# vcov.slrm

##### Variance-Covariance Matrix for a Fitted Spatial Logistic Regression

Returns the variance-covariance matrix of the estimates of the parameters of a point process model that was fitted by spatial logistic regression.

##### Usage

```
## S3 method for class 'slrm':
vcov(object, \dots,
what=c("vcov", "corr", "fisher", "Fisher"))
```

##### Arguments

- object
- A fitted point process model of class
`"slrm"`

. - ...
- Ignored.
- what
- Character string (partially-matched)
that specifies what matrix is returned.
Options are
`"vcov"`

for the variance-covariance matrix,`"corr"`

for the correlation matrix, and`"fisher"`

or`"Fisher"`

##### Details

This function computes the asymptotic variance-covariance
matrix of the estimates of the canonical parameters in the
point process model `object`

. It is a method for the
generic function `vcov`

.

`object`

should be an object of class `"slrm"`

, typically
produced by `slrm`

. It represents a Poisson point process
model fitted by spatial logistic regression.

The canonical parameters of the fitted model `object`

are the quantities returned by `coef.slrm(object)`

.
The function `vcov`

calculates the variance-covariance matrix
for these parameters.
The argument `what`

provides three options:
[object Object],[object Object],[object Object]
In all three cases, the result is a square matrix.
The rows and columns of the matrix correspond to the canonical
parameters given by `coef.slrm(object)`

. The row and column
names of the matrix are also identical to the names in
`coef.slrm(object)`

.

Note that standard errors and 95% confidence intervals for
the coefficients can also be obtained using
`confint(object)`

or `coef(summary(object))`

.

Standard errors for the fitted intensity can be obtained
using `predict.slrm`

.

##### Value

- A square matrix.

##### Error messages

An error message that reports
*system is computationally singular* indicates that the
determinant of the Fisher information matrix was either too large
or too small for reliable numerical calculation.
This can occur because of numerical overflow or
collinearity in the covariates.

##### References

Baddeley, A., Berman, M., Fisher, N.I., Hardegen, A., Milne, R.K.,
Schuhmacher, D., Shah, R. and Turner, R. (2010)
Spatial logistic regression and change-of-support
for spatial Poisson point processes.
*Electronic Journal of Statistics*
**4**, 1151--1201.
{doi: 10.1214/10-EJS581}

##### See Also

`vcov`

for the generic,

`slrm`

for information about fitted models,

`predict.slrm`

for other kinds of calculation about the model,

`confint`

for confidence intervals.

##### Examples

```
X <- rpoispp(42)
fit <- slrm(X ~ x + y)
vcov(fit)
vcov(fit, what="corr")
vcov(fit, what="f")
```

*Documentation reproduced from package spatstat, version 1.34-1, License: GPL (>= 2)*