library(graphicalMCP)
library(lrstat)
library(gMCP)There are two R packages that cover graphical multiple comparison
procedures (MCPs): gMCP (Rohmeyer
and Klinglmueller 2024) and lrstat (Lu 2023). The development of
graphicalMCP benefited from these two packages. Here we
provide some comparisons between graphicalMCP and other
packages with respect to key functions.
graphicalMCP::graph_generate_weights()gMCP::generateWeights()graphicalMCP::graph_test_shortcut()gMCP::gMCP()graphicalMCP::graph_calculate_power()gMCP::calcPower()graphicalMCP::graph_test_closure()gMCP::gMCP()graphicalMCP::graph_calculate_power()gMCP::calcPower()graphicalMCP::graph_test_closure()gMCP::gMCP()graphicalMCP::graph_calculate_power()gMCP::calcPower()A random graph for five hypotheses will be generated and used for the
comparison. Weighting strategies from the following two functions will
be compared: graphicalMCP::graph_generate_weights() and
gMCP::generateWeights(). This process is repeated 1000
times. Weighting strategies are matched for all 1000 cases.
set.seed(1234)
identical <- NULL
for (i in 1:1000) {
graph <- random_graph(5)
graphicalmcp_weights <- graphicalMCP::graph_generate_weights(graph)
dimnames(graphicalmcp_weights) <- list(NULL, NULL)
gmcp_weights <-
gMCP::generateWeights(graph$transitions, graph$hypotheses)
gmcp_weights <- gmcp_weights[nrow(gmcp_weights):1, ] # Reorder rows
identical <- c(
identical,
all.equal(gmcp_weights, graphicalmcp_weights, tolerance = 1e-7)
)
}
all(identical)
#> [1] TRUEA random graph for five hypotheses will be generated and used for the
comparison. A set of p-values is randomly generated to be used for the
graphical MCP. Adjusted p-values are calculated and compared using the
following functions: graphicalMCP::graph_test_shortcut()
and gMCP::gMCP(). This process is repeated 10000 times.
Adjusted p-values are matched for all 10000 cases.
set.seed(1234)
alpha <- 0.025
identical <- NULL
for (i in 1:10000) {
graph <- random_graph(5)
p <- runif(5, 0, alpha)
graphicalmcp_test_shortcut <-
graph_test_shortcut(graph, p, alpha = alpha)$outputs$adjusted_p
gmcp_test_shortcut <-
gMCP(as_graphMCP(graph), p, alpha = alpha)@adjPValues
identical <- c(
identical,
all.equal(graphicalmcp_test_shortcut, gmcp_test_shortcut, tolerance = 1e-7)
)
}
all(identical)
#> [1] TRUEA random graph for five hypotheses will be generated and used for the
comparison. A set of marginal power (without multiplicity adjustment) is
randomly generated. Local power (with multiplicity adjustment) is
calculated and compared using the following functions:
graphicalMCP::graph_calculate_power() and
gMCP::calcPower(). Since different simulation methods are
used, results are slightly different. The maximum absolute difference in
local power is 0.0051 (0.51%) among 1000 cases, which is relatively
small.
set.seed(1234)
alpha <- 0.025
sim_corr <- matrix(.5, 5, 5)
diag(sim_corr) <- 1
graphicalmcp_power <- NULL
gmcp_power <- NULL
for (i in 1:1000) {
graph <- random_graph(5)
marginal_power <- runif(5, 0.5, 0.9)
noncentrality_parameter <-
qnorm(1 - 0.025, lower.tail = TRUE) -
qnorm(1 - marginal_power, lower.tail = TRUE)
set.seed(1234 + i - 1)
graphicalmcp_power <- rbind(
graphicalmcp_power,
graph_calculate_power(
graph,
alpha = alpha,
power_marginal = marginal_power,
sim_corr = sim_corr,
sim_n = 2^17
)$power$power_local
)
set.seed(1234 + i - 1)
gmcp_power <- rbind(
gmcp_power,
calcPower(
graph$hypotheses,
alpha = alpha,
graph$transitions,
mean = noncentrality_parameter,
corr.sim = sim_corr,
n.sim = 2^17
)$LocalPower
)
}
diff <- data.frame(
rbind(graphicalmcp_power, gmcp_power),
procedure = rep(c("graphicalMCP", "gMCP"), each = nrow(graphicalmcp_power))
)
write.csv(
diff,
here::here("vignettes/cache/comparisons_power_shortcut.csv"),
row.names = FALSE
)
diff <- read.csv(here::here("vignettes/cache/comparisons_power_shortcut.csv"))
graphicalmcp_power <- subset(diff, procedure == "graphicalMCP")
gmcp_power <- subset(diff, procedure == "gMCP")
round(
max(
abs(
graphicalmcp_power[, -ncol(graphicalmcp_power)] -
gmcp_power[, -ncol(gmcp_power)]
)
),
4
) # Maximum difference in local power among 1000 casesA successive graph with two primary and two secondary hypotheses will
be generated and used for the comparison. A set of p-values is randomly
generated to be used for the graphical MCP. Adjusted p-values are
calculated and compared using the following functions:
graphicalMCP::graph_test_closure() and
gMCP::gMCP(). Parametric tests are used for two primary
hypotheses. This process is repeated 10000 times. Adjusted p-values are
matched for all 10000 cases.
hypotheses <- c(0.5, 0.5, 0, 0)
transitions <- rbind(
c(0, 0.5, 0.5, 0),
c(0.5, 0, 0, 0.5),
c(0, 1, 0, 0),
c(1, 0, 0, 0)
)
graph <- graph_create(hypotheses, transitions)
set.seed(1234)
alpha <- 0.025
identical <- NULL
test_corr <- rbind(
c(1, 0.5, NA, NA),
c(0.5, 1, NA, NA),
c(NA, NA, 1, NA),
c(NA, NA, NA, 1)
)
for (i in 1:10000) {
p <- runif(4, 0, alpha)
graphicalmcp_test_parametric <- graph_test_closure(
graph,
p,
alpha = alpha,
test_groups = list(1:2, 3:4),
test_types = c("parametric", "bonferroni"),
test_corr = list(test_corr[1:2, 1:2], NA)
)$outputs$adjusted_p
gmcp_test_parametric <- gMCP(
as_graphMCP(graph),
p,
alpha = 0.025,
correlation = test_corr
)@adjPValues
identical <- c(
identical,
all.equal(graphicalmcp_test_parametric, gmcp_test_parametric, tolerance = 1e-7)
)
}
all(identical)
#> [1] TRUEA successive graph with two primary and two secondary hypotheses will
be generated and used for the comparison. A set of marginal power
(without multiplicity adjustment) is randomly generated. Local power
(with multiplicity adjustment) is calculated and compared using the
following functions: graphicalMCP::graph_calculate_power()
and gMCP::calcPower(). Parametric tests are used for two
primary hypotheses. This process is repeated 100 times. Since different
simulation methods are used, results are slightly different. The maximum
absolute difference in local power is 0.0142 (1.42%) among 100 cases,
which is small.
hypotheses <- c(0.5, 0.5, 0, 0)
transitions <- rbind(
c(0, 0.5, 0.5, 0),
c(0.5, 0, 0, 0.5),
c(0, 1, 0, 0),
c(1, 0, 0, 0)
)
graph <- graph_create(hypotheses, transitions)
test_corr <- rbind(
c(1, 0.5, NA, NA),
c(0.5, 1, NA, NA),
c(NA, NA, 1, NA),
c(NA, NA, NA, 1)
)
sim_corr <- matrix(0.5, 4, 4)
diag(sim_corr) <- 1
set.seed(1234)
alpha <- 0.025
graphicalmcp_power_parametric <- NULL
gmcp_power_parametric <- NULL
for (i in 1:100) {
marginal_power <- runif(4, 0.5, 0.9)
noncentrality_parameter <-
qnorm(1 - 0.025, lower.tail = TRUE) -
qnorm(1 - marginal_power, lower.tail = TRUE)
set.seed(1234 + i - 1)
graphicalmcp_power_parametric <- rbind(
graphicalmcp_power_parametric,
graph_calculate_power(
graph,
alpha = alpha,
test_groups = list(1:2, 3:4),
test_types = c("parametric", "bonferroni"),
test_corr = list(test_corr[1:2, 1:2], NA),
power_marginal = marginal_power,
sim_corr = sim_corr,
sim_n = 2^14
)$power$power_local
)
set.seed(1234 + i - 1)
gmcp_power_parametric <- rbind(
gmcp_power_parametric,
calcPower(
graph$hypotheses,
alpha = alpha,
graph$transitions,
corr.test = test_corr,
mean = noncentrality_parameter,
corr.sim = sim_corr,
n.sim = 2^14
)$LocalPower
)
}
diff <- data.frame(
rbind(graphicalmcp_power_parametric, gmcp_power_parametric),
procedure = rep(c("graphicalMCP", "gMCP"), each = nrow(gmcp_power_parametric))
)
write.csv(
diff,
here::here("vignettes/cache/comparisons_power_parametric.csv"),
row.names = FALSE
)
diff <- read.csv(here::here("vignettes/cache/comparisons_power_parametric.csv"))
graphicalmcp_power <- subset(diff, procedure == "graphicalMCP")
gmcp_power <- subset(diff, procedure == "gMCP")
round(
max(
abs(
graphicalmcp_power_parametric[, -ncol(graphicalmcp_power_parametric)] -
gmcp_power_parametric[, -ncol(gmcp_power)]
)
),
4
) # Maximum difference in local power among 100 casesA successive graph with two primary and two secondary hypotheses will
be generated and used for the comparison. A set of p-values is randomly
generated to be used for the graphical MCP. Adjusted p-values are
calculated and compared using the following functions:
graphicalMCP::graph_test_closure() and
lrstat::fadjpsim(). Simes tests are used for two primary
hypotheses. This process is repeated 10000 times. Adjusted p-values are
matched for all 10000 cases.
hypotheses <- c(0.5, 0.5, 0, 0)
eps <- 0.0001
transitions <- rbind(
c(0, 1 - eps, eps, 0),
c(1 - eps, 0, 0, eps),
c(0, 1, 0, 0),
c(1, 0, 0, 0)
)
graph <- graph_create(hypotheses, transitions)
set.seed(1234)
alpha <- 0.025
identical <- NULL
family <- rbind(
c(1, 1, 0, 0),
c(0, 0, 1, 0),
c(0, 0, 0, 1)
)
for (i in 1:10000) {
p <- runif(4, 0, alpha)
graphicalmcp_test_simes <- graph_test_closure(
graph,
p,
alpha = alpha,
test_groups = list(1:2, 3:4),
test_types = c("simes", "bonferroni")
)$outputs$adjusted_p
names(graphicalmcp_test_simes) <- NULL
lrstat_test_simes <-
fadjpsim(
fwgtmat(graph$hypotheses, graph$transitions),
p,
family
)
identical <- c(
identical,
all.equal(graphicalmcp_test_simes, lrstat_test_simes, tolerance = 1e-7)
)
}
all(identical)
#> [1] TRUEPower simulations are not available in lrstat. Thus a
comparison could be done to compare
graphicalMCP::graph_calculate_power() and a manual
repetition of lrstat::fadjpsim() for many sets of marginal
power. This process is the same as the above comparison of adjusted
p-values, and thus omitted.