Abstract
Two random variables X and Y on a common probability space are mutually completely dependent (m.c.d.) if each one is a function of the other with probability one. For continuous X and Y, a natural approach to constructing a measure of dependence is via the distance between the copula of X and Y and the independence copula. We show that this approach depends crucially on the choice of the distance function. For example, the L p-distances, suggested by Schweizer and Wolff, cannot generate a measure of (mutual complete) dependence, since every copula is the uniform limit of copulas linking m.c.d. variables. Instead, we propose to use a modified Sobolev norm, with respect to which mutual complete dependence cannot approximate any other kind of dependence. This Sobolev norm yields the first nonparametric measure of dependence which, among other things, captures precisely the two extremes of dependence, i.e., it equals 0 if and only if X and Y are independent, and 1 if and only if X and Y are m.c.d. Examples are given to illustrate the difference to the Schweizer–Wolff measure.
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References
Darsow WF, Olsen ET (1995) Norms for copulas. Int J Math Math Sci 18(3): 417–436
Darsow WF, Nguyen B, Olsen ET (1992) Copulas and Markov processes. Illinois J Math 36(4): 600–642
Evans LC (1998) Partial differential equations. American Mathematical Society, Providence
Hoeffding W (1994) The collected works of Wassily Hoeffding. Springer, New York
Joe H (1989) Relative entropy measures of multivariate dependence. J Am Stat Assoc 84(405): 157–164
Joe H (1997) Multivariate models and dependence concepts. Chapman & Hall, London
Kimeldorf G, Sampson AR (1978) Monotone dependence. Ann Stat 6(4): 895–903
Lancaster HO (1963) Correlation and complete dependence of random variables. Ann Math Stat 34: 1315–1321
Micheas AC, Zografos K (2006) Measuring stochastic dependence using \({\phi}\) -divergence. J Multivariate Anal 97(3): 765–784
Mikusiński P, Sherwood H, Taylor MD (1992) Shuffles of min. Stochastica 13(1): 61–74
Nelsen RB (2006) An introduction to copulas 2nd edn. Springer, New York
Rényi A (1959) On measures of dependence. Acta Math Acad Sci Hungar 10: 441–451
Scarsini M (1984) On measures of concordance. Stochastica 8(3): 201–218
Schweizer B, Wolff EF (1981) On nonparametric measures of dependence for random variables. Ann Stat 9(4): 879–885
Siburg KF, Stoimenov PA (2008) A scalar product for copulas. J Math Anal Appl 344(1): 429–439
Sklar A (1959) Fonctions de répartition à n dimensions et leurs marges. Publ Inst Stat Univ Paris 8: 229–231
Vitale RA (1990) On stochastic dependence and a class of degenerate distributions. In: Block HW, Sampson AR, Savits TH (eds) Topics in statistical dependence (Somerset, PA, 1987). Inst. Math. Statist. Hayward, CA, pp 459–469
Vitale RA (1991) Approximation by mutually completely dependent processes. J Approx Theory 66(2): 225–228
Zografos K (1998) On a measure of dependence based on Fisher’s information matrix. Comm Stat Theory Methods 27(7): 1715–1728
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Siburg, K.F., Stoimenov, P.A. A measure of mutual complete dependence. Metrika 71, 239–251 (2010). https://doi.org/10.1007/s00184-008-0229-9
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DOI: https://doi.org/10.1007/s00184-008-0229-9