sfDistribution: Two-parameter Spending Function Families
In gsDesign: Group Sequential Design
sfLogistic R Documentation
Two-parameter Spending Function Families
Description
The functions sfLogistic(), sfNormal(),
sfExtremeValue(), sfExtremeValue2(), sfCauchy(), and
sfBetaDist() are all 2-parameter spending function families. These
provide increased flexibility in some situations where the flexibility of a
one-parameter spending function family is not sufficient. These functions
all allow fitting of two points on a cumulative spending function curve; in
this case, four parameters are specified indicating an x and a y coordinate
for each of 2 points. Normally each of these functions will be passed to
gsDesign() in the parameter sfu for the upper bound or
sfl for the lower bound to specify a spending function family for a
design. In this case, the user does not need to know the calling sequence.
The calling sequence is useful, however, when the user wishes to plot a
spending function as demonstrated in the examples; note, however, that an
automatic \alpha- and \beta-spending function plot
is also available.
sfBetaDist(alpha,t,param) is simply alpha times the incomplete
beta cumulative distribution function with parameters a and b
passed in param evaluated at values passed in t.
The other spending functions take the form
f(t;\alpha,a,b)=\alpha
F(a+bF^{-1}(t))
where F() is a
cumulative distribution function with values > 0 on the real line
(logistic for sfLogistic(), normal for sfNormal(), extreme
value for sfExtremeValue() and Cauchy for sfCauchy()) and
F^{-1}() is its inverse.
For the logistic spending function this simplifies to
f(t;\alpha,a,b)=\alpha (1-(1+e^a(t/(1-t))^b)^{-1}).
For the extreme value distribution with
F(x)=\exp(-\exp(-x))
this
simplifies to
f(t;\alpha,a,b)=\alpha \exp(-e^a (-\ln t)^b).
Since the
extreme value distribution is not symmetric, there is also a version where
the standard distribution is flipped about 0. This is reflected in
sfExtremeValue2() where
F(x)=1-\exp(-\exp(x)).
Usage
sfLogistic(alpha, t, param)
sfBetaDist(alpha, t, param)
sfCauchy(alpha, t, param)
sfExtremeValue(alpha, t, param)
sfExtremeValue2(alpha, t, param)
sfNormal(alpha, t, param)
Arguments
alpha
Real value > 0 and no more than 1. Normally,
alpha=0.025 for one-sided Type I error specification or
alpha=0.1 for Type II error specification. However, this could be set
to 1 if for descriptive purposes you wish to see the proportion of spending
as a function of the proportion of sample size or information.
t
A vector of points with increasing values from 0 to 1, inclusive.
Values of the proportion of sample size or information for which the
spending function will be computed.
param
In the two-parameter specification, sfBetaDist()
requires 2 positive values, while sfLogistic(), sfNormal(),
sfExtremeValue(),
sfExtremeValue2() and sfCauchy() require the first parameter
to be any real value and the second to be a positive value. The four
parameter specification is c(t1,t2,u1,u2) where the objective is that
sf(t1)=alpha*u1 and sf(t2)=alpha*u2. In this
parameterization, all four values must be between 0 and 1 and t1 <
t2, u1 < u2.
Value
An object of type spendfn.
See vignette("SpendingFunctionOverview") for further details.
Note
The gsDesign technical manual is available at
https://keaven.github.io/gsd-tech-manual/.
Author(s)
Keaven Anderson keaven_anderson@merck.com
References
Jennison C and Turnbull BW (2000), Group Sequential
Methods with Applications to Clinical Trials. Boca Raton: Chapman and Hall.
See Also
gsDesign
Examples
library(ggplot2)
# design a 4-analysis trial using a Kim-DeMets spending function
# for both lower and upper bounds
x <- gsDesign(k = 4, sfu = sfPower, sfupar = 3, sfl = sfPower, sflpar = 1.5)
# print the design
x
# plot the alpha- and beta-spending functions
plot(x, plottype = 5)
# start by showing how to fit two points with sfLogistic
# plot the spending function using many points to obtain a smooth curve
# note that curve fits the points x=.1, y=.01 and x=.4, y=.1
# specified in the 3rd parameter of sfLogistic
t <- 0:100 / 100
plot(t, sfLogistic(1, t, c(.1, .4, .01, .1))$spend,
xlab = "Proportion of final sample size",
ylab = "Cumulative Type I error spending",
main = "Logistic Spending Function Examples",
type = "l", cex.main = .9
)
lines(t, sfLogistic(1, t, c(.01, .1, .1, .4))$spend, lty = 2)
# now just give a=0 and b=1 as 3rd parameters for sfLogistic
lines(t, sfLogistic(1, t, c(0, 1))$spend, lty = 3)
# try a couple with unconventional shapes again using
# the xy form in the 3rd parameter
lines(t, sfLogistic(1, t, c(.4, .6, .1, .7))$spend, lty = 4)
lines(t, sfLogistic(1, t, c(.1, .7, .4, .6))$spend, lty = 5)
legend(
x = c(.0, .475), y = c(.76, 1.03), lty = 1:5,
legend = c(
"Fit (.1, 01) and (.4, .1)", "Fit (.01, .1) and (.1, .4)",
"a=0, b=1", "Fit (.4, .1) and (.6, .7)",
"Fit (.1, .4) and (.7, .6)"
)
)
# set up a function to plot comparsons of all
# 2-parameter spending functions
plotsf <- function(alpha, t, param) {
plot(t, sfCauchy(alpha, t, param)$spend,
xlab = "Proportion of enrollment",
ylab = "Cumulative spending", type = "l", lty = 2
)
lines(t, sfExtremeValue(alpha, t, param)$spend, lty = 5)
lines(t, sfLogistic(alpha, t, param)$spend, lty = 1)
lines(t, sfNormal(alpha, t, param)$spend, lty = 3)
lines(t, sfExtremeValue2(alpha, t, param)$spend, lty = 6, col = 2)
lines(t, sfBetaDist(alpha, t, param)$spend, lty = 7, col = 3)
legend(
x = c(.05, .475), y = .025 * c(.55, .9),
lty = c(1, 2, 3, 5, 6, 7),
col = c(1, 1, 1, 1, 2, 3),
legend = c(
"Logistic", "Cauchy", "Normal", "Extreme value",
"Extreme value 2", "Beta distribution"
)
)
}
# do comparison for a design with conservative early spending
# note that Cauchy spending function is quite different
# from the others
param <- c(.25, .5, .05, .1)
plotsf(.025, t, param)
gsDesign documentation built on Sept. 11, 2024, 5:58 p.m.
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| sfLogistic | R Documentation |
Two-parameter Spending Function Families
Description
The functions sfLogistic(), sfNormal(),
sfExtremeValue(), sfExtremeValue2(), sfCauchy(), and
sfBetaDist() are all 2-parameter spending function families. These
provide increased flexibility in some situations where the flexibility of a
one-parameter spending function family is not sufficient. These functions
all allow fitting of two points on a cumulative spending function curve; in
this case, four parameters are specified indicating an x and a y coordinate
for each of 2 points. Normally each of these functions will be passed to
gsDesign() in the parameter sfu for the upper bound or
sfl for the lower bound to specify a spending function family for a
design. In this case, the user does not need to know the calling sequence.
The calling sequence is useful, however, when the user wishes to plot a
spending function as demonstrated in the examples; note, however, that an
automatic \alpha- and \beta-spending function plot
is also available.
sfBetaDist(alpha,t,param) is simply alpha times the incomplete
beta cumulative distribution function with parameters a and b
passed in param evaluated at values passed in t.
The other spending functions take the form
f(t;\alpha,a,b)=\alpha
F(a+bF^{-1}(t))
where F() is a
cumulative distribution function with values > 0 on the real line
(logistic for sfLogistic(), normal for sfNormal(), extreme
value for sfExtremeValue() and Cauchy for sfCauchy()) and
F^{-1}() is its inverse.
For the logistic spending function this simplifies to
f(t;\alpha,a,b)=\alpha (1-(1+e^a(t/(1-t))^b)^{-1}).
For the extreme value distribution with
F(x)=\exp(-\exp(-x))
this simplifies to
f(t;\alpha,a,b)=\alpha \exp(-e^a (-\ln t)^b).
Since the
extreme value distribution is not symmetric, there is also a version where
the standard distribution is flipped about 0. This is reflected in
sfExtremeValue2() where
F(x)=1-\exp(-\exp(x)).
Usage
sfLogistic(alpha, t, param)
sfBetaDist(alpha, t, param)
sfCauchy(alpha, t, param)
sfExtremeValue(alpha, t, param)
sfExtremeValue2(alpha, t, param)
sfNormal(alpha, t, param)
Arguments
alpha |
Real value |
t |
A vector of points with increasing values from 0 to 1, inclusive. Values of the proportion of sample size or information for which the spending function will be computed. |
param |
In the two-parameter specification,
|
Value
An object of type spendfn.
See vignette("SpendingFunctionOverview") for further details.
Note
The gsDesign technical manual is available at https://keaven.github.io/gsd-tech-manual/.
Author(s)
Keaven Anderson keaven_anderson@merck.com
References
Jennison C and Turnbull BW (2000), Group Sequential Methods with Applications to Clinical Trials. Boca Raton: Chapman and Hall.
See Also
gsDesign
Examples
library(ggplot2)
# design a 4-analysis trial using a Kim-DeMets spending function
# for both lower and upper bounds
x <- gsDesign(k = 4, sfu = sfPower, sfupar = 3, sfl = sfPower, sflpar = 1.5)
# print the design
x
# plot the alpha- and beta-spending functions
plot(x, plottype = 5)
# start by showing how to fit two points with sfLogistic
# plot the spending function using many points to obtain a smooth curve
# note that curve fits the points x=.1, y=.01 and x=.4, y=.1
# specified in the 3rd parameter of sfLogistic
t <- 0:100 / 100
plot(t, sfLogistic(1, t, c(.1, .4, .01, .1))$spend,
xlab = "Proportion of final sample size",
ylab = "Cumulative Type I error spending",
main = "Logistic Spending Function Examples",
type = "l", cex.main = .9
)
lines(t, sfLogistic(1, t, c(.01, .1, .1, .4))$spend, lty = 2)
# now just give a=0 and b=1 as 3rd parameters for sfLogistic
lines(t, sfLogistic(1, t, c(0, 1))$spend, lty = 3)
# try a couple with unconventional shapes again using
# the xy form in the 3rd parameter
lines(t, sfLogistic(1, t, c(.4, .6, .1, .7))$spend, lty = 4)
lines(t, sfLogistic(1, t, c(.1, .7, .4, .6))$spend, lty = 5)
legend(
x = c(.0, .475), y = c(.76, 1.03), lty = 1:5,
legend = c(
"Fit (.1, 01) and (.4, .1)", "Fit (.01, .1) and (.1, .4)",
"a=0, b=1", "Fit (.4, .1) and (.6, .7)",
"Fit (.1, .4) and (.7, .6)"
)
)
# set up a function to plot comparsons of all
# 2-parameter spending functions
plotsf <- function(alpha, t, param) {
plot(t, sfCauchy(alpha, t, param)$spend,
xlab = "Proportion of enrollment",
ylab = "Cumulative spending", type = "l", lty = 2
)
lines(t, sfExtremeValue(alpha, t, param)$spend, lty = 5)
lines(t, sfLogistic(alpha, t, param)$spend, lty = 1)
lines(t, sfNormal(alpha, t, param)$spend, lty = 3)
lines(t, sfExtremeValue2(alpha, t, param)$spend, lty = 6, col = 2)
lines(t, sfBetaDist(alpha, t, param)$spend, lty = 7, col = 3)
legend(
x = c(.05, .475), y = .025 * c(.55, .9),
lty = c(1, 2, 3, 5, 6, 7),
col = c(1, 1, 1, 1, 2, 3),
legend = c(
"Logistic", "Cauchy", "Normal", "Extreme value",
"Extreme value 2", "Beta distribution"
)
)
}
# do comparison for a design with conservative early spending
# note that Cauchy spending function is quite different
# from the others
param <- c(.25, .5, .05, .1)
plotsf(.025, t, param)
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