Performs the Spatial Scan Test for clustering in a spatial point pattern, or for clustering of one type of point in a bivariate spatial point pattern.
scan.test(X, r, ...,
method = c("poisson", "binomial"),
nsim = 19,
baseline = NULL,
case = 2,
alternative = c("greater", "less", "two.sided"),
verbose = TRUE)
An object of class "htest"
(hypothesis test)
which also belongs to the class "scan.test"
.
Printing this object gives the result of the test.
Plotting this object displays the Likelihood Ratio Test Statistic
as a function of the location of the centre of the circle.
A point pattern (object of class "ppp"
).
Radius of circle to use. A single number or a numeric vector.
Optional. Arguments passed to as.mask
to determine the
spatial resolution of the computations.
Either "poisson"
or "binomial"
specifying the type of likelihood.
Number of simulations for computing Monte Carlo p-value.
Baseline for the Poisson intensity, if method="poisson"
.
A pixel image or a function.
Which type of point should be interpreted as a case,
if method="binomial"
.
Integer or character string.
Alternative hypothesis: "greater"
if the alternative
postulates that the mean number of points inside the circle
will be greater than expected under the null.
Logical. Whether to print progress reports.
Adrian Baddeley Adrian.Baddeley@curtin.edu.au
and Rolf Turner rolfturner@posteo.net
The spatial scan test (Kulldorf, 1997) is applied
to the point pattern X
.
In a nutshell,
If method="poisson"
then
a significant result would mean that there is a circle of radius
r
, located somewhere in the spatial domain of the data,
which contains a significantly higher than
expected number of points of X
. That is, the
pattern X
exhibits spatial clustering.
If method="binomial"
then X
must be a bivariate (two-type)
point pattern. By default, the first type of point is interpreted as
a control (non-event) and the second type of point as a case (event).
A significant result would mean that there is a
circle of radius r
which contains a significantly higher than
expected number of cases. That is, the cases are clustered together,
conditional on the locations of all points.
Following is a more detailed explanation.
If method="poisson"
then the scan test based on Poisson
likelihood is performed (Kulldorf, 1997).
The dataset X
is treated as an unmarked point pattern.
By default (if baseline
is not specified)
the null hypothesis is complete spatial randomness CSR
(i.e. a uniform Poisson process).
The alternative hypothesis is a Poisson process with
one intensity \(\beta_1\) inside some circle of radius
r
and another intensity \(\beta_0\) outside the
circle.
If baseline
is given, then it should be a pixel image
or a function(x,y)
. The null hypothesis is
an inhomogeneous Poisson process with intensity proportional
to baseline
. The alternative hypothesis is an inhomogeneous
Poisson process with intensity
beta1 * baseline
inside some circle of radius r
,
and beta0 * baseline
outside the circle.
If method="binomial"
then the scan test based on
binomial likelihood is performed (Kulldorf, 1997).
The dataset X
must be a bivariate point pattern,
i.e. a multitype point pattern with two types.
The null hypothesis is that all permutations of the type labels are
equally likely.
The alternative hypothesis is that some circle of radius
r
has a higher proportion of points of the second type,
than expected under the null hypothesis.
The result of scan.test
is a hypothesis test
(object of class "htest"
) which can be plotted to
report the results. The component p.value
contains the
\(p\)-value.
The result of scan.test
can also be plotted (using the plot
method for the class "scan.test"
). The plot is
a pixel image of the Likelihood Ratio Test Statistic
(2 times the log likelihood ratio) as a function
of the location of the centre of the circle.
This pixel image can be extracted from the object
using as.im.scan.test
.
The Likelihood Ratio Test Statistic is computed by
scanLRTS
.
Kulldorff, M. (1997) A spatial scan statistic. Communications in Statistics --- Theory and Methods 26, 1481--1496.
plot.scan.test
,
as.im.scan.test
,
relrisk
,
scanLRTS
nsim <- if(interactive()) 19 else 2
rr <- if(interactive()) seq(0.5, 1, by=0.1) else c(0.5, 1)
scan.test(redwood, 0.1 * rr, method="poisson", nsim=nsim)
scan.test(chorley, rr, method="binomial", case="larynx", nsim=nsim)
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