an object of class "lm", usually, a result of a call to lm.

an object of class "summary.lm", usually, a result of a call to summary.lm.

logical; if TRUE, the correlation matrix of the estimated parameters is returned and printed.

the number of significant digits to use when printing.

logical. If TRUE, print the correlations in a symbolic form (see symnum) rather than as numbers.

logical. If TRUE, ‘significance stars’ are printed for each coefficient.

further arguments passed to or from other methods.

the weighted residuals, the usual residuals rescaled by the square root of the weights specified in the call to lm.

a p \times 4 matrix with columns for the estimated coefficient, its standard error, t-statistic and corresponding (two-sided) p-value. Aliased coefficients are omitted.

named logical vector showing if the original coefficients are aliased.

the square root of the estimated variance of the random error

\hat\sigma^2 = \frac{1}{n-p}\sum_i{w_i R_i^2},

where R_i is the i-th residual, residuals[i].

degrees of freedom, a 3-vector (p, n-p, p*), the first being the number of non-aliased coefficients, the last being the total number of coefficients.

(for models including non-intercept terms) a 3-vector with the value of the F-statistic with its numerator and denominator degrees of freedom.

R^2, the ‘fraction of variance explained by the model’,

R^2 = 1 - \frac{\sum_i{R_i^2}}{\sum_i(y_i- y^*)^2},

where y^* is the mean of y_i if there is an intercept and zero otherwise.

the above R^2 statistic ‘adjusted’, penalizing for higher p.

a p \times p matrix of (unscaled) covariances of the \hat\beta_j, j=1, \dots, p.

the correlation matrix corresponding to the above cov.unscaled, if correlation = TRUE is specified.

(only if correlation is true.) The value of the argument symbolic.cor.

from object, if present there.