Kmark: Mark-Weighted K Function

An object of class "fv" (see fv.object).

Essentially a data frame containing numeric columns

r

the values of the argument \(r\) at which the mark correlation integral \(K_f(r)\) has been estimated

theo

the theoretical value of \(K_f(r)\) when the marks attached to different points are independent, namely \(\pi r^2\)

together with a column or columns named

"iso" and/or "trans", according to the selected edge corrections. These columns contain estimates of the mark-weighted \(K\) function \(K_f(r)\)

obtained by the edge corrections named (if returnL=FALSE).

The functions Kmark and markcorrint are identical. (Eventually markcorrint will be deprecated.)

The mark-weighted \(K\) function \(K_f(r)\) of a marked point process (Penttinen et al, 1992) is a generalisation of Ripley's \(K\) function, in which the contribution from each pair of points is weighted by a function of their marks. If the marks of the two points are \(m_1, m_2\) then the weight is proportional to \(f(m_1, m_2)\) where \(f\) is a specified test function.

The mark-weighted \(K\) function is defined so that $$ \lambda K_f(r) = \frac{C_f(r)}{E[ f(M_1, M_2) ]} $$ where $$ C_f(r) = E \left[ \sum_{x \in X} f(m(u), m(x)) 1{0 < ||u - x|| \le r} \; \big| \; u \in X \right] $$ for any spatial location \(u\) taken to be a typical point of the point process \(X\). Here \(||u-x||\) is the euclidean distance between \(u\) and \(x\), so that the sum is taken over all random points \(x\) that lie within a distance \(r\) of the point \(u\). The function \(C_f(r)\) is the unnormalised mark-weighted \(K\) function. To obtain \(K_f(r)\) we standardise \(C_f(r)\) by dividing by \(E[f(M_1,M_2)]\), the expected value of \(f(M_1,M_2)\) when \(M_1\) and \(M_2\) are independent random marks with the same distribution as the marks in the point process.

Under the hypothesis of random labelling, the mark-weighted \(K\) function is equal to Ripley's \(K\) function, \(K_f(r) = K(r)\).

The mark-weighted \(K\) function is sometimes called the mark correlation integral because it is related to the mark correlation function \(k_f(r)\) and the pair correlation function \(g(r)\) by $$ K_f(r) = 2 \pi \int_0^r s k_f(s) \, g(s) \, {\rm d}s $$ See markcorr for a definition of the mark correlation function.

Given a marked point pattern X, this command computes edge-corrected estimates of the mark-weighted \(K\) function. If returnL=FALSE then the estimated function \(K_f(r)\) is returned; otherwise the function $$ L_f(r) = \sqrt{K_f(r)/\pi} $$ is returned.