lgcp.estpcf: Fit a Log-Gaussian Cox Point Process by Minimum Contrast

An object of class "minconfit". There are methods for printing and plotting this object. It contains the following main components:

This algorithm fits a log-Gaussian Cox point process (LGCP) model to a point pattern dataset by the Method of Minimum Contrast, using the estimated pair correlation function of the point pattern.

The shape of the covariance of the LGCP must be specified: the default is the exponential covariance function, but other covariance models can be selected.

The argument X can be either

a point pattern:

An object of class "ppp" representing a point pattern dataset. The pair correlation function of the point pattern will be computed using pcf, and the method of minimum contrast will be applied to this.

a summary statistic:

An object of class "fv" containing the values of a summary statistic, computed for a point pattern dataset. The summary statistic should be the pair correlation function, and this object should have been obtained by a call to pcf or one of its relatives.

The algorithm fits a log-Gaussian Cox point process (LGCP) model to X, by finding the parameters of the LGCP model which give the closest match between the theoretical pair correlation function of the LGCP model and the observed pair correlation function. For a more detailed explanation of the Method of Minimum Contrast, see mincontrast.

The model fitted is a stationary, isotropic log-Gaussian Cox process (Moller and Waagepetersen, 2003, pp. 72-76). To define this process we start with a stationary Gaussian random field \(Z\) in the two-dimensional plane, with constant mean \(\mu\) and covariance function \(C(r)\). Given \(Z\), we generate a Poisson point process \(Y\) with intensity function \(\lambda(u) = \exp(Z(u))\) at location \(u\). Then \(Y\) is a log-Gaussian Cox process.

The theoretical pair correlation function of the LGCP is $$ g(r) = \exp(C(s)) $$ The intensity of the LGCP is $$ \lambda = \exp(\mu + \frac{C(0)}{2}). $$

The covariance function \(C(r)\) takes the form $$ C(r) = \sigma^2 c(r/\alpha) $$ where \(\sigma^2\) and \(\alpha\) are parameters controlling the strength and the scale of autocorrelation, respectively, and \(c(r)\) is a known covariance function determining the shape of the covariance. The strength and scale parameters \(\sigma^2\) and \(\alpha\) will be estimated by the algorithm. The template covariance function \(c(r)\) must be specified as explained below.

In this algorithm, the Method of Minimum Contrast is first used to find optimal values of the parameters \(\sigma^2\) and \(\alpha\). Then the remaining parameter \(\mu\) is inferred from the estimated intensity \(\lambda\).

The template covariance function \(c(r)\) is specified using the argument covmodel. This should be of the form list(model="modelname", …) where modelname is a string identifying the template model as explained below, and … are optional arguments of the form tag=value giving the values of parameters controlling the shape of the template model. The default is the exponential covariance \(c(r) = e^{-r}\) so that the scaled covariance is $$ C(r) = \sigma^2 e^{-r/\alpha}. $$ To determine the template model, the string "modelname" will be prefixed by "RM" and the code will search for a function of this name in the RandomFields package. For a list of available models see RMmodel in the RandomFields package. For example the Matern covariance with exponent \(\nu=0.3\) is specified by covmodel=list(model="matern", nu=0.3) corresponding to the function RMmatern in the RandomFields package.

If the argument lambda is provided, then this is used as the value of \(\lambda\). Otherwise, if X is a point pattern, then \(\lambda\) will be estimated from X. If X is a summary statistic and lambda is missing, then the intensity \(\lambda\) cannot be estimated, and the parameter \(\mu\) will be returned as NA.

The remaining arguments rmin,rmax,q,p control the method of minimum contrast; see mincontrast.

The optimisation algorithm can be controlled through the additional arguments "..." which are passed to the optimisation function optim. For example, to constrain the parameter values to a certain range, use the argument method="L-BFGS-B" to select an optimisation algorithm that respects box constraints, and use the arguments lower and upper to specify (vectors of) minimum and maximum values for each parameter.