Partial Residuals for Point Process Model

Computes the smoothed partial residuals, a diagnostic for transformation of a covariate in a Poisson point process model.

models, spatial
parres(model, covariate, ...,
       smooth.effect=FALSE, subregion=NULL,
       bw = "nrd0", adjust=1, from = NULL, to = NULL, n = 512,
       bw.input = c("points", "quad"), bw.restrict=FALSE, covname)
Fitted point process model (object of class "ppm").
The covariate of interest. Either a character string matching the name of one of the canonical covariates in the model, or one of the names "x" or "y" referring to the Cartesian coordinates, or one of the names of
Logical. Determines the choice of algorithm. See Details.
Optional. A window (object of class "owin") specifying a subset of the spatial domain of the data. The calculation will be confined to the data in this subregion.
Smoothing bandwidth or bandwidth rule (passed to density.default).
Smoothing bandwidth adjustment factor (passed to density.default).
n, from, to
Arguments passed to density.default to control the number and range of values at which the function will be estimated.
Additional arguments passed to density.default.
Character string specifying the input data used for automatic bandwidth selection.
Logical value, specifying whether bandwidth selection is performed using data from the entire spatial domain or from the subregion.
Optional. Character string to use as the name of the covariate.

This command computes the smoothed partial residual diagnostic (Baddeley, Chang, Song and Turner, 2012) for the transformation of a covariate in a Poisson point process model. The argument model must be a fitted Poisson point process model. The diagnostic works in two different ways: [object Object],[object Object] Alternatively covariate can be one of the character strings "x" or "y" signifying the Cartesian coordinates. The behaviour here depends on whether the coordinate was one of the canonical covariates in the model.

If there is more than one canonical covariate in the model that depends on the specified covariate, then the covariate effect is computed using all these canonical covariates. For example in a log-quadratic model which includes the terms x and I(x^2), the quadratic effect involving both these terms will be computed.

There are two choices for the algorithm. If smooth.effect=TRUE, the fitted covariate effect (according to model) is added to the point process residuals, then smoothing is applied to these values. If smooth.effect=FALSE, the point process residuals are smoothed first, and then the fitted covariate effect is added to the result.

The smoothing bandwidth is controlled by the arguments bw, adjust, bw.input and bw.restrict. If bw is a numeric value, then the bandwidth is taken to be adjust * bw. If bw is a string representing a bandwidth selection rule (recognised by density.default) then the bandwidth is selected by this rule.

The data used for automatic bandwidth selection are specified by bw.input and bw.restrict. If bw.input="points" (the default) then bandwidth selection is based on the covariate values at the points of the original point pattern dataset to which the model was fitted. If bw.input="quad" then bandwidth selection is based on the covariate values at every quadrature point used to fit the model. If bw.restrict=TRUE then the bandwidth selection is performed using only data from inside the subregion.


  • A function value table (object of class "fv") containing the values of the smoothed partial residual, the estimated variance, and the fitted effect of the covariate. Also belongs to the class "parres" which has methods for print and plot.


Baddeley, A. and Chang, Y.-M. and Song, Y. and Turner, R. (2012) Residual diagnostics for covariate effects in spatial point process models. Submitted for publication.

See Also

addvar, rhohat, rho2hat

  • parres
X <-  rpoispp(function(x,y){exp(3+x+2*x^2)})
  model <- ppm(X, ~x+y)
  tra <- parres(model, "x")
  plot(parres(model, "x", subregion=square(0.5)))
  model2 <- ppm(X, ~x+I(x^2)+y)
  plot(parres(model2, "x"))
  Z <- setcov(owin())
  plot(parres(model2, Z))
Documentation reproduced from package spatstat, version 1.34-1, License: GPL (>= 2)

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