This is my first attempt to model a linear regression for a response that is lognormally distributed. I have a dataframe df with two variables: the predictor X and the response. When I plot the response vs. the predictor variable X, we obtain this nice plot: enter image description here

When I plot the distribution of the logarithm of the response np.log(response) I obtain something pretty close to a Normal distribution:

. enter image description here

To model the relationship between X and response I build the following model,

import pymc3 as pm

with pm.Model() as model: 
    a = pm.Normal('a', 0, 10)
    b = pm.Normal('b', 0, 10)
    sigma = pm.Uniform('sigma', lower=0, upper=10)

    mu = pm.Deterministic('mu', a + b * df_train[X])

    y_hat = pm.Lognormal('y_hat', mu = mu, sd = sigma, observed = df['response'] )

    trace = pm.sample(2000, tune = 2000)

The next step is to measure to which extend the model is correct, so I compute the average response for the dataset, i.e,

mu_hat = np.exp(trace['mu'].mean(0)

However, when I plot how well this average fits the test set, I observe such a poor fit:

enter image description here

Possible Solutions: I have tried other likelihoods like Normal and Poisson and and I could not achieve a convergence for the model. I was getting an error saying:

Bad initial energy: inf. The model might be misspecified.

Any ideas on why this fit fails so miserably?


It looks like you have a lognormal distribution of X with a linear response, and maybe some linear error with the magnitude of X. Without the data, it's hard to tell, but here's my recreation of your problem:

matplotlib inline

import matplotlib.pyplot as plt
import numpy as np
import seaborn as sns

x = np.random.lognormal(5, 1, 10000)
y = x * np.random.normal(5,1,10000)

f, axes = plt.subplots(2, 1, figsize=(16,12))
sns.scatterplot(x,y, ax=axes[0])
sns.distplot(np.log(y), ax=axes[1])

Scatterplot of x and y, distribution of log(y)

Then we can model the x coefficient and dependent y error:

with pm.Model() as model: 
    sigma = pm.InverseGamma('sigma', mu=(y/x).std(), sd = (y/x).std()/len(x))
    #intercept = pm.Normal('Intercept', 0, sigma=1)
    x_coeff = pm.Normal('x_coeff', (y/x).mean(), sigma=1)

    l = pm.Normal('l', mu=x_coeff, sigma=sigma, observed=y/x)

    trace = pm.sample(3000, tune=1000, cores=4)

And now plotting the lines we get:

f, axes = plt.subplots(figsize=(16,8))
sns.scatterplot(x, y, ax=axes)
for (_,val) in pm.stats.quantiles(trace['x_coeff']).items():
    plt.plot(x, val*x, color='b')
    for (__, sd) in pm.stats.quantiles(trace['sigma']).items():
        plt.plot(x, (val+2*sd)*x, color='r')
        plt.plot(x, (val-2*sd)*x, color='r')

x coefficients plotted with 2*sd positive and negative

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.