meanAD: The Mean Absolute Deviation
In stamats/MKdescr: Descriptive Statistics
meanAD R Documentation
The Mean Absolute Deviation
Description
Computes (standardized) mean absolute deviation.
Usage
meanAD(x, na.rm = FALSE, constant = sqrt(pi/2))
Arguments
x
a numeric vector.
na.rm
logical. Should missing values be removed?
constant
standardizing contant; see details below.
Details
The mean absolute deviation is a consistent estimator of
\sqrt{2/\pi}\sigma for the standard deviation of
a normal distribution. Under minor deviations of the normal distributions
its asymptotic variance is smaller than that of the sample standard
deviation (Tukey (1960)).
It works well under the assumption of symmetric, where mean and median
coincide. Under the normal distribution it's about 18% more efficient
(asymptotic relative efficiency) than the median absolute deviation
((1/qnorm(0.75))/sqrt(pi/2)) and about 12% less efficient than the
sample standard deviation (Tukey (1960)).
Author(s)
Matthias Kohl Matthias.Kohl@stamats.de
References
Tukey, J. W. (1960). A survey of sampling from contaminated distribution.
In Olkin, I., editor, Contributions to Probability and Statistics.
Essays in Honor of H. Hotelling., pages 448-485. Stanford University Press.
See Also
sd, mad, sIQR.
Examples
## right skewed data
## mean absolute deviation
meanAD(rivers)
## standardized IQR
sIQR(rivers)
## median absolute deviation
mad(rivers)
## sample standard deviation
sd(rivers)
## for normal data
x <- rnorm(100)
sd(x)
sIQR(x)
mad(x)
meanAD(x)
## Asymptotic relative efficiency for Tukey's symmetric gross-error model
## (1-eps)*Norm(mean, sd = sigma) + eps*Norm(mean, sd = 3*sigma)
eps <- seq(from = 0, to = 1, by = 0.001)
ARE <- function(eps){
0.25*((3*(1+80*eps))/((1+8*eps)^2)-1)/(pi*(1+8*eps)/(2*(1+2*eps)^2)-1)
}
plot(eps, ARE(eps), type = "l", xlab = "Proportion of gross-errors",
ylab = "Asymptotic relative efficiency",
main = "ARE of mean absolute deviation w.r.t. sample standard deviation")
abline(h = 1.0, col = "red")
text(x = 0.5, y = 1.5, "Mean absolute deviation is better", col = "red",
cex = 1, font = 1)
## lower bound of interval
uniroot(function(x){ ARE(x)-1 }, interval = c(0, 0.002))
## upper bound of interval
uniroot(function(x){ ARE(x)-1 }, interval = c(0.5, 0.55))
## worst case
optimize(ARE, interval = c(0,1), maximum = TRUE)
stamats/MKdescr documentation built on Feb. 24, 2024, 2:11 p.m.
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| meanAD | R Documentation |
The Mean Absolute Deviation
Description
Computes (standardized) mean absolute deviation.
Usage
meanAD(x, na.rm = FALSE, constant = sqrt(pi/2))
Arguments
x |
a numeric vector. |
na.rm |
logical. Should missing values be removed? |
constant |
standardizing contant; see details below. |
Details
The mean absolute deviation is a consistent estimator of
\sqrt{2/\pi}\sigma for the standard deviation of
a normal distribution. Under minor deviations of the normal distributions
its asymptotic variance is smaller than that of the sample standard
deviation (Tukey (1960)).
It works well under the assumption of symmetric, where mean and median
coincide. Under the normal distribution it's about 18% more efficient
(asymptotic relative efficiency) than the median absolute deviation
((1/qnorm(0.75))/sqrt(pi/2)) and about 12% less efficient than the
sample standard deviation (Tukey (1960)).
Author(s)
Matthias Kohl Matthias.Kohl@stamats.de
References
Tukey, J. W. (1960). A survey of sampling from contaminated distribution. In Olkin, I., editor, Contributions to Probability and Statistics. Essays in Honor of H. Hotelling., pages 448-485. Stanford University Press.
See Also
sd, mad, sIQR.
Examples
## right skewed data
## mean absolute deviation
meanAD(rivers)
## standardized IQR
sIQR(rivers)
## median absolute deviation
mad(rivers)
## sample standard deviation
sd(rivers)
## for normal data
x <- rnorm(100)
sd(x)
sIQR(x)
mad(x)
meanAD(x)
## Asymptotic relative efficiency for Tukey's symmetric gross-error model
## (1-eps)*Norm(mean, sd = sigma) + eps*Norm(mean, sd = 3*sigma)
eps <- seq(from = 0, to = 1, by = 0.001)
ARE <- function(eps){
0.25*((3*(1+80*eps))/((1+8*eps)^2)-1)/(pi*(1+8*eps)/(2*(1+2*eps)^2)-1)
}
plot(eps, ARE(eps), type = "l", xlab = "Proportion of gross-errors",
ylab = "Asymptotic relative efficiency",
main = "ARE of mean absolute deviation w.r.t. sample standard deviation")
abline(h = 1.0, col = "red")
text(x = 0.5, y = 1.5, "Mean absolute deviation is better", col = "red",
cex = 1, font = 1)
## lower bound of interval
uniroot(function(x){ ARE(x)-1 }, interval = c(0, 0.002))
## upper bound of interval
uniroot(function(x){ ARE(x)-1 }, interval = c(0.5, 0.55))
## worst case
optimize(ARE, interval = c(0,1), maximum = TRUE)
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