kaplan.meier: Kaplan-Meier Estimator using Histogram Data

A list with two elements:

This function is needed mainly for internal use in spatstat, but may be useful in other applications where you want to form the Kaplan-Meier estimator from a huge dataset.

Suppose \(T_i\) are the survival times of individuals \(i=1,\ldots,M\) with unknown distribution function \(F(t)\) which we wish to estimate. Suppose these times are right-censored by random censoring times \(C_i\). Thus the observations consist of right-censored survival times \(\tilde T_i = \min(T_i,C_i)\) and non-censoring indicators \(D_i = 1\{T_i \le C_i\}\) for each \(i\).

If the number of observations \(M\) is large, it is efficient to use histograms. Form the histogram obs of all observed times \(\tilde T_i\). That is, obs[k] counts the number of values \(\tilde T_i\) in the interval (breaks[k],breaks[k+1]] for \(k > 1\) and [breaks[1],breaks[2]] for \(k = 1\). Also form the histogram nco of all uncensored times, i.e. those \(\tilde T_i\) such that \(D_i=1\). These two histograms are the arguments passed to kaplan.meier.

The vectors km and lambda returned by kaplan.meier are (histogram approximations to) the Kaplan-Meier estimator of \(F(t)\) and its hazard rate \(\lambda(t)\). Specifically, km[k] is an estimate of F(breaks[k+1]), and lambda[k] is an estimate of the average of \(\lambda(t)\) over the interval (breaks[k],breaks[k+1]).

The histogram breaks must include \(0\). If the histogram breaks do not span the range of the observations, it is important to count how many survival times \(\tilde T_i\) exceed the rightmost breakpoint, and give this as the value upperobs.