# Python linear regression diagnostic plots similar to R

I'm trying to get diagnostic plots for a linear regression in Python and I was wondering if there's a quick way to do this.

In R, you can use the code snippet below which'll give you a residuals vs. fitted plot, normal Q-Q plot, scale-location, residuals vs leverage plot.

``````m1 <- lm(cost~ distance, data = df1)
summary(m1)
plot(m1)
``````

Is there a quick way to do this in python?

There's a great blog post that describes how you can use Python code to get the same plots as R would give you but it requires quite a bit of code (compared to the R approach at least). Link: https://underthecurve.github.io/jekyll/update/2016/07/01/one-regression-six-ways.html#Python

• You can create a function / module and then import it and use a one-liner like `my_plot(formula, data)`. This is what R does under the hood as well. Some R code that might (not sure, sorry) be the source of `plot`: github.com/SurajGupta/r-source/blob/master/src/library/stats/R/… Commented Jul 7, 2018 at 7:26

I prefer to storing everything in `pandas` and plot with `DataFrame.plot()` whenever possible:

``````from matplotlib import pyplot as plt
from pandas.core.frame import DataFrame
import scipy.stats as stats
import statsmodels.api as sm

def linear_regression(df: DataFrame) -> DataFrame:
"""Perform a univariate regression and store results in a new data frame.

Args:
df (DataFrame): orginal data set with x and y.

Returns:
DataFrame: another dataframe with raw data and results.
"""
mod = sm.OLS(endog=df['y'], exog=df['x']).fit()
influence = mod.get_influence()

res = df.copy()
res['resid'] = mod.resid
res['fittedvalues'] = mod.fittedvalues
res['resid_std'] = mod.resid_pearson
res['leverage'] = influence.hat_matrix_diag
return res

def plot_diagnosis(df: DataFrame):
fig, axes = plt.subplots(nrows=2, ncols=2)
plt.style.use('seaborn')

# Residual against fitted values.
df.plot.scatter(
x='fittedvalues', y='resid', ax=axes[0, 0]
)
axes[0, 0].axhline(y=0, color='grey', linestyle='dashed')
axes[0, 0].set_xlabel('Fitted Values')
axes[0, 0].set_ylabel('Residuals')
axes[0, 0].set_title('Residuals vs Fitted')

# qqplot
sm.qqplot(
df['resid'], dist=stats.t, fit=True, line='45',
ax=axes[0, 1], c='#4C72B0'
)
axes[0, 1].set_title('Normal Q-Q')

# The scale-location plot.
df.plot.scatter(
x='fittedvalues', y='resid_std', ax=axes[1, 0]
)
axes[1, 0].axhline(y=0, color='grey', linestyle='dashed')
axes[1, 0].set_xlabel('Fitted values')
axes[1, 0].set_ylabel('Sqrt(|standardized residuals|)')
axes[1, 0].set_title('Scale-Location')

# Standardized residuals vs. leverage
df.plot.scatter(
x='leverage', y='resid_std', ax=axes[1, 1]
)
axes[1, 1].axhline(y=0, color='grey', linestyle='dashed')
axes[1, 1].set_xlabel('Leverage')
axes[1, 1].set_ylabel('Sqrt(|standardized residuals|)')
axes[1, 1].set_title('Residuals vs Leverage')

plt.tight_layout()
plt.show()
``````

There are still many features missing, but it provides a good start. I learnt how to extract influence statistics here, Access standardized residuals, cook's values, hatvalues (leverage) etc. easily in Python?

By the way, there is a package, dynobo/lmdiag, having all the features.