I think this will help. *I was looking for the same issue for a long time and finally found a solution for my problem*. In my case, **I was trying to fit some data to the lognormal distribution using **`scipy.stats.lognorm`

module. However, when I finally got the model parameters, I could not find a way to replicate my results using the mean and std from y data.

In the code below, I explain from the mean and std parameters how to produce a normally distributed data sample using scipy.stats.norm module. Using those data, I fit the normal model (`norm_dist_fitted`

) and also create a normal model using mean and standard deviation (`mu, sigma`

) extracted from the data.

Original model producing the data, fitted and produced-by-(mu-sigma)-pair is compared in a graph.

Fig1

In the next section of the code, I use the normal data to produce a lognormal-distributed sample. To do so notice that the lognormal samples will be the exponential of the original sample. Hence, the mean and standard deviation of the exponential sample will be (`exp(mu)`

and `exp(sigma)`

).

I fitted the produced data to a `lognormal`

(since the log of my sample (exp(x)) is normally distributed and follow the lognormal model assumptions.

To produce a lognormal model from the mean and standard deviation of your original data (x) the code will be:

```
lognorm_dist = scipy.stats.lognorm(s=sigma, loc=0, scale=np.exp(mu))
```

However, if your data is already in the exponential space (exp(x)), then you have to use:

```
muX = np.mean(np.log(x))
sigmaX = np.std(np.log(x))
scipy.stats.lognorm(s=sigmaX, loc=0, scale=muX)
```

Fig2

```
import scipy
import matplotlib.pyplot as plt
import seaborn as sns
import numpy as np
mu = 10 # Mean of sample !!! Make sure your data is positive for the lognormal example
sigma = 1.5 # Standard deviation of sample
N = 2000 # Number of samples
norm_dist = scipy.stats.norm(loc=mu, scale=sigma) # Create Random Process
x = norm_dist.rvs(size=N) # Generate samples
# Fit normal
fitting_params = scipy.stats.norm.fit(x)
norm_dist_fitted = scipy.stats.norm(*fitting_params)
t = np.linspace(np.min(x), np.max(x), 100)
# Plot normals
f, ax = plt.subplots(1, sharex='col', figsize=(10, 5))
sns.distplot(x, ax=ax, norm_hist=True, kde=False, label='Data X~N(mu={0:.1f}, sigma={1:.1f})'.format(mu, sigma))
ax.plot(t, norm_dist_fitted.pdf(t), lw=2, color='r',
label='Fitted Model X~N(mu={0:.1f}, sigma={1:.1f})'.format(norm_dist_fitted.mean(), norm_dist_fitted.std()))
ax.plot(t, norm_dist.pdf(t), lw=2, color='g', ls=':',
label='Original Model X~N(mu={0:.1f}, sigma={1:.1f})'.format(norm_dist.mean(), norm_dist.std()))
ax.legend(loc='lower right')
plt.show()
# The lognormal model fits to a variable whose log is normal
# We create our variable whose log is normal 'exponenciating' the previous variable
x_exp = np.exp(x)
mu_exp = np.exp(mu)
sigma_exp = np.exp(sigma)
fitting_params_lognormal = scipy.stats.lognorm.fit(x_exp, floc=0, scale=mu_exp)
lognorm_dist_fitted = scipy.stats.lognorm(*fitting_params_lognormal)
t = np.linspace(np.min(x_exp), np.max(x_exp), 100)
# Here is the magic I was looking for a long long time
lognorm_dist = scipy.stats.lognorm(s=sigma, loc=0, scale=np.exp(mu))
# The trick is to understand these two things:
# 1. If the EXP of a variable is NORMAL with MU and STD -> EXP(X) ~ scipy.stats.lognorm(s=sigma, loc=0, scale=np.exp(mu))
# 2. If your variable (x) HAS THE FORM of a LOGNORMAL, the model will be scipy.stats.lognorm(s=sigmaX, loc=0, scale=muX)
# with:
# - muX = np.mean(np.log(x))
# - sigmaX = np.std(np.log(x))
# Plot lognormals
f, ax = plt.subplots(1, sharex='col', figsize=(10, 5))
sns.distplot(x_exp, ax=ax, norm_hist=True, kde=False,
label='Data exp(X)~N(mu={0:.1f}, sigma={1:.1f})\n X~LogNorm(mu={0:.1f}, sigma={1:.1f})'.format(mu, sigma))
ax.plot(t, lognorm_dist_fitted.pdf(t), lw=2, color='r',
label='Fitted Model X~LogNorm(mu={0:.1f}, sigma={1:.1f})'.format(lognorm_dist_fitted.mean(), lognorm_dist_fitted.std()))
ax.plot(t, lognorm_dist.pdf(t), lw=2, color='g', ls=':',
label='Original Model X~LogNorm(mu={0:.1f}, sigma={1:.1f})'.format(lognorm_dist.mean(), lognorm_dist.std()))
ax.legend(loc='lower right')
plt.show()
```