R Dataset / Package HistData / MacdonellDF

On this R-data statistics page, you will find information about the MacdonellDF data set which pertains to Macdonell's Data on Height and Finger Length of Criminals, used by Gosset (1908). The MacdonellDF data set is found in the HistData R package. You can load the MacdonellDF data set in R by issuing the following command at the console data("MacdonellDF"). This will load the data into a variable called MacdonellDF. If R says the MacdonellDF data set is not found, you can try installing the package by issuing this command install.packages("HistData") and then attempt to reload the data with the library() command. If you need to download R, you can go to the R project website. You can download a CSV (comma separated values) version of the MacdonellDF R data set. The size of this file is about 57,283 bytes.

Macdonell's Data on Height and Finger Length of Criminals, used by Gosset (1908)

Description

In the second issue of Biometrika, W. R. Macdonell (1902) published an extensive paper, On Criminal Anthropometry and the Identification of Criminals in which he included numerous tables of physical characteristics 3000 non-habitual male criminals serving their sentences in England and Wales. His Table III (p. 216) recorded a bivariate frequency distribution of height by finger length. His main purpose was to show that Scotland Yard could have indexed their material more efficiently, and find a given profile more quickly.

W. S. Gosset (aka "Student") used these data in two classic papers in 1908, in which he derived various characteristics of the sampling distributions of the mean, standard deviation and Pearson's r. He said, "Before I had succeeded in solving my problem analytically, I had endeavoured to do so empirically." Among his experiments, he randomly shuffled the 3000 observations from Macdonell's table, and then grouped them into samples of size 4, 8, ..., calculating the sample means, standard deviations and correlations for each sample.

Usage

data(Macdonell)
data(MacdonellDF)

Format

Macdonell: A frequency data frame with 924 observations on the following 3 variables giving the bivariate frequency distribution of height and finger.

height

lower class boundaries of height, in decimal ft.

finger

length of the left middle finger, in mm.

frequency

frequency of this combination of height and finger

MacdonellDF: A data frame with 3000 observations on the following 2 variables.

height

a numeric vector

finger

a numeric vector

Details

Class intervals for height in Macdonell's table were given in 1 in. ranges, from (4' 7" 9/16 - 4' 8" 9/16), to (6' 4" 9/16 - 6' 5" 9/16). The values of height are taken as the lower class boundaries.

For convenience, the data frame MacdonellDF presents the same data, in expanded form, with each combination of height and finger replicated frequency times.

Source

Macdonell, W. R. (1902). On Criminal Anthropometry and the Identification of Criminals. Biometrika, 1(2), 177-227. doi:10.1093/biomet/1.2.177 http://www.jstor.org/stable/2331487

The data used here were obtained from:

Hanley, J. (2008). Macdonell data used by Student. http://www.medicine.mcgill.ca/epidemiology/hanley/Student/

References

Hanley, J. and Julien, M. and Moodie, E. (2008). Student's z, t, and s: What if Gosset had R? The American Statistican, 62(1), 64-69.

Gosett, W. S. [Student] (1908). Probable error of a mean. Biometrika, 6(1), 1-25. http://www.york.ac.uk/depts/maths/histstat/student.pdf

Gosett, W. S. [Student] (1908). Probable error of a correlation coefficient. Biometrika, 6, 302-310.

Examples

data(Macdonell)# display the frequency table
xtabs(frequency ~ finger+round(height,3), data=Macdonell)## Some examples by james.hanley@mcgill.caOctober 16, 2011
## http://www.biostat.mcgill.ca/hanley/
## See:http://www.biostat.mcgill.ca/hanley/Student/###############################################
##naive contour plots of height and finger ##
###############################################
 
# make a 22 x 42 table
attach(Macdonell)
ht <- unique(height) 
fi <- unique(finger)
fr <- t(matrix(frequency, nrow=42))
detach(Macdonell)
dev.new(width=10, height=5)# make plot double wide
op <- par(mfrow=c(1,2),mar=c(0.5,0.5,0.5,0.5),oma=c(2,2,0,0))dx <- 0.5/12
dy <- 0.5/12plot(ht,ht,xlim=c(min(ht)-dx,max(ht)+dx),
 ylim=c(min(fi)-dy,max(fi)+dy), xlab="", ylab="", type="n" )# unpack3000 heights while looping though the frequencies 
heights <- c()
for(i in 1:22) {
for (j in 1:42) {
 f<-fr[i,j]
 if(f>0) heights <- c(heights,rep(ht[i],f))
 if(f>0) text(ht[i], fi[j], toString(f), cex=0.4, col="grey40" ) 
}
}
text(4.65,13.5, "Finger length (cm)",adj=c(0,1), col="black") ;
text(5.75,9.5, "Height (feet)", adj=c(0,1), col="black") ;
text(6.1,11, "Observed bin\nfrequencies", adj=c(0.5,1), col="grey40",cex=0.85) ;
# crude countour plot
contour(ht, fi, fr, add=TRUE, drawlabels=FALSE, col="grey60")
# smoother contour plot (Galton smoothed 2-D frequencies this way)
# [Galton had experience with plotting isobars for meteorological data]
# it was the smoothed plot that made him remember his 'conic sections'
# and ask a mathematician to work out for him the iso-density
# contours of a bivariate Gaussian distribution... dx <- 0.5/12; dy <- 0.05; # shifts caused by averagingplot(ht,ht,xlim=c(min(ht),max(ht)),ylim=c(min(fi),max(fi)), xlab="", ylab="", type="n")
 
sm.fr <- matrix(rep(0,21*41),nrow <- 21)
for(i in 1:21) {
for (j in 1:41) {
 smooth.freq<-(1/4) * sum( fr[i:(i+1), j:(j+1)] ) 
 sm.fr[i,j]<-smooth.freq
 if(smooth.freq > 0 )
 text(ht[i]+dx, fi[j]+dy, sub("^0.", ".",toString(smooth.freq)), cex=0.4, col="grey40" )
 }
}
 
contour(ht[1:21]+dx, fi[1:41]+dy, sm.fr, add=TRUE, drawlabels=FALSE, col="grey60")
text(6.05,11, "Smoothed bin\nfrequencies", adj=c(0.5,1), col="grey40", cex=0.85) ;
par(op)
dev.new()# new default device#######################################
## bivariate kernel density estimate
#######################################if(require(KernSmooth)) {
MDest <- bkde2D(MacdonellDF, bandwidth=c(1/8, 1/8))
contour(x=MDest$x1, y=MDest$x2, z=MDest$fhat,
xlab="Height (feet)", ylab="Finger length (cm)", col="red", lwd=2)
with(MacdonellDF, points(jitter(height), jitter(finger), cex=0.5))
}#############################################################
## sunflower plot of height and finger with data ellipses##
#############################################################with(MacdonellDF, 
{
sunflowerplot(height, finger, size=1/12, seg.col="green3",
xlab="Height (feet)", ylab="Finger length (cm)")
reg <- lm(finger ~ height)
abline(reg, lwd=2)
if(require(car)) {
dataEllipse(height, finger, plot.points=FALSE, levels=c(.40, .68, .95))
}
})
############################################################
## Sampling distributions of sample sd (s) and z=(ybar-mu)/s
############################################################# note that Gosset used a divisor of n (not n-1) to get the sd.
# He also used Sheppard's correction for the 'binning' or grouping.
# with concatenated height measurements...mu <- mean(heights) ; sigma <- sqrt( 3000 * var(heights)/2999 )
c(mu,sigma)# 750 samples of size n=4 (as Gosset did)# see Student's z, t, and s: What if Gosset had R? 
# [Hanley J, Julien M, and Moodie E. The American Statistician, February 2008] # see also the photographs from Student's notebook ('Original small sample data and notes")
# under the link "Gosset' 750 samples of size n=4" 
# on website http://www.biostat.mcgill.ca/hanley/Student/
# and while there, look at the cover of the Notebook containing his yeast-cell counts
# http://www.medicine.mcgill.ca/epidemiology/hanley/Student/750samplesOf4/Covers.JPG
# (Biometrika 1907) and decide for yourself why Gosset, when forced to write under a 
# pen-name, might have taken the name he did!# PS: Can you figure out what the 750 pairs of numbers signify?
# hint: look again at the numbers of rows and columns in Macdonell's (frequency) Table III.
n <- 4
Nsamples <- 750y.bar.values <- s.over.sigma.values <- z.values <- c()
for (samp in 1:Nsamples) {
y <- sample(heights,n)
y.bar <- mean(y)
s<-sqrt( (n/(n-1))*var(y) ) 
z <- (y.bar-mu)/s
y.bar.values <- c(y.bar.values,y.bar) 
s.over.sigma.values <- c(s.over.sigma.values,s/sigma)
z.values <- c(z.values,z)
} 
op <- par(mfrow=c(2,2),mar=c(2.5,2.5,2.5,2.5),oma=c(2,2,0,0))
# sampling distributions
hist(heights,breaks=seq(4.5,6.5,1/12), main="Histogram of heights (N=3000)")
hist(y.bar.values, main=paste("Histogram of y.bar (n=",n,")",sep=""))hist(s.over.sigma.values,breaks=seq(0,4,0.1),
main=paste("Histogram of s/sigma (n=",n,")",sep="")); 
z=seq(-5,5,0.25)+0.125
hist(z.values,breaks=z-0.125, main="Histogram of z=(ybar-mu)/s")
# theoretical
lines(z, 750*0.25*sqrt(n-1)*dt(sqrt(n-1)*z,3), col="red", lwd=1)
par(op)#####################################################
## Chisquare probability plot for bivariate normality
#####################################################mu <- colMeans(MacdonellDF)
sigma <- var(MacdonellDF)
Dsq <- mahalanobis(MacdonellDF, mu, sigma)Q <- qchisq(1:3000/3000, 2)
plot(Q, sort(Dsq), xlab="Chisquare (2) quantile", ylab="Squared distance")
abline(a=0, b=1, col="red", lwd=2)

Dataset imported from https://www.r-project.org.

Attachments: csv, json

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