figure() 
    >>> ax = fig.gca()
    >>> ax.set_xticks(numpy.arange(0,1,0.1))
    >>> ax.set_yticks(numpy.arange(0,1,0.1))
    >>> plt.title("LHS-MDU") 
    >>> plt.scatter(k[0], k[1], c="g", label="sample 1") 
    >>> plt.scatter(p[0], p[1], c="r", label="sample 2") 
    >>> plt.scatter(q[0], q[1], c="b", label="sample 3") 
    >>> plt.scatter(r[0], r[1], c="y", label="sample 4") 
    >>> plt.grid()
    >>> plt.show() 

===========================================================================================

Sampling from arbitrary CDFs
=======================

After uniformly distributed samples have been generated from LHSMDU, you can convert these to samples from arbitrary distributions using inverse tranform sampling. In this, the CDF [0,1] of the distribution of interest is inverted, and then data points corresponding to the uniformly sampled points are picked up. To do this, you must have a `rv_contiuous` or `rv_discrete` distribution instance taken from scipy.stats. You can also use frozen distributions (after setting loc and scale parameters). Following is an example for normal distribution.::

    >>> import scipy.stats.distributions as ssd
    >>> p = ssd.norm
    >>> new_samples = lhsmdu.inverseTransformSample(p, k[0])
    >>> plt.hist(lhsmdu.inverseTransformSample(p, k[0]))
    >>> plt.show()




