statsmodels.regression.linear_model.RegressionResults¶

class statsmodels.regression.linear_model.RegressionResults(model, params, normalized_cov_params=None, scale=1.0, cov_type='nonrobust', cov_kwds=None, use_t=None, **kwargs)[source]¶

This class summarizes the fit of a linear regression model.

It handles the output of contrasts, estimates of covariance, etc.

Parameters:

modelRegressionModel: The regression model instance.
paramsndarray: The estimated parameters.
normalized_cov_paramsndarray: The normalized covariance parameters.
scalefloat: The estimated scale of the residuals.
cov_typestr: The covariance estimator used in the results.
cov_kwdsdict: Additional keywords used in the covariance specification.
use_tbool: Flag indicating to use the Student’s t in inference.
**kwargs: Additional keyword arguments used to initialize the results.

Attributes:

pinv_wexog: See model class docstring for implementation details.
cov_type: Parameter covariance estimator used for standard errors and t-stats.
df_model: Model degrees of freedom. The number of regressors p. Does not include the constant if one is present.
df_resid: Residual degrees of freedom. n - p - 1, if a constant is present. n - p if a constant is not included.
het_scale: adjusted squared residuals for heteroscedasticity robust standard errors. Is only available after HC#_se or cov_HC# is called. See HC#_se for more information.
history: Estimation history for iterative estimators.
model: A pointer to the model instance that called fit() or results.
params: The linear coefficients that minimize the least squares criterion. This is usually called Beta for the classical linear model.

Methods

`compare_f_test`(restricted)	Use F test to test whether restricted model is correct.
`compare_lm_test`(restricted[, demean, use_lr])	Use Lagrange Multiplier test to test a set of linear restrictions.
`compare_lr_test`(restricted[, large_sample])	Likelihood ratio test to test whether restricted model is correct.
`conf_int`([alpha, cols])	Compute the confidence interval of the fitted parameters.
`cov_params`([r_matrix, column, scale, cov_p, ...])	Compute the variance/covariance matrix.
`f_test`(r_matrix[, cov_p, invcov])	Compute the F-test for a joint linear hypothesis.
`get_prediction`([exog, transform, weights, ...])	Compute prediction results.
`get_robustcov_results`([cov_type, use_t])	Create new results instance with robust covariance as default.
`info_criteria`(crit[, dk_params])	Return an information criterion for the model.
`initialize`(model, params, **kwargs)	Initialize (possibly re-initialize) a Results instance.
`load`(fname)	Load a pickled results instance
`normalized_cov_params`()	See specific model class docstring
`predict`([exog, transform])	Call self.model.predict with self.params as the first argument.
`remove_data`()	Remove data arrays, all nobs arrays from result and model.
`save`(fname[, remove_data])	Save a pickle of this instance.
`scale`()	A scale factor for the covariance matrix.
`summary`([yname, xname, title, alpha, slim])	Summarize the Regression Results.
`summary2`([yname, xname, title, alpha, ...])	Experimental summary function to summarize the regression results.
`t_test`(r_matrix[, cov_p, use_t])	Compute a t-test for a each linear hypothesis of the form Rb = q.
`t_test_pairwise`(term_name[, method, alpha, ...])	Perform pairwise t_test with multiple testing corrected p-values.
`wald_test`(r_matrix[, cov_p, invcov, use_f, ...])	Compute a Wald-test for a joint linear hypothesis.
`wald_test_terms`([skip_single, ...])	Compute a sequence of Wald tests for terms over multiple columns.

Properties

`HC0_se`	White's (1980) heteroskedasticity robust standard errors.
`HC1_se`	MacKinnon and White's (1985) heteroskedasticity robust standard errors.
`HC2_se`	MacKinnon and White's (1985) heteroskedasticity robust standard errors.
`HC3_se`	MacKinnon and White's (1985) heteroskedasticity robust standard errors.
`aic`	Akaike's information criteria.
`bic`	Bayes' information criteria.
`bse`	The standard errors of the parameter estimates.
`centered_tss`	The total (weighted) sum of squares centered about the mean.
`condition_number`	Return condition number of exogenous matrix.
`cov_HC0`	Heteroscedasticity robust covariance matrix.
`cov_HC1`	Heteroscedasticity robust covariance matrix.
`cov_HC2`	Heteroscedasticity robust covariance matrix.
`cov_HC3`	Heteroscedasticity robust covariance matrix.
`eigenvals`	Return eigenvalues sorted in decreasing order.
`ess`	The explained sum of squares.
`f_pvalue`	The p-value of the F-statistic.
`fittedvalues`	The predicted values for the original (unwhitened) design.
`fvalue`	F-statistic of the fully specified model.
`llf`	Log-likelihood of model
`mse_model`	Mean squared error the model.
`mse_resid`	Mean squared error of the residuals.
`mse_total`	Total mean squared error.
`nobs`	Number of observations n.
`pvalues`	The two-tailed p values for the t-stats of the params.
`resid`	The residuals of the model.
`resid_pearson`	Residuals, normalized to have unit variance.
`rsquared`	R-squared of the model.
`rsquared_adj`	Adjusted R-squared.
`ssr`	Sum of squared (whitened) residuals.
`tvalues`	Return the t-statistic for a given parameter estimate.
`uncentered_tss`	Uncentered sum of squares.
`use_t`	Flag indicating to use the Student's distribution in inference.
`wresid`	The residuals of the transformed/whitened regressand and regressor(s).