Difference between revisions of "Fishburn-Shepp inequality"
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| + | ''$xyz$ inequality'' | ||
| − | An inequality for linear extensions of a finite [[Partially ordered set|partially ordered set]] | + | An inequality for linear extensions of a finite [[Partially ordered set|partially ordered set]] $(X,\prec)$. Elements $x,y\in X$ are incomparable if $x\neq y$ and neither $x\prec y$ nor $y\prec x$. Denote by $<_0$ a generic linear order extension of $\prec$ on $X$, let $N$ be the number of linear extensions $<_0$, and let $N(a_1<_0b_1,\ldots,a_n<_0b_n)$ be the number of linear extensions in which $a_i<_0b_i$ for $i=1,\ldots,n$. |
| − | The Fishburn–Shepp inequality says that if | + | The Fishburn–Shepp inequality says that if $x$, $y$ and $z$ are mutually incomparable members of $(X,\prec)$, then |
| − | < | + | $$N(x<_0 y)N(x<_0 z)<N(x<_0 y,x<_0 z)N.$$ |
| − | This was first proved for | + | This was first proved for $\leq$ in [[#References|[a3]]], then for $<$ in [[#References|[a2]]]. The [[Ahlswede–Daykin inequality|Ahlswede–Daykin inequality]] [[#References|[a1]]] plays a key role in the proof. |
The inequality is also written as | The inequality is also written as | ||
| − | < | + | $$\mu(x<_0y)\mu(x<_0z)<\mu(x<_0y,x<_0z),$$ |
| − | where | + | where $\mu(A)$ denotes the [[Probability|probability]] that a randomly chosen linear extension $<_0$ of $\prec$ satisfies $A$. When written as $\mu(x<_0y,x<_0z)/\mu(x<_0y)>\mu(x<_0z)$, one sees that the probability of $x<_0z$ increases when it is true that also $x<_0y$. Some plausible related inequalities are false [[#References|[a3]]]. |
See also [[Correlation inequalities|Correlation inequalities]]; [[FKG inequality|FKG inequality]]; [[Holley inequality|Holley inequality]]. | See also [[Correlation inequalities|Correlation inequalities]]; [[FKG inequality|FKG inequality]]; [[Holley inequality|Holley inequality]]. | ||
Revision as of 08:23, 1 August 2014
$xyz$ inequality
An inequality for linear extensions of a finite partially ordered set $(X,\prec)$. Elements $x,y\in X$ are incomparable if $x\neq y$ and neither $x\prec y$ nor $y\prec x$. Denote by $<_0$ a generic linear order extension of $\prec$ on $X$, let $N$ be the number of linear extensions $<_0$, and let $N(a_1<_0b_1,\ldots,a_n<_0b_n)$ be the number of linear extensions in which $a_i<_0b_i$ for $i=1,\ldots,n$.
The Fishburn–Shepp inequality says that if $x$, $y$ and $z$ are mutually incomparable members of $(X,\prec)$, then
$$N(x<_0 y)N(x<_0 z)<N(x<_0 y,x<_0 z)N.$$
This was first proved for $\leq$ in [a3], then for $<$ in [a2]. The Ahlswede–Daykin inequality [a1] plays a key role in the proof.
The inequality is also written as
$$\mu(x<_0y)\mu(x<_0z)<\mu(x<_0y,x<_0z),$$
where $\mu(A)$ denotes the probability that a randomly chosen linear extension $<_0$ of $\prec$ satisfies $A$. When written as $\mu(x<_0y,x<_0z)/\mu(x<_0y)>\mu(x<_0z)$, one sees that the probability of $x<_0z$ increases when it is true that also $x<_0y$. Some plausible related inequalities are false [a3].
See also Correlation inequalities; FKG inequality; Holley inequality.
References
| [a1] | R. Ahlswede, D.E. Daykin, "An inequality for the weights of two families, their unions and intersections" Z. Wahrscheinlichkeitsth. verw. Gebiete , 43 (1978) pp. 183–185 |
| [a2] | P.C. Fishburn, "A correlational inequality for linear extensions of a poset" Order , 1 (1984) pp. 127–137 |
| [a3] | L.A. Shepp, "The XYZ conjecture and the FKG inequality" Ann. of Probab. , 10 (1982) pp. 824–827 |
How to Cite This Entry:
Fishburn-Shepp inequality. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Fishburn-Shepp_inequality&oldid=22427
Fishburn-Shepp inequality. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Fishburn-Shepp_inequality&oldid=22427
This article was adapted from an original article by P.C. FishburnL.A. Shepp (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article