# Python – Log Gamma Distribution in Statistics

scipy.stats.loggamma() is a log gamma continuous random variable. It is inherited from the of generic methods as an instance of the rv_continuous class. It completes the methods with details specific for this particular distribution. Parameters :
q : lower and upper tail probability x : quantiles loc : [optional]location parameter. Default = 0 scale : [optional]scale parameter. Default = 1 size : [tuple of ints, optional] shape or random variates. moments : [optional] composed of letters [â€˜mvskâ€™]; â€˜mâ€™ = mean, â€˜vâ€™ = variance, â€˜sâ€™ = Fisherâ€™s skew and â€˜kâ€™ = Fisherâ€™s kurtosis. (default = â€˜mvâ€™). Results : log gamma continuous random variable
Code #1 : Creating log gamma continuous random variable
 `# importing library `` ` `from` `scipy.stats ``import` `loggamma   ``   ` `numargs ``=` `loggamma.numargs  ``a, b ``=` `4.32``, ``3.18``rv ``=` `loggamma(a, b)  ``   ` `print` `(``"RV : \n"``, rv)   `

Output :
```RV :
scipy.stats._distn_infrastructure.rv_frozen object at 0x000002A9D6AE0588
```
Code #2 : log gamma continuous variates and probability distribution
 `import` `numpy as np  ``quantile ``=` `np.arange (``0.01``, ``1``, ``0.1``)  `` ` `# Random Variates  ``R ``=` `loggamma.rvs(a, b)  ``print` `(``"Random Variates : \n"``, R)  `` ` `# PDF  ``R ``=` `loggamma.pdf(a, b, quantile)  ``print` `(``"\nProbability Distribution : \n"``, R)  `

Output :
```Random Variates :
3.941580350134656

Probability Distribution :
[1.76757240e-27 1.53388070e-24 6.78322725e-22 1.62994246e-19
2.25532281e-17 1.89389591e-15 1.01217167e-13 3.59400367e-12
8.81510518e-11 1.54700389e-09]

```
Code #3 : Graphical Representation.
 `import` `numpy as np  ``import` `matplotlib.pyplot as plt  ``    ` `distribution ``=` `np.linspace(``0``, np.minimum(rv.dist.b, ``3``))  ``print``(``"Distribution : \n"``, distribution)  ``    ` `plot ``=` `plt.plot(distribution, rv.pdf(distribution))  `

Output :
```Distribution :
[0.         0.06122449 0.12244898 0.18367347 0.24489796 0.30612245
0.36734694 0.42857143 0.48979592 0.55102041 0.6122449  0.67346939
0.73469388 0.79591837 0.85714286 0.91836735 0.97959184 1.04081633
1.10204082 1.16326531 1.2244898  1.28571429 1.34693878 1.40816327
1.46938776 1.53061224 1.59183673 1.65306122 1.71428571 1.7755102
1.83673469 1.89795918 1.95918367 2.02040816 2.08163265 2.14285714
2.20408163 2.26530612 2.32653061 2.3877551  2.44897959 2.51020408
2.57142857 2.63265306 2.69387755 2.75510204 2.81632653 2.87755102
2.93877551 3.        ]
```
Code #4 : Varying Positional Arguments
 `import` `matplotlib.pyplot as plt  ``import` `numpy as np  ``    ` `x ``=` `np.linspace(``0``, ``5``, ``100``)  ``    ` `# Varying positional arguments  ``y1 ``=` `loggamma .pdf(x, ``1``, ``3``)  ``y2 ``=` `loggamma .pdf(x, ``1``, ``4``)  ``plt.plot(x, y1, ``"*"``, x, y2, ``"r--"``)  `

Output :

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