# library(cateSurvival)
# devtools::install_github("jlstiles/SDE_transport")
# library(Simulations)
library(SDEtransport)
# Functions to generate data for transport:
# make W different for the two sites:
n=1e6
f_W = function(n) {
W1 = rbinom(n, 1, 0.5)
W2 = rbinom(n, 1, 0.4 + 0.2 * W1)
data.frame(W1 = W1, W2 = W2)
}
W = f_W(n)
f_S = function(W) {
with(W, plogis(W1 - W2 + 0.7))
}
P_SW = f_S(W)
S = rbinom(n,1,P_SW)
mean(S)
hist(P_SW, breaks = 200)
max(P_SW)
min(P_SW)
# make a pscore model
f_A = function(S,W) {
df = cbind(S = S, W)
with(df, plogis(-0.6 * S - 0.7 * W1 - W2 + 1))
}
pscores = f_A(S,W)
max(pscores)
min(pscores)
hist(pscores, 200)
A = rbinom(n, 1, pscores)
mean(A)
# make a intermediate confounder model
f_Z = function(A,S,W) {
df = cbind(S=S, W, A = A)
with(df, plogis(0.1 * S - 0.4 * W1 + 0.3 * W2 + 1 * A - 0.3))
}
pzscores = f_Z(A,S,W)
hist(pzscores,200)
Z = rbinom(n, 1, pzscores)
max(pzscores)
# make an M model according to the restrictions
f_M = function(Z,W,S) {
df = cbind(S=S, W, Z = Z)
# with(df, plogis(5*Z*S*W1 - 4))
with(df, plogis(-.14*S - 1*W1 + .5*W2 + 1.2*Z +.1))
}
Mscores = f_M(Z,W,S)
hist(Mscores, 200)
M = rbinom(n, 1, Mscores)
mean(M)
max(Mscores)
min(Mscores)
# make a Y model according to the restrictions
f_Y = function(M,Z,W) {
df = cbind(M=M, Z = Z, W)
with(df, plogis(1 * M + 1.5 * W1 - 0.37 * W2 + 1 * Z - 1))
}
Yscores = f_Y(M,Z,W)
Y = rbinom(n, 1, Yscores)
hist(Yscores, 200)
min(Y*log(Yscores)+(1-Y)*log(1-Yscores))
mean(Y)
max(Yscores)
# pack these functions into a DGP
func_list = list(f_W = f_W, f_S = f_S, f_A = f_A, f_Z = f_Z, f_M = f_M, f_Y = f_Y)
covariates = list(covariates_S = c("W1","W2"),
covariates_A = c("S","W1","W2"),
covariates_Z = c("S","A","W1","W2"),
covariates_M = c("Z","W1","W2"),
covariates_Y = c("M","Z","W1","W2"),
covariates_QZ = c("S","W1","W2"))
sim_kara = function(n, covariates, truth) {
data = gendata.SDEtransport(n,
f_W = truth$f_W,
f_S = truth$f_S,
f_A = truth$f_A,
f_Z = truth$f_Z,
f_M = truth$f_M,
f_Y = truth$f_Y)
test = SDE_tmle3(data, covariates= covariates, truth = truth,
truncate = list(lower =.0001, upper = .9999), glm_only = TRUE,
iptw = TRUE, onestep = TRUE,B=500)
return(test)
}
library(parallel)
B = 500
n=5000
res5000 = mclapply(1:B, FUN = function(x) sim_kara(n, covariates, func_list),
mc.cores = getOption("mc.cores", 24L))
save(res5000, func_list, file = "res5000.RData")
res5000_YMmis.1 = mclapply(1:B, FUN = function(x) sim_kara(n, covariates, func_list),
mc.cores = getOption("mc.cores", 24L))
save(res5000, func_list, file = "res5000.1.RData")
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