hoeffd

0th

Percentile

Matrix of Hoeffding's D Statistics

Computes a matrix of Hoeffding's (1948) D statistics for all possible pairs of columns of a matrix. D is a measure of the distance between F(x,y) and G(x)H(y), where F(x,y) is the joint CDF of X and Y, and G and H are marginal CDFs. Missing values are deleted in pairs rather than deleting all rows of x having any missing variables. The D statistic is robust against a wide variety of alternatives to independence, such as non-monotonic relationships. The larger the value of D, the more dependent are X and Y (for many types of dependencies). D used here is 30 times Hoeffding's original D, and ranges from -0.5 to 1.0 if there are no ties in the data. print.hoeffd prints the information derived by hoeffd. The higher the value of D, the more dependent are x and y. hoeffd also computes the mean and maximum absolute values of the difference between the joint empirical CDF and the product of the marginal empirical CDFs.

Keywords
htest, nonparametric
Usage
hoeffd(x, y)
# S3 method for hoeffd
print(x, …)
Arguments
x

a numeric matrix with at least 5 rows and at least 2 columns (if y is absent), or an object created by hoeffd

y

a numeric vector or matrix which will be concatenated to x

ignored

Details

Uses midranks in case of ties, as described by Hollander and Wolfe. P-values are approximated by linear interpolation on the table in Hollander and Wolfe, which uses the asymptotically equivalent Blum-Kiefer-Rosenblatt statistic. For P<.0001 or >0.5, P values are computed using a well-fitting linear regression function in log P vs. the test statistic. Ranks (but not bivariate ranks) are computed using efficient algorithms (see reference 3).

Value

a list with elements D, the matrix of D statistics, n the matrix of number of observations used in analyzing each pair of variables, and P, the asymptotic P-values. Pairs with fewer than 5 non-missing values have the D statistic set to NA. The diagonals of n are the number of non-NAs for the single variable corresponding to that row and column.

References

Hoeffding W. (1948): A non-parametric test of independence. Ann Math Stat 19:546--57.

Hollander M. and Wolfe D.A. (1973). Nonparametric Statistical Methods, pp. 228--235, 423. New York: Wiley.

Press WH, Flannery BP, Teukolsky SA, Vetterling, WT (1988): Numerical Recipes in C. Cambridge: Cambridge University Press.

rcorr, varclus

• hoeffd
• print.hoeffd
Examples
# NOT RUN {
x <- c(-2, -1, 0, 1, 2)
y <- c(4,   1, 0, 1, 4)
z <- c(1,   2, 3, 4, NA)
q <- c(1,   2, 3, 4, 5)
hoeffd(cbind(x,y,z,q))

# Hoeffding's test can detect even one-to-many dependency
set.seed(1)
x <- seq(-10,10,length=200)
y <- x*sign(runif(200,-1,1))
plot(x,y)
hoeffd(x,y)
# }

Documentation reproduced from package Hmisc, version 4.3-1, License: GPL (>= 2)

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