0th

Percentile

Generate a Quadrature Scheme from a Point Pattern

Generates a quadrature scheme (an object of class "quad") from point patterns of data and dummy points.

Keywords
spatial, datagen
Usage
quadscheme(data, dummy, method="grid", ...)
Arguments
data
The observed data point pattern. An object of class "ppp" or in a format recognised by as.ppp()
dummy
The pattern of dummy points for the quadrature. An object of class "ppp" or in a format recognised by as.ppp() Defaults to default.dummy(data, ...)
method
The name of the method for calculating quadrature weights: either "grid" or "dirichlet".
...
Parameters of the weighting method (see below) and parameters for constructing the dummy points if necessary.
Details

This is the primary method for producing a quadrature schemes for use by ppm. The function ppm fits a point process model to an observed point pattern using the Berman-Turner quadrature approximation (Berman and Turner, 1992; Baddeley and Turner, 2000) to the pseudolikelihood of the model. It requires a quadrature scheme consisting of the original data point pattern, an additional pattern of dummy points, and a vector of quadrature weights for all these points. Such quadrature schemes are represented by objects of class "quad". See quad.object for a description of this class.

Quadrature schemes are created by the function quadscheme. The arguments data and dummy specify the data and dummy points, respectively. There is a sensible default for the dummy points (provided by default.dummy). Alternatively the dummy points may be specified arbitrarily and given in any format recognised by as.ppp. There are also functions for creating dummy patterns including corners, gridcentres, stratrand and spokes. The quadrature region is the region over which we are integrating, and approximating integrals by finite sums. If dummy is a point pattern object (class "ppp") then the quadrature region is taken to be dummy$window. If dummy is just a list of$x, y$coordinates then the quadrature region defaults to the observation window of the data pattern, data$window.

If dummy is missing, then the optional arguments (for ...) include an argument nd. An nd[1] by nd[2] grid of dummy points is generated by default.dummy. If method = "grid" then the optional arguments (for ...) are (nd, ntile). The quadrature region (see below) is divided into an ntile[1] by ntile[2] grid of rectangular tiles. The weight for each quadrature point is the area of a tile divided by the number of quadrature points in that tile. If method="dirichlet" then the optional arguments are (exact=TRUE, nd). The quadrature points (both data and dummy) are used to construct the Dirichlet tessellation. The quadrature weight of each point is the area of its Dirichlet tile inside the quadrature region. If exact == TRUE then this area is computed exactly using the package deldir; otherwise it is computed approximately by discretisation.

Value

• An object of class "quad" describing the quadrature scheme (data points, dummy points, and quadrature weights) suitable as the argument Q of the function ppm() for fitting a point process model.

The quadrature scheme can be inspected using the print and plot methods for objects of class "quad".

References

Baddeley, A. and Turner, R. Practical maximum pseudolikelihood for spatial point patterns. Australian and New Zealand Journal of Statistics 42 (2000) 283--322. Berman, M. and Turner, T.R. Approximating point process likelihoods with GLIM. Applied Statistics 41 (1992) 31--38.

ppm, as.ppp, quad.object, gridweights, dirichlet.weights, corners, gridcentres, stratrand, spokes

Examples
data(simdat)

# grid weights
Q <- quadscheme(simdat, nd=50)           # 1 dummy point per tile
Q <- quadscheme(simdat, ntile=25, nd=50) # 4 dummy points per tile

# Dirichlet weights
D <- runifpoint(250, simdat$window) Q <- quadscheme(simdat, D, method="dirichlet", exact=FALSE) # polygonal window data(demopat) X <- unmark(demopat) Q <- quadscheme(X) # mask window X$window <- as.mask(X\$window)
Q <- quadscheme(X)