# summary.glm

##### Summarizing Generalized Linear Model Fits

These functions are all `methods`

for class `glm`

or
`summary.glm`

objects.

- Keywords
- models, regression

##### Usage

```
# S3 method for glm
summary(object, dispersion = NULL, correlation = FALSE,
symbolic.cor = FALSE, …)
```# S3 method for summary.glm
print(x, digits = max(3, getOption("digits") - 3),
symbolic.cor = x$symbolic.cor,
signif.stars = getOption("show.signif.stars"), …)

##### Arguments

- object
an object of class

`"glm"`

, usually, a result of a call to`glm`

.- x
an object of class

`"summary.glm"`

, usually, a result of a call to`summary.glm`

.- dispersion
the dispersion parameter for the family used. Either a single numerical value or

`NULL`

(the default), when it is inferred from`object`

(see ‘Details’).- correlation
logical; if

`TRUE`

, the correlation matrix of the estimated parameters is returned and printed.- digits
the number of significant digits to use when printing.

- symbolic.cor
logical. If

`TRUE`

, print the correlations in a symbolic form (see`symnum`

) rather than as numbers.- signif.stars
logical. If

`TRUE`

, ‘significance stars’ are printed for each coefficient.- …
further arguments passed to or from other methods.

##### Details

`print.summary.glm`

tries to be smart about formatting the
coefficients, standard errors, etc. and additionally gives
‘significance stars’ if `signif.stars`

is `TRUE`

.
The `coefficients`

component of the result gives the estimated
coefficients and their estimated standard errors, together with their
ratio. This third column is labelled `t ratio`

if the
dispersion is estimated, and `z ratio`

if the dispersion is known
(or fixed by the family). A fourth column gives the two-tailed
p-value corresponding to the t or z ratio based on a Student t or
Normal reference distribution. (It is possible that the dispersion is
not known and there are no residual degrees of freedom from which to
estimate it. In that case the estimate is `NaN`

.)

Aliased coefficients are omitted in the returned object but restored
by the `print`

method.

Correlations are printed to two decimal places (or symbolically): to
see the actual correlations print `summary(object)$correlation`

directly.

The dispersion of a GLM is not used in the fitting process, but it is
needed to find standard errors.
If `dispersion`

is not supplied or `NULL`

,
the dispersion is taken as `1`

for the `binomial`

and
`Poisson`

families, and otherwise estimated by the residual
Chisquared statistic (calculated from cases with non-zero weights)
divided by the residual degrees of freedom.

`summary`

can be used with Gaussian `glm`

fits to handle the
case of a linear regression with known error variance, something not
handled by `summary.lm`

.

##### Value

`summary.glm`

returns an object of class `"summary.glm"`

, a
list with components

the component from `object`

.

the component from `object`

.

the component from `object`

.

the component from `object`

.

the component from `object`

.

the component from `object`

.

the component from `object`

.

the deviance residuals:
see `residuals.glm`

.

the matrix of coefficients, standard errors, z-values and p-values. Aliased coefficients are omitted.

named logical vector showing if the original coefficients are aliased.

either the supplied argument or the inferred/estimated
dispersion if the latter is `NULL`

.

a 3-vector of the rank of the model and the number of residual degrees of freedom, plus number of coefficients (including aliased ones).

the unscaled (`dispersion = 1`

) estimated covariance
matrix of the estimated coefficients.

ditto, scaled by `dispersion`

.

(only if `correlation`

is true.) The estimated
correlations of the estimated coefficients.

(only if `correlation`

is true.) The value
of the argument `symbolic.cor`

.

##### See Also

##### Examples

`library(stats)`

```
# NOT RUN {
## For examples see example(glm)
# }
```

*Documentation reproduced from package stats, version 3.6.0, License: Part of R 3.6.0*