AreaInter: The Area Interaction Point Process Model

• An object of class "interact" describing the interpoint interaction structure of the area-interaction process with disc radius $r$.

The function ppm(), which fits point process models to point pattern data, requires an argument of class "interact" describing the interpoint interaction structure of the model to be fitted. The appropriate description of the area interaction structure is yielded by the function AreaInter(). See the examples below.

In standard form, the area-interaction process (Widom and Rowlinson, 1970; Baddeley and Van Lieshout, 1995) with disc radius $r$, intensity parameter $\kappa$ and interaction parameter $\gamma$ is a point process with probability density $$f(x_1,\ldots,x_n) = \alpha \kappa^{n(x)} \gamma^{-A(x)}$$ where $x_1,\ldots,x_n$ represent the points of the pattern, $n(x)$ is the number of points in the pattern, and $A(x)$ is the area of the region formed by the union of discs of radius $r$ centred at the points $x_1,\ldots,x_n$. Here $\alpha$ is a normalising constant.

The interaction parameter $\gamma$ can be any positive number. If $\gamma = 1$ then the model reduces to a Poisson process with intensity $\kappa$. If $\gamma < 1$ then the process is regular, while if $\gamma > 1$ the process is clustered. Thus, an area interaction process can be used to model either clustered or regular point patterns. Two points interact if the distance between them is less than $2r$.

The standard form of the model, shown above, is a little complicated to interpret in practical applications. For example, each isolated point of the pattern $x$ contributes a factor $\kappa \gamma^{-\pi r^2}$ to the probability density. In spatstat, the model is parametrised in a different form, which is easier to interpret. In canonical scale-free form, the probability density is rewritten as $$f(x_1,\ldots,x_n) = \alpha \beta^{n(x)} \eta^{-C(x)}$$ where $\beta$ is the new intensity parameter, $\eta$ is the new interaction parameter, and $C(x) = B(x) - n(x)$ is the interaction potential. Here $$B(x) = \frac{A(x)}{\pi r^2}$$ is the normalised area (so that the discs have unit area). In this formulation, each isolated point of the pattern contributes a factor $\beta$ to the probability density (so the first order trend is $\beta$). The quantity $C(x)$ is a true interaction potential, in the sense that $C(x) = 0$ if the point pattern $x$ does not contain any points that lie close together (closer than $2r$ units apart).

The old parameters $\kappa,\gamma$ of the standard form are related to the new parameters $\beta,\eta$ of the canonical scale-free form, by $$\beta = \kappa \gamma^{-\pi r^2} = \kappa /\eta$$ and $$\eta = \gamma^{\pi r^2}$$ provided $\gamma$ and $\kappa$ are positive and finite.

In the canonical scale-free form, the parameter $\eta$ can take any nonnegative value. The value $\eta = 1$ again corresponds to a Poisson process, with intensity $\beta$. If $\eta < 1$ then the process is regular, while if $\eta > 1$ the process is clustered. The value $\eta = 0$ corresponds to a hard core process with hard core radius $r$ (interaction distance $2r$). The nonstationary area interaction process is similar except that the contribution of each individual point $x_i$ is a function $\beta(x_i)$ of location, rather than a constant beta. Note the only argument of AreaInter() is the disc radius r. When r is fixed, the model becomes an exponential family. The canonical parameters $\log(\beta)$ and $\log(\eta)$ are estimated by ppm(), not fixed in AreaInter().