totlos.msm: Total length of stay, or expected number of visits

A vector of expected total lengths of stay (totlos.msm), or expected number of visits (envisits.msm), for each transient state.

The expected total length of stay in state \(j\) between times \(t_1\) and \(t_2\), from the point of view of an individual in state \(i\) at time 0, is defined by the integral from \(t_1\) to \(t_2\) of the \(i,j\) entry of the transition probability matrix \(P(t) = Exp(tQ)\), where \(Q\) is the transition intensity matrix.

The corresponding expected number of visits to state \(j\) (excluding the stay in the current state at time 0) is \(\sum_{i!=j} T_i Q_{i,j}\), where \(T_i\) is the expected amount of time spent in state \(i\).

More generally, suppose that \(\pi_0\) is the vector of probabilities of being in each state at time 0, supplied in start, and we want the vector \(\mathbf{x}\) giving the expected lengths of stay in each state. The corresponding integral has the following solution (van Loan 1978; van Rosmalen et al. 2013)

$$\mathbf{x} = \left[ \begin{array}{ll} 1 & \mathbf{0}_K \end{array} \right] Exp(t Q') \left[ \begin{array}{l} \mathbf{0}_K\\I_K \end{array} \right] $$

where $$Q' = \left[ \begin{array}{ll} 0 & \mathbf{\pi}_0\\ \mathbf{0}_K & Q - rI_K \end{array} \right] $$

\(\pi_0\) is the row vector of initial state probabilities supplied in start, \(\mathbf{0}_K\) is the row vector of K zeros, \(r\) is the discount rate, \(I_K\) is the K x K identity matrix, and \(Exp\) is the matrix exponential.

Alternatively, the integrals can be calculated numerically, using the integrate function. This may take a long time for models with many states where \(P(t)\) is expensive to calculate. This is required where tot = Inf, since the package author is not aware of any analytic expression for the limit of the above formula as \(t\) goes to infinity.

With the argument num.integ=TRUE, numerical integration is used even where the analytic solution is available. This facility is just provided for checking results against versions 1.2.4 and earlier, and will be removed eventually. Please let the package maintainer know if any results are different.

For a model where the individual has only one place to go from each state, and each state is visited only once, for example a progressive disease model with no recovery or death, these are equal to the mean sojourn time in each state. However, consider a three-state health-disease-death model with transitions from health to disease, health to death, and disease to death, where everybody starts healthy. In this case the mean sojourn time in the disease state will be greater than the expected length of stay in the disease state. This is because the mean sojourn time in a state is conditional on entering the state, whereas the expected total time diseased is a forecast for a healthy individual, who may die before getting the disease.

In the above formulae, \(Q\) is assumed to be constant over time, but the results generalise easily to piecewise-constant intensities. This function automatically handles models fitted using the pci option to msm. For any other inhomogeneous models, the user must specify piecewise.times and piecewise.covariates arguments to totlos.msm.