I do this linear regression with StatsModels:

import numpy as np
import statsmodels.api as sm
from statsmodels.sandbox.regression.predstd import wls_prediction_std

n = 100

x = np.linspace(0, 10, n)
e = np.random.normal(size=n)
y = 1 + 0.5*x + 2*e
X = sm.add_constant(x)

re = sm.OLS(y, X).fit()

prstd, iv_l, iv_u = wls_prediction_std(re)

My questions are, iv_l and iv_u are the upper and lower confidence intervals or prediction intervals?

How I get others?

I need the confidence and prediction intervals for all points, to do a plot.


For test data you can try to use the following.

predictions = result.get_prediction(out_of_sample_df)

I found the summary_frame() method buried here and you can find the get_prediction() method here. You can change the significance level of the confidence interval and prediction interval by modifying the "alpha" parameter.

I am posting this here because this was the first post that comes up when looking for a solution for confidence & prediction intervals – even though this concerns itself with test data rather.

Here's a function to take a model, new data, and an arbitrary quantile, using this approach:

def ols_quantile(m, X, q):
  # m: OLS model.
  # X: X matrix.
  # q: Quantile.
  # Set alpha based on q.
  a = q * 2
  if q > 0.5:
    a = 2 * (1 - q)
  predictions = m.get_prediction(X)
  frame = predictions.summary_frame(alpha=a)
  if q > 0.5:
    return frame.obs_ci_upper
  return frame.obs_ci_lower
  • 1
    predictions.summary_frame(alpha=0.05) throws an error for me (TypeError: 'builtin_function_or_method' object is not iterable). I've raised an issue on github: github.com/statsmodels/statsmodels/issues/4437 Apr 7 '18 at 8:09
  • 1
    What is out_of_sample_df? Or more generally, what parameters does get_prediction() take? When I try to feed it e.g. x-values for the prediction, it ValueErrors out.
    – Dan
    Apr 20 '18 at 18:24
  • @Dan See statsmodels.org/dev/generated/….
    – T_T
    Jul 6 '18 at 23:20
  • @Dan Check if you have added the constant value. Mar 17 '20 at 22:02

update see the second answer which is more recent. Some of the models and results classes have now a get_prediction method that provides additional information including prediction intervals and/or confidence intervals for the predicted mean.

old answer:

iv_l and iv_u give you the limits of the prediction interval for each point.

Prediction interval is the confidence interval for an observation and includes the estimate of the error.

I think, confidence interval for the mean prediction is not yet available in statsmodels. (Actually, the confidence interval for the fitted values is hiding inside the summary_table of influence_outlier, but I need to verify this.)

Proper prediction methods for statsmodels are on the TODO list.


Confidence intervals are there for OLS but the access is a bit clumsy.

To be included after running your script:

from statsmodels.stats.outliers_influence import summary_table

st, data, ss2 = summary_table(re, alpha=0.05)

fittedvalues = data[:, 2]
predict_mean_se  = data[:, 3]
predict_mean_ci_low, predict_mean_ci_upp = data[:, 4:6].T
predict_ci_low, predict_ci_upp = data[:, 6:8].T

# Check we got the right things
print np.max(np.abs(re.fittedvalues - fittedvalues))
print np.max(np.abs(iv_l - predict_ci_low))
print np.max(np.abs(iv_u - predict_ci_upp))

plt.plot(x, y, 'o')
plt.plot(x, fittedvalues, '-', lw=2)
plt.plot(x, predict_ci_low, 'r--', lw=2)
plt.plot(x, predict_ci_upp, 'r--', lw=2)
plt.plot(x, predict_mean_ci_low, 'r--', lw=2)
plt.plot(x, predict_mean_ci_upp, 'r--', lw=2)

enter image description here

This should give the same results as SAS, http://jpktd.blogspot.ca/2012/01/nice-thing-about-seeing-zeros.html

  • 1
    One issue with this method is that if the points are sparse, predict_mean_ci_low and predict_mean_ci_upp are going to be jagged/pointy when plotted because they only exist at the fitted values, instead of a range of points. However, the fit line is defined for all points. There is a comment that says using hat_matrix only works for fitted values in github.com/statsmodels/statsmodels/blob/master/statsmodels/… - any idea how to get around that?
    – Andrew Mao
    Aug 21 '15 at 17:46
  • I have an issue with the application of this answer to my dataset, posted as a separate question here: stackoverflow.com/questions/34998772/…. Any advice much appreciated!
    – PJW
    Jan 25 '16 at 17:43
  • This is an old question, but based on this answer, how would it be possible to only get those data points below the 95 CI? I posted this as new question stackoverflow.com/questions/50585837/…
    – PedroA
    May 29 '18 at 13:47
  • Isn't there a way to do the same when one does "fit_regularized()" instead? It seems that all methods work for normal "fit()"
    – azal
    Mar 4 at 11:34

summary_frame and summary_table work well when you need exact results for a single quantile, but don't vectorize well. This will provide a normal approximation of the prediction interval (not confidence interval) and works for a vector of quantiles:

def ols_quantile(m, X, q):
  # m: Statsmodels OLS model.
  # X: X matrix of data to predict.
  # q: Quantile.
  from scipy.stats import norm
  mean_pred = m.predict(X)
  se = np.sqrt(m.scale)
  return mean_pred + norm.ppf(q) * se

With time series results, you get a much smoother plot using the get_forecast() method. An example of time series is below:

# Seasonal Arima Modeling, no exogenous variable
model = SARIMAX(train['MI'], order=(1,1,1), seasonal_order=(1,1,0,12), enforce_invertibility=True)

results = model.fit()


enter image description here

The next step is to make the predictions, this generates the confidence intervals.

# make the predictions for 11 steps ahead
predictions_int = results.get_forecast(steps=11)

enter image description here

These can be put in a data frame but need some cleaning up:

# get a better view

enter image description here

Concatenate the data frame, but clean up the headers

conf_df = pd.concat([test['MI'],predictions_int.predicted_mean, predictions_int.conf_int()], axis = 1)


enter image description here

Then we rename the columns.

conf_df = conf_df.rename(columns={0: 'Predictions', 'lower MI': 'Lower CI', 'upper MI': 'Upper CI'})

enter image description here

Make the plot.

# make a plot of model fit
# color = 'skyblue'

fig = plt.figure(figsize = (16,8))
ax1 = fig.add_subplot(111)

x = conf_df.index.values

upper = conf_df['Upper CI']
lower = conf_df['Lower CI']

conf_df['MI'].plot(color = 'blue', label = 'Actual')
conf_df['Predictions'].plot(color = 'orange',label = 'Predicted' )
upper.plot(color = 'grey', label = 'Upper CI')
lower.plot(color = 'grey', label = 'Lower CI')

# plot the legend for the first plot
plt.legend(loc = 'lower left', fontsize = 12)

# fill between the conf intervals
plt.fill_between(x, lower, upper, color='grey', alpha='0.2')



enter image description here


You can get the prediction intervals by using LRPI() class from the Ipython notebook in my repo (https://github.com/shahejokarian/regression-prediction-interval).

You need to set the t value to get the desired confidence interval for the prediction values, otherwise the default is 95% conf. interval.

The LRPI class uses sklearn.linear_model's LinearRegression , numpy and pandas libraries.

There is an example shown in the notebook too.


You can calculate them based on results given by statsmodel and the normality assumptions.

Here is an example for OLS and CI for the mean value:

import statsmodels.api as sm
import numpy as np
from scipy import stats

#Significance level:
sl = 0.05
#Evaluate mean value at a required point x0. Here, at the point (0.0,2.0) for N_model=2:
x0 = np.asarray([1.0, 0.0, 2.0])# If you have no constant in your model, remove the first 1.0. For more dimensions, add the desired values.

#Get an OLS model based on output y and the prepared vector X (as in your notation):
model = sm.OLS(endog = y, exog = X )
results = model.fit()
#Get two-tailed t-values:
(t_minus, t_plus) = stats.t.interval(alpha = (1.0 - sl), df =  len(results.resid) - len(x0) )
y_value_at_x0 = np.dot(results.params, x0)
lower_bound = y_value_at_x0 + t_minus*np.sqrt(results.mse_resid*( np.dot(np.dot(x0.T,results.normalized_cov_params),x0) ))
upper_bound = y_value_at_x0 +  t_plus*np.sqrt(results.mse_resid*( np.dot(np.dot(x0.T,results.normalized_cov_params),x0) ))

You can wrap a nice function around this with input results, point x0 and significance level sl.

I am unsure now if you can use this for WLS() since there are extra things happening there.

Ref: Ch3 in [D.C. Montgomery and E.A. Peck. “Introduction to Linear Regression Analysis.” 4th. Ed., Wiley, 1992].

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