# reproduce Table 2 from Lu, Luo, & Chen (2008)
tab <- c()
for(J in c(2,4))
for(aJ in (1:4)/10)
for(p1J in c(0, c(1, 3, 5, 7, 9)/10)){
rJ <- 1-aJ
r <- seq(1, rJ, length = J)
# p1J = p^(J-1)
tab <- c(tab, power.mmrm.ar1(rho = p1J^(1/(J-1)), ra = r, sigmaa = 1,
lambda = 1, times = 1:J,
delta = 1, sig.level = 0.05, power = 0.80)$phi1)
}
matrix(tab, ncol = 6, byrow = TRUE)
# approximate simulation results from Table 5 from Lu, Luo, & Chen (2008)
ra <- c(100, 76, 63, 52)/100
rb <- c(100, 87, 81, 78)/100
power.mmrm.ar1(rho=0.6, ra=ra, sigmaa=1, rb = rb,
lambda = sqrt(1.25/1.75), power = 0.904, delta = 0.9
)
power.mmrm.ar1(rho=0.6, ra=ra, sigmaa=1, rb = rb,
lambda = 1.25/1.75, power = 0.910, delta = 0.9
)
power.mmrm.ar1(rho=0.6, ra=ra, sigmaa=1, rb = rb,
lambda = 1, power = 0.903, delta = 0.9
)
power.mmrm.ar1(rho=0.6, ra=ra, sigmaa=1, rb = rb,
lambda = 2, power = 0.904, delta = 0.9
)
power.mmrm.ar1(N=81, ra=ra, sigmaa=1, rb = rb,
lambda = sqrt(1.25/1.75), power = 0.904, delta = 0.9
)
power.mmrm.ar1(N=87, rho=0.6, ra=ra, sigmaa=1, rb = rb,
lambda = 1.25/1.75, power = 0.910
)
power.mmrm.ar1(N=80, rho=0.6, ra=ra, sigmaa=1, rb = rb,
lambda = 1, delta = 0.9
)
power.mmrm.ar1(N=84, rho=0.6, ra=ra, sigmaa=1, rb = rb,
lambda = 2, power = 0.904, delta = 0.9, sig.level = NULL
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