sc.studentt2: Scaled Student t Distribution with 2 df Family Function
In VGAM: Vector Generalized Linear and Additive Models
sc.studentt2 R Documentation
Scaled Student t Distribution with 2 df Family Function
Description
Estimates the location and scale parameters of
a scaled Student t distribution with 2 degrees of freedom,
by maximum likelihood estimation.
Usage
sc.studentt2(percentile = 50, llocation = "identitylink",
lscale = "loglink", ilocation = NULL, iscale = NULL,
imethod = 1, zero = "scale")
Arguments
percentile
A numerical vector containing values between 0 and 100,
which are the quantiles and expectiles.
They will be returned as ‘fitted values’.
llocation, lscale
See Links for more choices,
and CommonVGAMffArguments.
ilocation, iscale, imethod, zero
See CommonVGAMffArguments for details.
Details
Koenker (1993) solved for the distribution whose quantiles are
equal to its expectiles.
Its canonical form has mean and mode at 0,
and has a heavy tail (in fact, its variance is infinite).
The standard (“canonical”) form of this
distribution can be endowed with a location and scale parameter.
The standard form has a density
that can be written as
f(z) = 2 / (4 + z^2)^{3/2}
for real y.
Then z = (y-a)/b for location and scale parameters
a and b > 0.
The mean of Y is a.
By default, \eta_1=a) and
\eta_2=\log(b).
The expectiles/quantiles corresponding to percentile
are returned as the fitted values;
in particular, percentile = 50 corresponds to the mean
(0.5 expectile) and median (0.5 quantile).
Note that if Y has a standard dsc.t2
then Y = \sqrt{2} T_2 where T_2
has a Student-t distribution with 2 degrees of freedom.
The two parameters here can also be estimated using
studentt2 by specifying df = 2 and making
an adjustment for the scale parameter, however, this VGAM
family function is more efficient since the EIM is known
(Fisher scoring is implemented.)
Value
An object of class "vglmff" (see vglmff-class).
The object is used by modelling functions such as vglm,
rrvglm
and vgam.
Author(s)
T. W. Yee
References
Koenker, R. (1993).
When are expectiles percentiles? (solution)
Econometric Theory,
9, 526–527.
See Also
dsc.t2,
studentt2.
Examples
set.seed(123); nn <- 1000
kdata <- data.frame(x2 = sort(runif(nn)))
kdata <- transform(kdata, mylocat = 1 + 3 * x2,
myscale = 1)
kdata <- transform(kdata, y = rsc.t2(nn, loc = mylocat, scale = myscale))
fit <- vglm(y ~ x2, sc.studentt2(perc = c(1, 50, 99)), data = kdata)
fit2 <- vglm(y ~ x2, studentt2(df = 2), data = kdata) # 'same' as fit
coef(fit, matrix = TRUE)
head(fitted(fit))
head(predict(fit))
# Nice plot of the results
## Not run: plot(y ~ x2, data = kdata, col = "blue", las = 1,
sub = paste("n =", nn),
main = "Fitted quantiles/expectiles using the sc.studentt2() distribution")
matplot(with(kdata, x2), fitted(fit), add = TRUE, type = "l", lwd = 3)
legend("bottomright", lty = 1:3, lwd = 3, legend = colnames(fitted(fit)),
col = 1:3)
## End(Not run)
fit@extra$percentile # Sample quantiles
VGAM documentation built on Sept. 18, 2024, 9:09 a.m.
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| sc.studentt2 | R Documentation |
Scaled Student t Distribution with 2 df Family Function
Description
Estimates the location and scale parameters of a scaled Student t distribution with 2 degrees of freedom, by maximum likelihood estimation.
Usage
sc.studentt2(percentile = 50, llocation = "identitylink",
lscale = "loglink", ilocation = NULL, iscale = NULL,
imethod = 1, zero = "scale")
Arguments
percentile |
A numerical vector containing values between 0 and 100, which are the quantiles and expectiles. They will be returned as ‘fitted values’. |
llocation, lscale |
See |
ilocation, iscale, imethod, zero |
See |
Details
Koenker (1993) solved for the distribution whose quantiles are equal to its expectiles. Its canonical form has mean and mode at 0, and has a heavy tail (in fact, its variance is infinite).
The standard (“canonical”) form of this distribution can be endowed with a location and scale parameter. The standard form has a density that can be written as
f(z) = 2 / (4 + z^2)^{3/2}
for real y.
Then z = (y-a)/b for location and scale parameters
a and b > 0.
The mean of Y is a.
By default, \eta_1=a) and
\eta_2=\log(b).
The expectiles/quantiles corresponding to percentile
are returned as the fitted values;
in particular, percentile = 50 corresponds to the mean
(0.5 expectile) and median (0.5 quantile).
Note that if Y has a standard dsc.t2
then Y = \sqrt{2} T_2 where T_2
has a Student-t distribution with 2 degrees of freedom.
The two parameters here can also be estimated using
studentt2 by specifying df = 2 and making
an adjustment for the scale parameter, however, this VGAM
family function is more efficient since the EIM is known
(Fisher scoring is implemented.)
Value
An object of class "vglmff" (see vglmff-class).
The object is used by modelling functions such as vglm,
rrvglm
and vgam.
Author(s)
T. W. Yee
References
Koenker, R. (1993). When are expectiles percentiles? (solution) Econometric Theory, 9, 526–527.
See Also
dsc.t2,
studentt2.
Examples
set.seed(123); nn <- 1000
kdata <- data.frame(x2 = sort(runif(nn)))
kdata <- transform(kdata, mylocat = 1 + 3 * x2,
myscale = 1)
kdata <- transform(kdata, y = rsc.t2(nn, loc = mylocat, scale = myscale))
fit <- vglm(y ~ x2, sc.studentt2(perc = c(1, 50, 99)), data = kdata)
fit2 <- vglm(y ~ x2, studentt2(df = 2), data = kdata) # 'same' as fit
coef(fit, matrix = TRUE)
head(fitted(fit))
head(predict(fit))
# Nice plot of the results
## Not run: plot(y ~ x2, data = kdata, col = "blue", las = 1,
sub = paste("n =", nn),
main = "Fitted quantiles/expectiles using the sc.studentt2() distribution")
matplot(with(kdata, x2), fitted(fit), add = TRUE, type = "l", lwd = 3)
legend("bottomright", lty = 1:3, lwd = 3, legend = colnames(fitted(fit)),
col = 1:3)
## End(Not run)
fit@extra$percentile # Sample quantiles
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