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Two remarks on order statistics
71
Journal of Statistical Planning and Inference 11 (1985) 71-74 North-Holland
TWO REMARKS Ludger
ON ORDER
STATISTICS
RLJSCHENDORF
Institut fiir Mathematische Stochastik, Federal Republic of Germany
University of Freiburg, 07800 Freiburg im Breisgau,
Received 14 March 1983; revised manuscript received 16 February 1984 Recommended by S. Panchapakesan
Abstract: Let X,t,, . . . ,X,,, be the order statistics of n iid distributed random variables. We prove that (X(i)) have a certain Markov property for general distributions and secondly that the order statistics have monotone conditional regression dependence. Both properties are well known in the case of continuous distributions. AMS Subject Classification: 62630. Key words: Markov property; Monotone regression; Dependence; MTP2.
Let X=(X,,..., X,) be a random vector with iid components Xi and let Xc ) = Xcn,) denote the ordered vector, X(i,zz ... IX(,), so X, ) takes its values in (X(1,, ... , B={~ER”,~,Ix~I~-~Ix,}. For XEB with xi = . . . =X~IO. The following proposition is a somewhat more explicit version of Theorem 3.1 (b) of Arnold et al. (1984). It implies that the ordered values nearly are a Markov chain. Furthermore, the proof allows one to derive several explicit formulas for the distribution of Xc) (cf. Remark 1). For XEB,
kin-1,
let fk=fk(x)=
C,“=, 11,)(q),
and let Tk=?k(Xo).
Then:
Proposition 1. (Xckj,Tk)15k5n is a Markov chain. Proof. The distribution dPX( ’ --&x)= (Cf. COBOVer (1973),
of X,) is given by
n!
Tl! *-or,! Th.2.1).
(1)
le(x) For X=(X,,
. . . . Xk), xl 5 ... Ix,,
0378-3758/85/$3.30 0 1985, Elsevier Science Publishers B.V. (North-Holland)
let
12
L. Riischendorf / Remarks on order statistics
B,={~ER”-~;
(x,y)EB}=(y=(yl,...,y,-k);XklylI...~y,-k}.
Let sI, . . . . sI be the length of the ties in xl, . . . , xk. Then for y E B,, the length of ties in (x,y) are of the form s, ,..., s~_~,s,+~,s,+, ,..., s,, where OlrsnC:=, si, With d@%,>...,&,) fk
=
dp(x’,....xk)
’
(1) implies n!
fk(x1,..-,+)=
dp(xk+I>...,~n,(y)_
(2)
B,'1 *1.0-(s,+r)!***s,!
Since .s!= fk(x, y) we obtain n!
fk(x,,.**,xk)=
S,! “‘S/_
I!
g/&k, fk).
Similarly,
I q!
fk-l(%...,xk-l)=
n!
,!
“‘S,_
gk-
1(xk- 1, fk- 1)
fors/> 1,
n!
noting that for s,> 1, fk_ I = sI - 1, while for sI = 1, ?k_ 1= s/_ 1 (the functional form of &_ r, hk_ 1 is obvious from (2)). This observation implies the Markov property of (xc,,, Tk)*
0
Remark 1. If x = (x1, . . . ) xk) has ties sI, . . . , sI and fk(x) denotes (as in (2)) the density of the first k order statistics, then we obtain from (2) the following simplified formula: fk(x)=s,!.__s
_ I
,;;_k+s), hk(%Xk)~ I
1.
(3)
.
with
For Px’(xk)
= 0, (3) reduces
to
n! (1 -F(X/J)“? s,! . ..s.!(n - k)! For Px’(xk) > 0,
h,(l,Xk) =-
1
px'(xk)
[(l
-.(xk-))n-k+l
-(l
-F(Xk))“Pk+r],
(4)
13
L. Riischendorf / Remarks on order statistics
h&,x,)=
--&
[(I -F(_q-))“-k+2-(1
-F(X/J)“-k+2
-(n-k+2)PX1(Xk)(l Some further
formulas
The second remark
are given by Gupta concerns
dependence
XEB with ties r,, . . . , ~~ the functionf(x)= Lemma 1. Zf x, y E B, then f(xvy)f(xr\y) sup (inf)).
+x/J)“-k+‘].
and Gupta properties l/r,!...r,!.
(1981) and David of order statistics.
(V (A)
rf(x)f(y)
(5) (1980).
Define for
denoting componentwise
Proof. For a vector .Z= (Z,, . . . , Z,) let I(Z) denote the length of the last tie in Z, i.e. I(Z)= C;=, ll,l(Zi). The proof goes by induction in n E N. (a) n = 2. Consider the cases (xi
Letx=(x,,...,x,,x,+,)=(x’,~,+~),
&t
fw-(Y) =fWfW> f(xAY)f(x"Y)
Y=(Y~,...,Y,,Y,+~)=(Y’,Y,+~)
=f(x'Ay
(6)
ftxAy;f(xvy,.
‘>
')f(x"'r
Let x,y,, we obtain /(y) = 1, I(xVy) = 1 and, therefore, 1 /(xAy) /(xVy)
1 = /(x’Ay’)
1 +
11
Io+l
so this case follows from the assumption. IfY,+, = yn , then I(y) = /(y’) + 1, I(xvy) 1 i(xAy)@Vy)
1
=I(x)
= Qx’vy’)
+
1 and
1 = (,(x’Ay’)
+ l)(/(x’Vy’)
+ 1)
1
1 =p z (f(x) + 1)(&y’) + 1) f(x)I(y)’ Again (6) and the induction discussed similarly. 0
assumption
Lemma 1 implies that n!f(x)l,(x) Karlin and Rinott (1980), Def. 3.1).
settle this case. The other
is an MTP,
function
cases can be
(for the definition
cf.
74
L. Riischendorf / Remarks on order statistics
Proposition
2.
f,, = dPX’)/dPX
is MTP,.
Cl
Proposition 2 implies, that the distribution of XC1,, . . . , Xck, is stochastically increasing in (XCk+ ,), . . . , Xcn,) (cf. Th.4.1 of Karlin Rinott (1980)). Therefore, especially, X(i) is positively regression dependent on XU, for general underlying distributions. For absolutely continuous distributions Proposition 2 is due to Karlin and Rinott (1980), Prop. 3.11, while the likelihood ratio dependence of X~i,,X~, in the continuous case was observed by Lehmann (1966).
References Arnold,
B.C., A. Becker,
U. Gather
and H. Zahedi
(1984). On the Markov
property
of order statistics.
J. Statist. Plann. Inference 9, 147-154. Conover,
W.J.
(1973). Rank tests for one sample,
of a continuous
distribution
function.
(1980). Order Statistics. Wiley,
David,
H.A.
Gupta,
P.L. and R.C. Gupta
two samples
and k samples
without
the assumption
in discrete
order statistics.
Ann. Statist. 1, 1105-l 125.
(1981). Probability
New York. of ties and Markov
property
J. Statist. Plann. Inference 5, 213-279. Karlin,
S. and Y. Rinott
(1980). Classes
of orderings
of measures
and related
correlation
J. Multivariate Anal. 10, 467-498. Lehmann,
E.L.
(1966). Some concepts
of dependence.
Ann. Math. Statist. 37, 1137-1153.
inequalities.
Journal of Statistical Planning and Inference 11 (1985) 71-74 North-Holland
TWO REMARKS Ludger
ON ORDER
STATISTICS
RLJSCHENDORF
Institut fiir Mathematische Stochastik, Federal Republic of Germany
University of Freiburg, 07800 Freiburg im Breisgau,
Received 14 March 1983; revised manuscript received 16 February 1984 Recommended by S. Panchapakesan
Abstract: Let X,t,, . . . ,X,,, be the order statistics of n iid distributed random variables. We prove that (X(i)) have a certain Markov property for general distributions and secondly that the order statistics have monotone conditional regression dependence. Both properties are well known in the case of continuous distributions. AMS Subject Classification: 62630. Key words: Markov property; Monotone regression; Dependence; MTP2.
Let X=(X,,..., X,) be a random vector with iid components Xi and let Xc ) = Xcn,) denote the ordered vector, X(i,zz ... IX(,), so X, ) takes its values in (X(1,, ... , B={~ER”,~,Ix~I~-~Ix,}. For XEB with xi = . . . =X~I
kin-1,
let fk=fk(x)=
C,“=, 11,)(q),
and let Tk=?k(Xo).
Then:
Proposition 1. (Xckj,Tk)15k5n is a Markov chain. Proof. The distribution dPX( ’ --&x)= (Cf. COBOVer (1973),
of X,) is given by
n!
Tl! *-or,! Th.2.1).
(1)
le(x) For X=(X,,
. . . . Xk), xl 5 ... Ix,,
0378-3758/85/$3.30 0 1985, Elsevier Science Publishers B.V. (North-Holland)
let
12
L. Riischendorf / Remarks on order statistics
B,={~ER”-~;
(x,y)EB}=(y=(yl,...,y,-k);XklylI...~y,-k}.
Let sI, . . . . sI be the length of the ties in xl, . . . , xk. Then for y E B,, the length of ties in (x,y) are of the form s, ,..., s~_~,s,+~,s,+, ,..., s,, where OlrsnC:=, si, With d@%,>...,&,) fk
=
dp(x’,....xk)
’
(1) implies n!
fk(x1,..-,+)=
dp(xk+I>...,~n,(y)_
(2)
B,'1 *1.0-(s,+r)!***s,!
Since .s!= fk(x, y) we obtain n!
fk(x,,.**,xk)=
S,! “‘S/_
I!
g/&k, fk).
Similarly,
I q!
fk-l(%...,xk-l)=
n!
,!
“‘S,_
gk-
1(xk- 1, fk- 1)
fors/> 1,
n!
noting that for s,> 1, fk_ I = sI - 1, while for sI = 1, ?k_ 1= s/_ 1 (the functional form of &_ r, hk_ 1 is obvious from (2)). This observation implies the Markov property of (xc,,, Tk)*
0
Remark 1. If x = (x1, . . . ) xk) has ties sI, . . . , sI and fk(x) denotes (as in (2)) the density of the first k order statistics, then we obtain from (2) the following simplified formula: fk(x)=s,!.__s
_ I
,;;_k+s), hk(%Xk)~ I
1.
(3)
.
with
For Px’(xk)
= 0, (3) reduces
to
n! (1 -F(X/J)“? s,! . ..s.!(n - k)! For Px’(xk) > 0,
h,(l,Xk) =-
1
px'(xk)
[(l
-.(xk-))n-k+l
-(l
-F(Xk))“Pk+r],
(4)
13
L. Riischendorf / Remarks on order statistics
h&,x,)=
--&
[(I -F(_q-))“-k+2-(1
-F(X/J)“-k+2
-(n-k+2)PX1(Xk)(l Some further
formulas
The second remark
are given by Gupta concerns
dependence
XEB with ties r,, . . . , ~~ the functionf(x)= Lemma 1. Zf x, y E B, then f(xvy)f(xr\y) sup (inf)).
+x/J)“-k+‘].
and Gupta properties l/r,!...r,!.
(1981) and David of order statistics.
(V (A)
rf(x)f(y)
(5) (1980).
Define for
denoting componentwise
Proof. For a vector .Z= (Z,, . . . , Z,) let I(Z) denote the length of the last tie in Z, i.e. I(Z)= C;=, ll,l(Zi). The proof goes by induction in n E N. (a) n = 2. Consider the cases (xi
Letx=(x,,...,x,,x,+,)=(x’,~,+~),
&t
fw-(Y) =fWfW> f(xAY)f(x"Y)
Y=(Y~,...,Y,,Y,+~)=(Y’,Y,+~)
=f(x'Ay
(6)
ftxAy;f(xvy,.
‘>
')f(x"'r
Let x,
1 = /(x’Ay’)
1 +
11
Io+l
so this case follows from the assumption. IfY,+, = yn , then I(y) = /(y’) + 1, I(xvy) 1 i(xAy)@Vy)
1
=I(x)
= Qx’vy’)
+
1 and
1 = (,(x’Ay’)
+ l)(/(x’Vy’)
+ 1)
1
1 =p z (f(x) + 1)(&y’) + 1) f(x)I(y)’ Again (6) and the induction discussed similarly. 0
assumption
Lemma 1 implies that n!f(x)l,(x) Karlin and Rinott (1980), Def. 3.1).
settle this case. The other
is an MTP,
function
cases can be
(for the definition
cf.
74
L. Riischendorf / Remarks on order statistics
Proposition
2.
f,, = dPX’)/dPX
is MTP,.
Cl
Proposition 2 implies, that the distribution of XC1,, . . . , Xck, is stochastically increasing in (XCk+ ,), . . . , Xcn,) (cf. Th.4.1 of Karlin Rinott (1980)). Therefore, especially, X(i) is positively regression dependent on XU, for general underlying distributions. For absolutely continuous distributions Proposition 2 is due to Karlin and Rinott (1980), Prop. 3.11, while the likelihood ratio dependence of X~i,,X~, in the continuous case was observed by Lehmann (1966).
References Arnold,
B.C., A. Becker,
U. Gather
and H. Zahedi
(1984). On the Markov
property
of order statistics.
J. Statist. Plann. Inference 9, 147-154. Conover,
W.J.
(1973). Rank tests for one sample,
of a continuous
distribution
function.
(1980). Order Statistics. Wiley,
David,
H.A.
Gupta,
P.L. and R.C. Gupta
two samples
and k samples
without
the assumption
in discrete
order statistics.
Ann. Statist. 1, 1105-l 125.
(1981). Probability
New York. of ties and Markov
property
J. Statist. Plann. Inference 5, 213-279. Karlin,
S. and Y. Rinott
(1980). Classes
of orderings
of measures
and related
correlation
J. Multivariate Anal. 10, 467-498. Lehmann,
E.L.
(1966). Some concepts
of dependence.
Ann. Math. Statist. 37, 1137-1153.
inequalities.