rxPp {rxode2} | R Documentation |
Simulate a from a Poisson process
Description
Simulate a from a Poisson process
Usage
rxPp(
n,
lambda,
gamma = 1,
prob = NULL,
t0 = 0,
tmax = Inf,
randomOrder = FALSE
)
Arguments
n |
Number of time points to simulate in the Poisson process |
lambda |
Rate of Poisson process |
gamma |
Asymmetry rate of Poisson process. When gamma=1.0, this simulates a homogenous Poisson process. When gamma<1.0, the Poisson process has more events early, when gamma > 1.0, the Poisson process has more events late in the process. When gamma is non-zero, the tmax should not be infinite but indicate the end of the Poisson process to be simulated. In most pharamcometric cases, this will be the end of the study. Internally this uses a rate of: l(t) = lambdagamma(t/tmax)^(gamma-1) |
prob |
When specified, this is a probability function with one argument, time, that gives the probability that a Poisson time t is accepted as a rejection time. |
t0 |
the starting time of the Poisson process |
tmax |
the maximum time of the Poisson process |
randomOrder |
when |
Value
This returns a vector of the Poisson process times; If the dropout is >= tmax, then all the rest of the times are = tmax to indicate the dropout is equal to or after tmax.
Author(s)
Matthew Fidler
Examples
## Sample homogenous Poisson process of rate 1/10
rxPp(10, 1 / 10)
## Sample inhomogenous Poisson rate of 1/10
rxPp(10, 1 / 10, gamma = 2, tmax = 100)
## Typically the Poisson process times are in a sequential order,
## using randomOrder gives the Poisson process in random order
rxPp(10, 1 / 10, gamma = 2, tmax = 10, randomOrder = TRUE)
## This uses an arbitrary function to sample a non-homogenous Poisson process
rxPp(10, 1 / 10, prob = function(x) {
1/(1+abs(x))
})