Compute a kernel smoothed intensity function from a point pattern.
# S3 method for ppp
density(x, sigma=NULL, …,
weights=NULL, edge=TRUE, varcov=NULL,
at="pixels", leaveoneout=TRUE,
adjust=1, diggle=FALSE, se=FALSE,
kernel="gaussian",
scalekernel=is.character(kernel),
positive=FALSE, verbose=TRUE)
Point pattern (object of class "ppp"
).
Standard deviation of isotropic smoothing kernel.
Either a numerical value, or a function that computes an
appropriate value of sigma
.
Optional weights to be attached to the points.
A numeric vector, numeric matrix, an expression
,
or a pixel image.
Additional arguments passed to pixellate.ppp
and as.mask
to determine
the pixel resolution, or passed to sigma
if it is a function.
Logical value indicating whether to apply edge correction.
Variance-covariance matrix of anisotropic smoothing kernel.
Incompatible with sigma
.
String specifying whether to compute the intensity values
at a grid of pixel locations (at="pixels"
) or
only at the points of x
(at="points"
).
Logical value indicating whether to compute a leave-one-out
estimator. Applicable only when at="points"
.
Optional. Adjustment factor for the smoothing parameter.
Logical. If TRUE
, use the Jones-Diggle improved edge correction,
which is more accurate but slower to compute than the default
correction.
The smoothing kernel.
A character string specifying the smoothing kernel
(current options are "gaussian"
, "epanechnikov"
,
"quartic"
or "disc"
),
or a pixel image (object of class "im"
)
containing values of the kernel, or a function(x,y)
which
yields values of the kernel.
Logical value.
If scalekernel=TRUE
, then the kernel will be rescaled
to the bandwidth determined by sigma
and varcov
:
this is the default behaviour when kernel
is a character string.
If scalekernel=FALSE
, then sigma
and varcov
will be ignored: this is the default behaviour when kernel
is a
function or a pixel image.
Logical value indicating whether to compute standard errors as well.
Logical value indicating whether to force all density values to
be positive numbers. Default is FALSE
.
Logical value indicating whether to issue warnings about numerical problems and conditions.
By default, the result is
a pixel image (object of class "im"
).
Pixel values are estimated intensity values,
expressed in “points per unit area”.
If at="points"
, the result is a numeric vector
of length equal to the number of points in x
.
Values are estimated intensity values at the points of x
.
In either case, the return value has attributes
"sigma"
and "varcov"
which report the smoothing
bandwidth that was used.
If weights
is a matrix with more than one column, then the
result is a list of images (if at="pixels"
) or a matrix of
numerical values (if at="points"
).
If se=TRUE
, the result is a list with two elements named
estimate
and SE
, each of the format described above.
Negative and zero values of the density estimate are possible
when at="pixels"
because of numerical errors in finite-precision
arithmetic.
By default, density.ppp
does not try to repair such errors.
This would take more computation time and is not always needed.
(Also it would not be appropriate if weights
include negative values.)
To ensure that the resulting density values are always positive,
set positive=TRUE
.
This is a method for the generic function density
.
It computes a fixed-bandwidth kernel estimate
(Diggle, 1985) of the intensity function of the point process
that generated the point pattern x
.
By default it computes the convolution of the
isotropic Gaussian kernel of standard deviation sigma
with point masses at each of the data points in x
.
Anisotropic Gaussian kernels, and non-Gaussian kernels, are also supported.
Each point has unit weight, unless the argument weights
is
given.
If edge=TRUE
, the intensity estimate is corrected for
edge effect bias in one of two ways:
If diggle=FALSE
(the default) the intensity estimate is
correted by dividing it by the convolution of the
Gaussian kernel with the window of observation.
This is the approach originally described in Diggle (1985).
Thus the intensity value at a point \(u\) is
$$
\hat\lambda(u) = e(u) \sum_i k(x_i - u) w_i
$$
where \(k\) is the Gaussian smoothing kernel,
\(e(u)\) is an edge correction factor,
and \(w_i\) are the weights.
If diggle=TRUE
then the code uses the improved edge correction
described by Jones (1993) and Diggle (2010, equation 18.9).
This has been shown to have better performance (Jones, 1993)
but is slightly slower to compute.
The intensity value at a point \(u\) is
$$
\hat\lambda(u) = \sum_i k(x_i - u) w_i e(x_i)
$$
where again \(k\) is the Gaussian smoothing kernel,
\(e(x_i)\) is an edge correction factor,
and \(w_i\) are the weights.
In both cases, the edge correction term \(e(u)\) is the reciprocal of the kernel mass inside the window: $$ \frac{1}{e(u)} = \int_W k(v-u) \, {\rm d}v $$ where \(W\) is the observation window.
By default, smoothing is performed using a Gaussian kernel,
with smoothing bandwidth determined by the arguments
sigma
, varcov
and adjust
.
if sigma
is a single numerical value,
this is taken as the standard deviation of the isotropic Gaussian
kernel.
alternatively sigma
may be a function that computes
an appropriate bandwidth
from the data point pattern by calling sigma(x)
.
To perform automatic bandwidth selection using cross-validation,
it is recommended to use the functions
bw.diggle
,
bw.CvL
,
bw.scott
or
bw.ppl
.
The smoothing kernel may be made anisotropic
by giving the variance-covariance matrix varcov
.
The arguments sigma
and varcov
are incompatible.
Alternatively sigma
may be a vector of length 2 giving the
standard deviations of the \(x\) and \(y\) coordinates,
thus equivalent to varcov = diag(rep(sigma^2, 2))
.
if neither sigma
nor varcov
is specified,
an isotropic Gaussian kernel will be used,
with a default value of sigma
calculated by a simple rule of thumb
that depends only on the size of the window.
The argument adjust
makes it easy for the user to change the
bandwidth specified by any of the rules above.
The value of sigma
will be multiplied by
the factor adjust
. The matrix varcov
will be
multiplied by adjust^2
. To double the smoothing bandwidth, set
adjust=2
.
An infinite bandwidth, sigma=Inf
or adjust=Inf
,
is permitted, and yields an intensity estimate which is constant
over the spatial domain.
The choice of smoothing kernel is determined by the argument kernel
.
This should be a character string giving the name of a recognised
two-dimensional kernel
(current options are "gaussian"
, "epanechnikov"
,
"quartic"
or "disc"
),
or a pixel image (object of class "im"
)
containing values of the kernel, or a function(x,y)
which
yields values of the kernel. The default is a Gaussian kernel.
If scalekernel=TRUE
then the kernel values will be rescaled
according to the arguments sigma
, varcov
and
adjust
as explained above, effectively treating
kernel
as the template kernel with standard deviation equal to 1.
This is the default behaviour when kernel
is a character string.
If scalekernel=FALSE
, the kernel values will not be altered,
and the arguments sigma
, varcov
and adjust
are ignored. This is the default behaviour when kernel
is a
pixel image or a function.
If at="pixels"
(the default), intensity values are
computed at every location \(u\) in a fine grid,
and are returned as a pixel image. The point pattern is first discretised
using pixellate.ppp
, then the intensity is
computed using the Fast Fourier Transform.
Accuracy depends on the pixel resolution and the discretisation rule.
The pixel resolution is controlled by the arguments
…
passed to as.mask
(specify the number of
pixels by dimyx
or the pixel size by eps
).
The discretisation rule is controlled by the arguments
…
passed to pixellate.ppp
(the default rule is that each point is allocated to the nearest
pixel centre; this can be modified using the arguments
fractional
and preserve
).
If at="points"
, the intensity values are computed
to high accuracy at the points of x
only. Computation is
performed by directly evaluating and summing the kernel
contributions without discretising the data. The result is a numeric
vector giving the density values.
The intensity value at a point \(x_i\) is (if diggle=FALSE
)
$$
\hat\lambda(x_i) = e(x_i) \sum_j k(x_j - x_i) w_j
$$
or (if diggle=TRUE
)
$$
\hat\lambda(x_i) = \sum_j k(x_j - x_i) w_j e(x_j)
$$
If leaveoneout=TRUE
(the default), then the sum in the equation
is taken over all \(j\) not equal to \(i\),
so that the intensity value at a
data point is the sum of kernel contributions from
all other data points.
If leaveoneout=FALSE
then the sum is taken over all \(j\),
so that the intensity value at a data point includes a contribution
from the same point.
If weights
is a matrix with more than one column, then the
calculation is effectively repeated for each column of weights. The
result is a list of images (if at="pixels"
) or a matrix of
numerical values (if at="points"
).
The argument weights
can also be an expression
.
It will be evaluated in the data frame as.data.frame(x)
to obtain a vector or matrix of weights. The expression may involve
the symbols x
and y
representing the Cartesian
coordinates, the symbol marks
representing the mark values
if there is only one column of marks, and the names of the columns of
marks if there are several columns.
The argument weights
can also be a pixel image
(object of class "im"
). numerical weights for the data points
will be extracted from this image (by looking up the pixel values
at the locations of the data points in x
).
To select the bandwidth sigma
automatically by
cross-validation, use
bw.diggle
,
bw.CvL
,
bw.scott
or
bw.ppl
.
To perform spatial interpolation of values that were observed
at the points of a point pattern, use Smooth.ppp
.
For adaptive nonparametric estimation, see
adaptive.density
.
For data sharpening, see sharpen.ppp
.
To compute a relative risk surface or probability map for
two (or more) types of points, use relrisk
.
Baddeley, A., Rubak, E. and Turner, R. (2015) Spatial Point Patterns: Methodology and Applications with R. Chapman and Hall/CRC Press.
Diggle, P.J. (1985) A kernel method for smoothing point process data. Applied Statistics (Journal of the Royal Statistical Society, Series C) 34 (1985) 138--147.
Diggle, P.J. (2003) Statistical analysis of spatial point patterns, Second edition. Arnold.
Diggle, P.J. (2010) Nonparametric methods. Chapter 18, pp. 299--316 in A.E. Gelfand, P.J. Diggle, M. Fuentes and P. Guttorp (eds.) Handbook of Spatial Statistics, CRC Press, Boca Raton, FL.
Jones, M.C. (1993) Simple boundary corrections for kernel density estimation. Statistics and Computing 3, 135--146.
bw.diggle
,
bw.CvL
,
bw.scott
bw.ppl
for bandwidth selection.
Smooth.ppp
,
sharpen.ppp
,
adaptive.density
,
relrisk
,
ppp.object
,
im.object
.
# NOT RUN {
if(interactive()) {
opa <- par(mfrow=c(1,2))
plot(density(cells, 0.05))
plot(density(cells, 0.05, diggle=TRUE))
par(opa)
v <- diag(c(0.05, 0.07)^2)
plot(density(cells, varcov=v))
}
# }
# NOT RUN {
Z <- density(cells, 0.05)
Z <- density(cells, 0.05, diggle=TRUE)
Z <- density(cells, 0.05, se=TRUE)
Z <- density(cells, varcov=diag(c(0.05^2, 0.07^2)))
Z <- density(cells, 0.05, weights=data.frame(a=1:42,b=42:1))
Z <- density(cells, 0.05, weights=expression(x))
# }
# NOT RUN {
# automatic bandwidth selection
plot(density(cells, sigma=bw.diggle(cells)))
# equivalent:
plot(density(cells, bw.diggle))
# evaluate intensity at points
density(cells, 0.05, at="points")
plot(density(cells, sigma=0.4, kernel="epanechnikov"))
# relative risk calculation by hand (see relrisk.ppp)
lung <- split(chorley)$lung
larynx <- split(chorley)$larynx
D <- density(lung, sigma=2)
plot(density(larynx, sigma=2, weights=1/D))
# }
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