Stability Problems for Stochastic Models: Proceedings of the 9th International Seminar held in Varna, Bulgaria, May 13-19, 1985 (Lecture Notes in Mathematics, 1233) 3540172041, 9783540172048
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Lecture Notes in Mathematics Edited by A. Dold and B. Eckmann
1233
Stability Problems for Stochastic Models Proceedings of the 9th International Seminar held in Varna, Bulgaria, May 13-19, 1985
Edited by V.V. Kalashnikov, B. Penkovand V. M. Zolotarev
Springer-Verlag Berlin Heidelberg New York London Paris Tokyo
Editors Vladimir V. Kalashnikov Institute for System Studies Prospekt 60 let Oktjabrja 9 117312 Moscow, USSR Boyan Penkov Bulgarian Academy of Sciences Centre for Mathematics and Mechanics P.O. Box 373 1090 Sofia, Bulgaria Vladimir M. Zolotarev Steklov Mathematical Institute. Academy of Sciences of the USSR Vavilov st. 42, 117333 Moscow, USSR
Mathematics Subject Classification (1980): 60B 10, 60B99, 60E 10, 60E99, 60F05, 60K25, 60K99, 62E 10, 62F 10, 62F35, 62H 12, 62P99 ISBN 3-540-17204-1 Springer-Verlag Berlin Heidelberg New York ISBN 0-387-17204-1 Springer-Verlag New York Berlin Heidelberg
This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically those of translation, reprinting, re-use of illustrations, broadcasting, reproduction by photocopying machine or similar means, and storage in data banks. Under § 54 of the German Copyright Law where copies are made for other than private use, a fee is payable to "Verwertungsgesellschaft Wort", Munich.
© Springer-Verlag Berlin Heidelberg 1987 Printed in Germany Printing and binding: Druckhaus Beltz, Hemsbach/Bergstr. 2146/3140-543210
CON TEN T S
Page
Zolotarev, V.M.
Preface
1. Hohlov, Yu. S. The estimation of the rate of convergence in the integral limit theorem in the Euclidean motion group 2. Kagan, A.M., Zinger, A.A., Contribution to the analytic theory of forms of independent random variables
11
3. Klebanov, L.B., Manija, G.M., Melamed, J.A. stable laws and estImatIon of their parameters • • . . . . . . . . . • . . .. 23 4. Koicheva, M. The method of metric distances in the problem of estimation of deviation from the exponential distribution .......•.......................•••.•.............. 32 5. Korolev, V.Yu. The accuracy of the normal approximation to the distribution of the sum of a random number of independent random variables .............•....•..•................ 36 Kruglov, V.M., Titov, A.N. Mixtures of probability distributions .....•.......................•••................. 41 7. Maejima, M. Some limit theorems for summability methods of LLd. random variables .........•.....••.•.•............... 57 8. Nagaev, A.V., Shcolnick, S.M. Properties of mode of spectral positive stable distributions ..••.................... 69 9. Nevzorov, V.B. Two characterizations using records
79
10. Nikulin, V.N. On orthogonal-series estimators for probability distributions .............••.•••.•..•............. 86 11. Obretov, A., Rachev, S. Estimates of the deviation between the exponential and new classes of bivariate distributions ....................••..•••••.•.•.•••........•... 93 12. Omey, E., Willekens, E. On the difference between distributions of sums and maxima ....•••.•••.•.•......•......•• 103 13. Popov, V.A. On the inequalities of Berry-Esseen and V.M. Zolotarev ..•.•..•••...............•......•.•..........•.. 114 14. Radu, V. Some fixed point theorems in probabilistic metric spaces ...•.•..............•............................ 125 15. Riedel, M. The asymptotic BIAS in a deviation of a location model · ......................•.•....•..•............•. 134
IV
16. Rossberg, H.J. Cramer's decomposition theorem within the continauation theory of distribution functions ..•••.•..... 145 17. Rychlik, T., Zielifiski, R. An asymptotically most BIAS-robust invariant estimator of location ..........•.•...... 156 18. Sasvari, Z., Wolf, W. Characterizing the distributions oft era nd 0 m ve ctor s X" I X2. X-3 by the dis t rib ut i 0 n 0 f the s t e t i s t i c (>;,- X , X., ) "
172
19. Siganov, I. On stability estimates of Cramer's theorem
178
20. Szeidl, L. On the estimation of momoents of regenerative cycles in a general closed central-server queueing network
182
21. Vostrikova, L. On
190
J
and their applications
22. Vsekhsvyatskii, S.Yu. On some properties of ideal metrics of order'fl ...........•..................................•.... 204 23. Yanushkevichius, R. On and sample variance ...
independence of sample mean
c ••••••••••••••••••••••••••••••••••••••••
207
PRE
f
ACE
The INTERNATIONAL SEMINAR ON MATHEMATICAL MODELLING AND STABILITY Of STOCHASTIC MODELS was held in Varna during the week of 13 to 19 May 1985. Such seminars on continuity and stability of stochastic models have been periodically organized in the USSR since 1974. The Ninth Seminar in Varna was the first one outside the Soviet Union and the second international one among these meetings. The first international Seminar ( sixth in the general order ) took place in Moscow in 1982. The Seminars are organized by the SteklovInstitute of the Soviet Academy of Sciences in collaboration with different other mathematical centres. The Varna Seminar was held on the initiative of the SteklovInstitute together with the Centre of Mathematics and Mechanics in Bulgaria and the Allunion Institute for System Analysis in Moscow. Looking through the contents of the proceedings of all the nine seminars one can realize that the Program Committee has never put strict limits on the spectrum of subjects treated. The explanation is that the organizers wanted not only a broad exchange of research information among the participants, but also to propagate the fundamental ideas and methods of a relatively new research area. In particular, the idea that every approximation problem can be considered as a stability problem in the framework of a relevant characterization model was a central one. Closely connected to this approach is the use of metrics in the space of random variables and their distributions, which leads naturally to a more close consideration of different questions concerning probability metrics *. As a result the participants in
the seminars formed always two groups.
The first group
* See also the foreword to the proceedings of the previous seminar, Lecture Notes, in Mathematics, vol. 982.
VI
consisted of active adherents of the above ideas, tending to materialize them in solving concrete problems. The second group included participants who Liked to learn more on these new approaches and methods. The traditional subject area of the seminars was extended in Varna by including problems on mathematical modelling in general. This was a quite natural decision stimulating the interests of experts of the two areas. The Organizing Committee ( Chairman Blagovest Sendov, Vicechairman V.M. Zolotarev ) received more than eighty papers from a dozen of countries. There were more then 120 participants. A substantial organizational effort was necessary to prepare the seminar and to publish these proceedings.
are due to our Bul-
garian colleagues and hosts for the nice atmosphere that they meeting. Particular
throughout the
are due to B. Sendov, B.Dimitrov, G.Tchobanov and A.
Obretenov. The editorial
was done
by
l.Boneva
V.M. Zolotarev
and
E.Pantcheva.
THE ESTIMATION IF THE RATE IF CONVERGEM:E IN THE INTEGRAl LIMIT THEOREM IN THE EUCLIDEAN MOTION GROUP Yu. S. Hohlov The aim of the present paper is to obtain estimate of the rate of convergence in the integral limit theorem in Euclidean motion group in the case of the stable limit distribution.
The estimate is obtained for uniform metric. To obtain this
estimate we use some ideal probability metrics in the space of random variables in Euclidean motion group. 1. The integral limit theorem in group
In this paper we consider the group transformation /Rei on
Y
If(
d
igin in
IR .
g(n):::!ft .. ffncan
1M (d)
U
SO
!It '
(d)
!J,
Yr + U,
+ ... +
,92, .. ,
u, ... Un_
,
(Y, U) , where
, . . . , gn '
then their product
,where lJ(n)==tJ, ...
lfn and
1
be a sequence of random motions. V.N. Tutubalin for
([1]) and L.G. Gorostiza ([2])
THEOREM 1. Let
g
is a rotation about the or-
be represented in the form g(n)::::( Y(n),U(n»)
Let now
3
which is the group of one-to-one
can be written in the form
If we have several motions
Yrn)::::
and
t
is the translation parameter and
d
nY(a') ,
!Rd preserving the orientation of the space and the inner
g
product. Any element
1A1(d).
Y2 ' . . .
for any
d
d= 2
proved the following result.
be a sequence of independent identically dis-
tributed random variables with values in IA1 (d) and satisfying the following conditions: 1) the distribution of
SO(d>
lIIl!asure on 2)
E
I Y.1 1
2 ",
Um)::::
u, ..'Un
converges weakly to normalized Hear
J
00
Then the distribution of
n
-1/2
Y( rn
converges weakly to spherically sym-
2
d fl 2 IR and n- Yen)
. normal d istribution on met r1C
an d
U ( n)
are asymptotically
independent.
In the paper [3J B. Roynette gave a new simple proof of this result. P. Baldi described the collection of all stable distributions on the group
J!tUd)
([4J).
It turns out that every such distribution is a composition of a spherically symd metric stable distribution on A? and an uniform distribution on . Now we can consider theorem 1 as the conditions under which the distribution of tne random belongs to the domain of normal attraction of normal distribution
motion
when we use the scale normalization of the translation parameter. An analogous res ult was proved by the author of this paper in the case of the stable
limit
dis
tribution ([5J). Recently A.K. Grincevicius ([10J) slightly generalized the result of
the
paper
[5J
and
1.1 '
THEOREM 2. Let
got
rt , ::72
the
and
sufficient
d IR . The distribution of random motion g,=(Y"lI,J
belongs to the domain of normal attraction of the stable distribution on the paraeet.er
a, 0
«
2)
#Wrd) with
ex < 2, CY =F 1 under the scale normalization if and only if
1) the distribution of
so (d)
conditions.
be a sequence of independent identically dis
. "
tributed randOlll motions of the space
necessary
Urn j converges weakly to normalized Haar measure on
,
P{IY,J>x}=(C+O(f))lx
cX
, as s:.... 00 for some C:> O.
Now it is natural to ask the question about the estimation of the rate of convergence to the limit distribution. In the solution of a number of problems of the estimation of the rate of convergence in the limit theorems and in the problems of stability of characterization of distributions the socalled ideal metrics were very useful ([6], [7]). We construct some metrics of this type on the group M4(dj in this paper and discuss its properties. After that we get the estimation of the rate of
to the stable distribution on group 2. Ideal metrics on the group
AWrd; for
uniform metric.
AWrd).
At first we remind of the definition of the ideal probability metric ([8]). Let E be a complete, separable metr i c space with metr ic
d
and a () algebra
J3 of
3
Borel sets generated by this metr i c , Let us suppose that we have an associative semigroup operation ,,0" on space J(
(E)
E. This operation induces the operation in set
of random variables with values in E. Let us consider also a collection
.iJ ={d} 'J e r}
of one-to-one and continuous transformations of space
E
and sup-
pose that the folluwing conditions are fulfilled: 1) set and
IIt 0 02! 2) 3)
r
is a normalized group, the norm of an element
I!, I .
I
J2 1
f
is denoted by
I el' ,
,
J2 ="v1, .lJdZ
£)1, ciJe
is the identical transformation of the space
4) for any
1(X
j
IE
r
X, Y e E
and
'1
oy)
E,
rX J 0
1 (Y )
DEFINITION 1. The simple probability metr i c in X ( E)
is called the ideal
metric of order S , S:= 0, if it has the following properties: 1) for any
X , Y,
which are independent of
Z
I'(XoZ, YOZ) /,(ZO%,ZO Y) 2) for
EIlY
I
to
r
and
£:
fl(%, Y)
X, y
I' (-7(%) '1 (Y») Itl Sometimes we shall say shortly that In our case we have
s
jI
·fI( x, Y) is the ideal metr ic on
E=Mrd),D={4,C>O}is
E .
the set of the scale normal-
izations of the translation parameter. The main result of this section is the following
THEOREM 3. let
if.,
be an ideal metric of order S on IR
following properties: (1)
j't(Y+UY"
(2)
;Ut( Y, + u, Y, >2 + £:
'2) Y) :: It, (1, ( Y) ,
SUPctf;+!lrx,
xclR
(Y»)
Xel!?
1
"
d
, which have the
4
g
where
(Y, U) ,
!J, = ( r; , If,) , .%'= (r; ,
are independent random motions. Then the metric
sup
==
, OM(dJ
X
where
are the random motions with distributions Ff and
and
probability metric of order
S on
IIrf
is the ideal
(d) .
PROOf.
be random motions and
independent of
!fa'
e
X'
.7,
and
are
e", !I e IA1 (d)
jI(!ls0 gt' !l3°!k =: BUp jI,(!I0§j0!l,(X') , go gJ o f2(XJ) x,g
Itt (!I
==
0
(
r; + u,:r) , go !Is ( >.? + 0 x»)
6sup;UtCY,+u,x,
x
!E: sup /'t (go!!, (X) .x:,fl
,
go g/i.l')
Here we use the property (1) of metric
=1' ({1"
JU, .
!/2)
Analogously, using the property (2), we
get
fI(!J,°f/a,
x.g
!E:SUPh(g°fl,(,x), gO!!;(,x))=j/(G;,g2)' x,g Further
fI (.11: (!it), 4
=x,y sup fit (j°.iJc ( flr )(X), go 4
= $UPjlI,(Y+U(cv,)+UU,x, Y+UCCiE)+ UU2 X ::e,g
= SliP
Y+UY,+ULJ, (; X»)J C(f Y+
oc,gF'f
C
Ie/
f/,(hog;(z),
s
= leI
(X)) )
U0?(; ,zo»))
$
We will use some metrics of this type in this paper. Let the variation distance, peetively. The metrics
Var,,p
and
?:"s
be
the uniform metric and the so-called Ss-metric on p¥dr es -
Var
ideal metric of order S on
and'p are ideal metrics of order S == 0 and It is easy to
Ss is
the
that these metrics have prop-
erties 1 and 2 of theorem 3. Consequently we can construct the ideal metrics on the
5
group /l,1(dJ using these metrics, which we will denote by the same symbols Var,
.
We remark here that for these metrics we can omit the supremum over
p ,
gEPWCg)in
their definition. 3. Some 1 _
In the proof of the main result of this paper we need some lemmas, which will be proved in this section. At first we introduce some notations. Let Q/r be the
a.
stable distribution on I/H (d) {
-i1
with structure parameter
is the projection of
LEII4A 1. Let
If, 1
tt
i\
t/
!R .
be the distributions on 1M (d). Then - il
*;::,
pRO(F. Let!l, =:(
and
on space
- /I
*
C(d,d).:1
and
flex
be random motions with distributions
-/I
QC{ •
.P ( P, , ) =.P (g,,, z g ) = SUp x P (g, UX') = ;l/P'p ( Y, + 6
cc and scale parameter iI ,
o, X, v., + U2 X
*' p',
-/I
Q(X
* Pz) +
(-
(X
A
/72
fit)· Var
0
(&:
g,2 (X) 6 A} d (ijOC\f if-
varCO: *
rj"
c- rAJ
+j>
tt)+ JJC
r/JZ)
1
0
+ Slip Slip II p{ gtI s:
J/.. =SUP d X e II? 0""-'"
/ m
t;+
1//;0 ... oy'd(fJ(xxdy)-fJ (x)Cdy)))
. "'d ,ldI? d +id=m
'i:x"
a
1
The main result of the present paper is the following r= [cxJ+! . Then
THEOREM 4. let #.=0,1=0 r-f Fl
.P ( P..
n
L
C(c;()
"
• d C( .a yrna x
[
] n 1- r/o: ,
(s, (p, Qo:) ,
PROOF. In proof of this theorem we follow in principle the proof of the analogous result in [7]. Let n
is fixed,
fj'
!j
and
uun
ions (!iWYU),UU»)and (j-l/CXnJ)j
are distributions of random mot-
Using lemma 1 we get
Further
Finally we get
jJ (
C '.p(
f}cx)
f;-
cn-j-rr/n
m
+C.;z::..fJ(P . ,Q J=f n-J-r ex
+C +0
) •
F
IX
(ij it;{. fJ ex
+c(d,c;(),1
-)I'
17-m-1
flex
I,
if-
I
IX"
(/trlfl)ln
o:
Yare ac(
- it
"" p, , Orr *
_ iI .i/rr - iI )·Var(Q *P*I} ,Q If IX 1 cc ex
.:fl!: O( iJ /! )(. a(f7-J-O!n;(- p..
J =0 J'
A
(17- n/n f'
(/117 oC'
ij A :/I' (X
+14 +4
or
)
aex "" aa: ) r/n-J-l )In*' din I}JII7) cx fin
Jln
If
(X
0(
!l il % [}(fl-m-l)ln;;
'cx
fin [}(X
a(trlftJlfl) ex
8
=[ ;
m
Let
J.
Using lemma 2 and the property of regularity of our met r Ics
we get
.,.
C
.I..
J
0 var (r/rl-j-I)ln p .i/n 1/ *" Q}=O, t , r e s J
J
In a neighbourhood I t I
.. K-I (K=1,2, ... ), i
the
Ypstrictly
Gaussian
Yp
THEOREM2. let the r vv,
Y
relation (2).Then the r v , i
(3)
is
r. v ,
has
the
CX,j3,A ,
Ypstrictly stable iffits c.f. is of the form
min (!
L f)
'ex:
tion (2). Then the r ,v ,
vp
})
,
vary in the range
(4) THEOREM 3. Let the r ,v ,
distribution.
have the generating function (1), satisfying
.I(i)=ho c-,1 I t l0 ' J':::12 J ,
and such that there are constants
infFe,y: I'min ( 'M)
with more than
points of growth for which
C, ,
C2 .
(1£)
There have been proved the following assertions in
which we state
here in the following form.
PROPOSITION. Let the d.f . F(x; U) the posit i ve numbers
t,
J ' .. ,
tk
have more than /( points of growth and
be such that
... ,k)
(1) the functions
are continuous w. r . t.
oe
7.i
and
'f
ZI!. ) ) j
=:
I, ... ) k,
have continuous w. r , t.
partial derivatives up to the second order inclusively; (Li )
Then
det 1l
iJz
(22 ;
X ) =f:. 0 .
7.i and the random vector
Vii (7£ - U)
is asymptotically normal
-1
N(O,lI (1fl;Xn If, moreover, uniformly w.r.t
rc»; 7.1) E:.1
and the estimator
u"
is
Vii -consistent
jr ,then the convergence of the d.f. of the random vector
27 the limiting normal d.f. is uniform w.r.t. the set
JC.
Let us apply the obtained results to study the properties of estimators of a parameter vector ZP.=(a,p,71J
of the
Yp-strictly stable law with c .f", (3)
n
Assume that there is a random sample of size F(X;ZR)
-I
of the law (3). Put
(IfnctJ)
Relf',,(Z;')*O
that
from a populat ion with d. L
>0
and let
be such
1,2,3,4
Using the random sample we can construct the MSM-estimator with components
based on the auxiliary estimator
o:"*=: In
(9)
if
Ilfn (l,) I I lJ1n ( l z> I 0::
if
The estimator
/ In 7:2
*
,
,in general ,
values from a larger set than (4).
ii:= (ct,ji,;J)
Therefore, let us introduce a new estimator
(10)
{"' A
a
= :
I
0< eX
l
k
fl
'k
g (iy») +
m
k==f
k
as the product L(2:>= QCZ)·
L(Z)
-6y
+
[J
Jk
)
e
i(Z)
. where
Note that m-f
I
(13)
holds for
lex t {]
zr -
y:?: 0 . 00
to infinity as
•
m-f
m-1
(iy) + !fm m
It was assumed that
g
m-1
.
(ty)
lex t F::: -
00 •
Thus by (8) we have that
According to lemma 4 the functions .f ( /r: and co
g ( iy)
tend
• The relations (10) and (11) imply the boundness of the
46 ratio griy) / .fUy)
. Tak i nq (12) and (13) into consideration we get
sup ariy) = sup (/L r iyJ/ / T(iy))
y,=O
I ,e, function
linear
a is
!. Equation (17) takes the form
11 (z)=/exp{iazu-
(20)
UJ 2
z
2
}dA(u)+I(Z).
0-0
In (20) the number Ll
is positive. Really, if Ll ==
0
then the left-hand and the
right-hand sides of (20) have different orders of growth as Iy)-+oo. If, for exam-
ple,a>O then put Z
= iy
and divide both parts of (20) by II (iy) . Let y
tend to
infinity. Taking into account (18) we get the contradiction: /=0. 2 2 Fix a number C such that C> ();/ J ,A (C) « ! 2
C/ y2}
. The inequality +l(iy)
obtained as a corollary of (20) is contradictory for
y
large enough because the
order of growth of its left-hand side is less than that of the right-hand side if
y-;>
00 •
2 2 for U>u /Ll
Consequently, A(u) ==!
have
!
lim _1_._(
y ...... -oo /loy) .
lim
y""-
00
1
. Besides that by (18) and (20) we
u71+/J
I
hV(iY)dAcu)+l(iYJ)
0-0 2
2
((2
2
- . - exp{lexly(];/J + 2 Y }==O •
/lUy)
This contradiction is a result of the assumpt ion that function points of growth.
N(v)
has not any
51
Now consider the second case, i.e. the case when the function
lV(v)
has points
of growth. We have already marked the fact that the d. f. A cannot be degenerated at zero. So there exist positive numbers C and c"C 1
{}
is con-
is constant in the interval (0,1)
V=!
at the point
. However the supposition
h(Z)
tradiction as it was shown above. The ch. f.
,otherwise /\I(V) /\I(V)
== 0
• It
== 0
,
leads to a con-
from (17) can be represented
as 2
htz:
(23)
.
Fix a constant 0 such that A(O):!Iq .
According to (17) and (18) we get
00
I;:: Zim -'-.-!hu(iy)dAO/) y...-co 11 (ry) C
/II q
we get respectively
00
and
.
L]2::lIt:{
and the representation of
n/l1fJ
0''l8 .".
the proof of theorem 3 in the case
A=E;l.lfj
LI is a positive function
As
1 for all Y large enough. For such y by (17) we have
is greater than
+ /Z(iyJ! Letting
.
,
cr.> 0
and
13
,where ;j >
. Fix e ,O< 0
can be taken arbitrarily small, we get Now prove theorem 3 in the case
v.> 0
j3 •
integrable over the normal d. f. for any integrable over the d. f. the functions
N(v)
A
£)./({'
and A = 0 • The function It follows from (9) that
for some positive U and all
flU
. As
j3 .
SOft 0
2 2 for U> () / Ll and A > 0 we obtain
and a= 0 :
a )1/2exp] - a!J-n;2 } o·(n)= (- J 2rrn 1 2n
, Dej
} be a random-walk method. J
(0
-1/2
s!lpCj(n)/Vconst.xn
.
J
r>O
(E) Let
and assume
P
Elf,! for some p>1Ir-!
when r0 ,
0 ,
(a)
E
"
(I +
log
+
-2
2
114
J -c
OQ
-1/2
lim sup
(c)
lim Slip (411n) (d ZDgn) n-oo
C41ln) cd logn) 1/4
={ p(1- p)} This was
-fl4
-1/2
n
1
also extended to
j
J-O
a..s , for some (any)
=1
x.) J
J.
J:;O
2
J
-n
0
(b)
p
E
av s ,
(f-p)
n- J
(0,1) .
random-walk method by Bingham-Maej ima [2].
the
THEOREM 6. ([2]). The following are equivalent. (a)
= d 2> 0
EXa = 0 ,
£exu"U+loq+IXolf2J (b)
lim sup (41ln) n_ oo
1/4
, 1 .
62
where Zo:- is a stable random variable with index ex and L (.) is a slowly varying function.
THEOREM 7. ([13]). Assume (A) and let 1
--
(4 2)
•
00
...2:' C·
So,)j:=o
(A) X
J
J
I?
with some normalization a (/I) > 0 .Define
i!i I 8(i!) I 00
(4.3) when
0 < 0
.1 O:[.(}t)
-tjlA
XJJf>O
J=O
1;00e -tudZ(VJ,t>O }
}
a
0
in C [e,=) for any s >0 . To discuss the functional limit theorem for the random-walv method, we start with the following.
t
THEOREM 13 ([ 9] ). Let
and
be two sequences of random variables ,2
2
generating two random-walk methods p(f', () ) and p( u;U ), and set ,
n
I
J
S=.;£'f. . n J=1 J (I ) If
!' =/-" ,
(Li )
n
If
,
then
1/2-1/(2«)
(6.1 )
17
,sn =J=1 ,;;;:£
Lt n
1/2
I' =PI"
)
1/2-1/(2")
00
01=0
P(Sn=j)-Xj
J
n
Lr n
1/2
)
0:>
J=O
P(Sn'=j)AJ)
,then the limits in (6.1) are independent.
COROLLARY 13.1. n
1/2-1/(2a:)
and
have independent limits. Hence the Borel and Euler sums generated by the same sequence have independent limits. The following statement is essentially the same as Theorem 13 (ii), and it
66 gives us some answer to the question of functional limit type for the Borel and Euler sums. THEOREM 14 ([9]). If t
n
'* S,
then
1/2-1/(2a)
[nt]
J=:O
=J)X J
and
n
1I2-1/(2c()
LCn
'/
2)
QO
J::o
J)X J
ens]
have independent limits. COROLLARY 14.1.
Define
Ii 1/2-f/(2 0 .
J
t
=1= s
COROLLARY 14.2. Define n '12 - / ( 2c< )
Lln(tJ=
' Lcn'/2)
tnt)
0
tnt:
J
( j )P (1-P)
CntJ-J
XJ , ,t>O.
Then Ll (t J and L1 ( S) have independent 1 imi ts i f t =t= s n n
.
7. THE RATE Of CONVERGENCf IN THE STABLE LIMIT THEOREM. In this last section, we shall give the rate of convergence in Corollary 7.1. for a restricted class of random variables
{X } J
in terms of an ideal metric,which was recently defined
by Maejima-Rachev [11]. We start with the definition of this new ideal metric. Denote
Ifgll p = 1/ glloo Let
r >0
00
p
Ig(XJ! dx]
tip
)
P
I ,
P( y
.r) aa:
81' ( X, y) & { k, ( X, y) } Y can et. xk,,(X, Y)
where
00
k (%, y) = r r /
, X I1'-1 I P (%
r
X) -
1 ,
I
-00
We restric random variables as fallows. Assumption (B). Suppose 0 < ex < 2 ,and that
of attraction of a stable random variable 1:
ex:
= exp {-I W lex} . THEOREM 16. Let (i) O.c: ex =-It J exp(-i
signt) ,
OltlE, jlfJ(f)j=exp(--Lldx'sin rr;e):; exp(_ 4 Jt j1/2) ex E using (17) we obtain (33)
In addition we have (34)
Combining (29),(30) and (32)-(34) we obtain the statement of Lemma.
75
Note that the integral in (28) is real-valued for any integer part icular
It 2Zn t ex p C-
k
. In
0
2:
00
f!r(X)=-;
1t 00
1
- 211
t)sin(tx+fZnt)dt
(J
2(
Jl2 2 if-Zn t)exp(
TC zt)cos(tx+tlnt)dt
o Proceed to the proof of Theorem 2.Denote by
Z and rna the modes of
ex
(X) and
g(X) respectively. Firstly we show that
z = rna +
(35)
W (£)
,
Choose .z;..cx2 X2 '
••• the
are independent? It is easy to prove the following
lemma. ... ,Xn
lEtIfA 2. Let
8 ;
...
fz" '" f n :=
i
-00
be independent r vv, with distribution functions
FIXi, for2,
F and S< being continuous d.f . and (Xi>O(i=1,2, ... ).Then the r ,v ,
k
are independent,Pff/ 0
in theorem 3 can have any positive value.
3. PROOF OF THEOREM 1. Consider the equalities
One can rewrite (1) in such a way:
x
00
j
(2)
-00
H2 ( X )
J H,(YJ!k (yJ dy d Fn(XJ
-00
00
=! where
_00
co -00
H,(YJ0«Y)H2(YJdFn ( y ) ... F,,_1(X)( ifk=:n-!
f?(:x)=F,(X) ..
,
,then
). The can-
ditions of theorem 1 allow us to substitute in (2) any absolutely continuous d.f. ChoosingF"(X)=F,,,e(XJ=(X-Z+f)/E Z (3)
(-= , 00)
H
2
for Z-e£X!:Zand lettinge-+Owe obtain for
Z ( z )/ _
Z*).
(4) _00
The next relation follows from (4):
II; t z:
C
(Z)
(5)
- - - -- --- 0«Z) - 7-C 111 lZ) -
flk ::: CI(t-c)= i
where
k
H,(Z)
(z >z*) ,
f4(YJ:{rYJdy /
il7z) =!k II,fJk(Z)
One gets now that
#,'(z)
j3,
-
. 00
for Z > Z *,
(6)
(Z)=(F,(Z)F;(Z)· .. Fk_1(Z))
which is valid for Z >Z ... From (6) F;(Z) ':
(7)
withZ")
0
,
84 R£FERENC£S
1. Renyi A. On outstanding values of a sequence of observations. - In: Selected Papers, Budapest, 1976, p.50-65. 2. Nevzorov V.B. On record times and inter-record times for sequence of nonidentically distributed random variables.- Notes of Sci. Semin. of Leningrad Branch of the /otlth. Inst. 142. (1985), 109-118. ( in Russian) 3. Tata M.N.
On outstanding values in a sequence of random variables. Zeitschr.
fur Wahrsch. verw. Geb. 12, (1969), 9-20. 4. Ahsanullah M. Record values and the exponential distribution. - Ann. Inst.Stat. Math. 30 (1978), 429-433. 5. Ahsanullah M.
Characterization of the exponential distribution by record values
B41 (1979), 116-121. 6. Ahsanullah M. On a characterization of the exponential distribution by weav homoscedasticity of record values,.
(1981) 715-717.
7. Ahsanullah M. Record values of exponentially distributed random variables.-Statist. Hefte,22 (1981) 121-127 8. Ahsannulah M.,Holland B. Record values and the geometric distribution.-Statist. Hefte,25 (1984) , 319-327. 9. Dallas A.C.Record values and the exponential distribution.-J.Appl.Probab. 18 (1981), 949-951. 10.Gupta R.C. Relationships between order statistics and record values and some characterization results.- J.Appl. Prob. 11.Kirmani S.N.U.A., Beg M.l.
l! (1984), 425-430.
On characterization of distribution by expected
records.- Sanvhya A46 (1984), 463-465. 12.Korwar R.M. On characterizing distributions for which the second record value has
a
linear
regression
on
the
first.-
B46,
(1984),
108-109.
13.Mohan N.R., Nayav 5.5. A characterization based on the equidistribution of the first two spacings of record values.- Zeitsch. fur Wahrsch. verw.Geb. 60 (1982) 219-221. 14.Nagaraja H.N.
On a characterization based on record values.- Austral. J.Statist
(1977), 70-73.
85 15.Nagaraja H.N.
Record values and extreme value distributions.-J. Appl. Prob. 19
(1982), 233-239 16.Nayav S.S.
Characterizations based on record values. J. Indian Stat.
1981, 123-127. 17.Pfeifer D. Characterizations of exponential distributions by indepedent nonstationary record increments.- J. APpl. Probab.19 (1982). 127-135 (Correction:
.!2.L 906 ). 18.Srivastava R.C. Some characterizations of the exponential distribution based on record values.- Bull. Inst.Math.Stat
l
(1978), 283
19.5rivastava R.C. Two characterizations of the geometric distribution by record values.- Sanvhya, B40, 276-278. 20.Srivastava R.C. Some characterizations of the exponential distribution based on record values. - In : Statistical distributions in scientific work, v.4, Dordrecht, 1981, p.411-416. 21.Srivastava R.C. On some characterizations of the geometric distribution.-Ibid, p.349-355. 22.Taillie C.
A note on Srivastava's characterization of the exponential distribu-
tion based on record values.- Ibid, p.417-418. 23.Westcott M. Characterizing the exponential distribution ( Letter to editor ).(1981), 568. 24.Khinchin A.Ya , The works on mathematical theory of queues. Moscow, 1963 ( in Russian ). Department of Mathematics and Mechanics Leningrad State University Leningrad
Received 20 May 1985
ON ORTHOGONAL-SERIES ESTIMATORS FOR PROBABILITY DISTRIBUTIONS
V.N. Nikulin
Let X =
{'3" } , j = I,. . • , n
be
independent identically distr ibuted random
variables with distribution function
F to be estimated. We consider the ortogo-
nalseries estimators of
F given by
a: p{jefJX)dt J
_
00
where
1
/
P ct,X)= - {j 2 n» -(j
Un''} l/l(X.-t) J
";=1
d;t
,0-6U
2 BXp (- X - Y )
LIn
-
Y
x
/ 6'n(A;
Y
or Lln(X,y)---:> 0
(X,y) E
N13U
fJ" (U, v) dudv
and be with the same exponential margin-
x y als with parameters Af ( U) , i/Z ( n)
such that
-1
-f
aUO(n) = i1f
( n J A2 ( n )
• If
has finite Laplace transform, then -1
lim Cn (/1 f if and only i f
PROOf.
(fl)X,.4
lim
-2
agO
(n)
The statement
-1
2
(n;y)
= exp (-x-y)
a ,1( n } ==! • follows
from
Lemma 2
and the proved above Theorem.
Further, we shall estimate the deviation between ad. f. bivariate
on U.
"0 00
6n (X,y) = auo / /
F" (oX, y)
/
and from (9) we conclude that (8) is true.
COROlLARY 1. Suppose -f
X
1
CD 00
. Therefore
exponential
d.
f.
with
F to fiR
and a
[see
parameters
(n].
In order to get the required estimate we shall prove some preliminary lemmas concerning the inequalities between metr ics in the space
:;: of all d.
f.
I
S
on
2
!R+ = [0, 00 ) x [0, 00) . LDI4A 3. for any d. f.
f
S
;:;
and
":?
on
IR:
such that
marginal densities
M= SUp
If
ax
f2(x,OO)I+ Sup ldd Fz(oo,X)1
x
the following relation holds
where.fJ is the uniform (Koloogorov) metric
I
SUp !j'(ZJ-f2(Z)j , Z= (.r,y) Z IE 1R 2
f2
has bounded
97 and L is the Levy metric
The proof is evident.
jf
Let
be
the
following
metric
on
the
.f
space
of
d.
f. 's
2 on $+
/,O:;,"2)=SlIp{lj.fd(F;-Fz)):I
7f} ,
2
where
IR+
de is the class of functions
which have continuous derivatives
aU)
x
=
max
U,JJ ,J('
LU;, C=
ax 8y2
F;) 8
CIf 1/5
4- ( T)
PROIF. Let
that for some
a
such that the functional
(/+j .I
. .
8x l 8y J
F,
1/5
,
(F,J2
and
F2
on
IR;
the following estilllate holds
) ,
=4,5526081
L ( F, J;) and
with real values
1 .
LEfIoIA 4. For any d. f. 's
where
a"f 2
2
IR+
= { (/,0) , (0, 1) , (1,1) , (1, 2) , ( 2, 1) , ( 2, 2)}
I 0 (/) I 6
satisfies
I
max
J(:J:,y),(X,y)
:>
e
. Hence, without loss of generality, we assume
6
Further we use the main idea of estimating
fI
in terms of L , given by G.
Yamukov (1977) [2] (see also V.M. Zolotorev (1976) [3]). Denote
.B =
J x [0,6 J , .B (c) = [0, a + eJ x [ 0, 6 + e J
and
Jex,y)=
T12
[(-(oX
2
2
2
+Y )] .
It is easy to verify that
\0(1)1 6
-:
and
J !ex,y)dxdy
!
.
98
Consider the functions: lI(X,Y)::
(J /1I{(lJ"V2) e s ;
a -o; rr:
)}j'(2
J1?2
z ,2 -E-)du,dv e Y-V
+
and
p(X,yJ
2V(X,y)-I.
vrx,y)
Obviously 0
, so that -I
1
, i f (X,y) belongs to
fjJ(X,y)={ 1 -{
0
I{(V"Vz ) £ .B(
we get
f
and from V,
Suppose X
ff )} = f
i2':
a
0
I { .}
1 ,
.Il
if(x,y) does not belong to
Really, let (X,y) E B(e) j =
P(X,y)
. Therefore II ( x,y)
+
B( c) .
e
. When
=f
then from U, "" f (X,y)
e B
follows we have
which gives If (X,y)
:= f
Further we find
8rp
ax so that
Ik8x l
2
LE
/1
1 1
o
f
0
-E.L I du1 du.2 aX
Analogously we get 7
11: e
ay
I
a3
I
Therefore
fI(lf)
(15)
h (X,y) o
;e3
3 2" 2 '2
= ;
eft.
=
,
4 a
:I(.!) = 111(X,y)d C8f ( x , y ) - 82(x,y)] . o 0
Integrating by parts we get 00
(j(f)=jJc.:r,O)
o
Next
:;, =-/ o
00=
ce, (X,O)-62 (x,O))dx-j / 0
r:
0::>
j( x,D) d
[8, (X, 0)- {]2(X,in] =
J [6',
= /(0,0) [6,( 0,0)-62 (0,0)J+ and
0
o
)-{]2 (x,O)J
da:
dxdy .
100
CO
.1 __/ [ / OO dlrX,y) dx [C,-C,J]dy 8y
2-
()
CQ[ 8I(O,y)
=;
(}
o
y
8xa
/
y
dxdy ==
00
0
elf
j j( 8,-(J2)dvdv 00 00
8xd d Yxy
,
2
8xdy the
and
R(X,y)
same manner as
=:
in
(;,(X,y)- IJ2 ( X , y ) the
0000
0 00
+/R(O,y)
o
00
0
a
00 00
'9';O,y) dy+/ jRex,YJ y
0
R(x,O)
a2 (
0
y
a
g;x,O)
a:
dX'dy
Hence 00 00
J(fJ = ; o
j.f( «r: d [ IJ, (X,yJ - [;2 (X,yJ ]
0
00
+/ o
(6, (O,y)-6'2(O,y)) 2
+
a8x8y 'f(O,O)
II
0000
8y
dy
0000
o 00
81(0,y)
we get
representation of
/ j !I(I,y) d R( x,y) =:!l( 0,0) R (0,0) + j
o
d d .x y
0
a 'f(x,y)
Using
j/
00 00
=/ !!1(X,y)dR(X,y) o 00 ""
g=
2.f ;00/00(c,,-6'Z) ox8y a
0
a2.f
00
where
2
(B,(O,y)-G2(O,y))dy+
ca co
finally
,
0
(b',(X,y)-IJ2 (x ,y )) d x dy
0
3
+ j[jj(6.,(X,VJ-6.2(X,VJ)- a fO}
11 FxGII 611FII UOIl • For m
m
m
the function m we shall often assume that m satisfies one or several of the following conditions:
m
J:: lim x-?
00
sup Iy!";; h
m e OX: Zimsup x., 00
m(x+y)
m(x)
sup ly/6.h
m(x+y)
m tx )
for
!
O
all
h >0
106 :II:
/ m(x-y)m(y)dy o =2jm(y)dy m t.x ; 0 OQ
m
G:
SlJ: lim
m x m(x) = lim mt x )
.
:x _
The
x m(XJ
m
m e OS]) : 11m sup
0 between two bounded on (-""',co)
F and 8 is defined as the Hausdorff distance between their complete
functions
graphs F and fJ :
r(F,B;a)
(4)
When The
Q'
r(F,C;a)
"'! one writes
Hausdorff
simply r; F, (])
distance
between
sets
was
introduced
( see [6] ). The Hausdorff distance between functions
by
F.Hausdorff
(see the definition (4))
was introduced by Bl.Sendov and B.Penvov [7]. In the theory of approximation the Hausdorff In
distance
was
systematically
used
by
the case of distributions functions
Bl.Sendov
(
see
[4],
[5]).
the Hausdorff distance ( with
parameter 1 ) is vnown as the Levy distance and is usually denoted byL(F,B)([B]) The definition of Levy goes as follows : let F and G (5)
L (F,
B)
= sup X
in! {Y:F(X-y)-y
B(x) £:
be distributions. Then
Fe x+ y)
+
y}
(- co,ee)
It is not difficult to see that (6)
UF,fJ)=r(F,G). The corresponding definition of the Levy distance of parameter 0: > 0 ( the
Hausdorff distance ) is the following: let (7)
r(F,{]j(X)
= L(F,[]jGr) =
F and G be distributions. Then
sup XE(-oo,oo)
inf{y:
116
- y + F (x - ex y )
Fe X + «y) + y }
(; (X)
We shall denote as usual the characteristic function of the distribution F by
.I
!(t>=jeitxdFe X
)
- 00
and
the
characteristic
function
of
the
distribution
G -
Our aim is to obtain an estimate for ru; Gja)( L ( F, G; Let us recall the well-Imown Berry-Esseen inequality
TI£OREM A. Let the distribution
F
0:»
by
g
by f and
g
[1],[2] for ,p(F, G)
satisfy a Lipschitz condition with
constant A . Then for every T>O we have :
+
,jVCF,G)
(8)
[1],[2].
The
Lipschitz
I F(x+h)-F(X) I
r
i- / o
condition
1I(f);9(tJI dt with
A
constant
means
that
A I hi.
Zolotarev's inequality for the Levy distance L (F, B) is the following [3] :
TI£OREM B. Let F and (; be distributions. Then for every T> 1,3
we have:
r (9)
LCF,B)
l;i +
/
!ICt)/(t)/ dt
o Notice now that there exists a connection between the Hausdorff distance with parameterO'>O and the uniform distance. Let us denote by w(F,'
g), cJ > 0,
the
modulus of continuity of the function F : w(F;8)= sup
{I Fcx+h)-FCX)!
:
E
(-oo,oo)} .
In probability theory the modulus of continuity is usually vnown as the function of concentration of the distribution F( see for example the book [9]). It is easy to see that the following lemma holds ([5],[10] ) : LOttA1. For everya>Oand for every two distributions
r( F, B ; cr ) 6.p ( F, G) 6 r CF, G; ex) +
w ( F, ex: r( F, G; ex») •
If the distribution F is continuous, then
(10)
lim r(F,G;o:) =,pCF,G).
F and B we have:
when
and therefore
117
The inequality (10) shows that the Hausdor ff distance with parameter ex' > 0 can be considered as a generalization of the uniform distance. But on the other hand it is clear, that it is not possible to obtain the inequality (8) directly from (9) and conversly. As we have already mentioned our aim will be to obtain an estimation for r(F,Bja) , from which
both estimations (8) and (9) follow.
Also from our estimation will follow the result of A.S. Fainleib [11], also [12, p, 94], which can be considered as a generalization of the Berry-Esseen inequality (8):
THEOREM C. let w(F;o) be the function of concentration of the distribution F. Then for every
r>o we have:
r +J IIU)-tq(t)/ --dt} C{W(F;y) 1
(11)
o where C is an absolute constant. If F satisfies a lipschitz condition with constant A ,then W(F;.!...)f:..1..r 7'
therefore (8) follows from (11) up to the constant. In the
of Fainleib [11), as well as in [12,p.94) the inequality (11)
is written in another, but equivalent form. The function h
.$(h) F
::=8UP X
c (- oo, oo )
-'-jIF(X+-U)-F(x-u)l d u 2h
o
is introduced and then the inequality becomes:
I f(tJ-g0 the following
inequality holds:
In (e +ex 1 W ( t)) (13)
+/
r
where C is an absolute constant.
1
!hiJ;g(fJ}
a
dt} ,
Before proving theorem 1 let us mal/-t
k e (O,JJ is fixed.
where
The main result in [14J reads as follows. THEOREM 3A. Every C-contraction on a complete Menger space (,5',
if , Ali TT
)
has
a unique fixed point, which is the limit of the successive approximations.
The proof of the above result is obtained from the deterministic Banach prin-
$
ciple, by constructing a metric on is such that f
which generates the
ie
,A
)-uni formi ty and
is a contraction with respect to that metr i c ,
As a matter of fact, the same proof is valid for a larger class of t-norms. This is due to the fact that the two-place funct ion d constructed in [14J is a metric in any Menger space ($,.7,7') if THEOREM 38. let ($ ,
d t p, C!) =
(6)
Slip
..r ,
{t,
T,.,,)
1m '
be a Menger space and define
FPq(t)
1- t}
.
Then (i)
d
is a metric on ;), which generates
the (c , A)-uniformity; (Lr ) Sis j -complete iff $
is
d -complete;
(iii)j:$-+$ is a C-contraction iff J is
d contraction.
PROOF. (i) We will prove only the triangle inequality. If
dcp, 1/) -c t,
rpqU,);::;.
and d(q,rJ -c t
!-t"
» 1- t 2
(t, + '2) which shows that
dt p.r)
2
":n( If,q 1- A
p=q .
LEtfoIA 3.3. Every C -contraction is (uniformly) continuous. PROOf. Let E> 0 and A
ko < min
ce , A)
e (0, f)
be given and choose
• Now if (P,q) e N( 0,0)
6>
, then
0 such that
'Pr';c cS) :> !- 0
.
Since
132
f
is a
F;
.i
p.;q
C -contraction, then we have that
F,
(6')
;rp.fq
(/(0) >/-ko >/-A
Therefore
F J. (krJ) > 1-/(0 .Ip q
, that is (fp,.fq) E N(E,A)
and the lemma follows. Now we can prove the following THEOREM 3C. S l/P
a0
n
J
0
and A t ( 0,1)
be given. Then by Lemma 3.1. there exists
such that (7) holds. Now i f
!P..
P =Pm
P. (E)::: F n n (c) > 1- A .f Pm! Po
n-ern n
Therefore that
C/o
P n
{p,.,}
J
and
/I rr
n (cJ
then we have
A) J V rrr
is a Cauchy sequence. Since $ is complete then there exists
converges to
qO'
is a fixed point for
From (9) and Lemma 3.3. it follows that .ff/ =- lf
f .
By Lemma 3.2
qo
o o
1
106$ such ' that is
is unique and the Theorem is proved.
REMARK 6. It is clear that the above proof holds in any complete probabilistic metric space, i f the (E, il) -topology exists, a situation totally different from what happens for probalistic contractions. REMARK 7. From Remark 5 it is easy to see that the classical 8anach principle is a consequence of Theorem 3C.
REFERENCES [1]
A. T. 8harucha-Reid, Fixed point theorems in probabilistic analysis,
Bull.
Amer-Math. Soc. 82 (1976) 641-657 [2]
G.L. Cain, Jr. and R.H. Karriel, Fixed and periodic points of local contractions on PM-spaces. Math. Systems Theory, vol. 9, No. 4 (1975-76) 289-297
[3]
Gh. Constantin, I. Istratescu, Elemente de analiza Ed. Acad. RSR, 1981
§i aplicatii.
133 [4]
O. HadHc, On the
(E.,
A) -topology of probabilistic locally convex spaces.
Glasnik Mat. 13 (1978) 61-:'6 [5]
PM -spaces ,
O. HadHc, A generalization of the contraction principle in Review of Research [lb. Radova] Prir. Mat. Fav. 10 (1980) 13-21
[6]
P. Mostert, A. Shields, On the structure of semigroups on a compact manifold with boundary. Annals of Math. 65 (1957) 117-143
[7]
D.H. Mushtari, A.N. Serstnev, On methods of introducing a topology in random metric
[8]
spaces.
Vysh.
Uch.
Zav.
Math.
6(55)
(1966),
V. Radu, On the t -norms of HadHc - type and fixed points in Review
[9]
Izv.
of
Research
[lb.
Radova].
Prir.
Mat.
Fav.
13
99-106
PM-spaces.
(1983)
81-85
V. Radu, On the contraction principle in Menger spaces. Analete Univ. Timivol.XXII (1984), Fasc.1-2, 83-88
[10]
B. Schweizer, A. Skl ar , E. Thorp, The metrization of
8M -spaces. Pacific
I. Math. 10 (1960) 673-75 [11]
V.M. Sehgal, A.I. Bharucha-Reid, Fixed points of contraction mappings on PM-spaces, Math. Systems Theory 6 (1972) 97-100
[12]
A.N. Serstnev, On the probabilistic generalization of metric spaces, Kazan Gos. Univ. Uch. lap. 124 (1964) 3-11
[13]
H. Sherwood, Complete probabilistic metric spaces. L, Wahr. verw. Geb. 20 (1971) 117.,.128
[14]
T.L. Hicks, On the theory of fixed points in probabilistic metric spaces. Review of Research [lb. Radova] Prir. Mat. Fav. 13 (1983) 69-80.
University of
Received 10.05.1985
Blvd. V. PSrvan No.4 1900
Romania
THE ASYMPTOTIC BIAS IN A DEVIATION Of A LOCATION MODEL M. Riedel 1.INTRlDUCTION.Consider a location model which is given by the parametric family
veRt
J={
where
F
is a fixed distribution function (d.f.) on the set
of real numbers and
tE IR.
(1.1)
In robust estimation theory the parametric model is not supposed to be exactly true. The observations
x,., X2 "
used to estimate
•• ,
the unknown parameter
V
are
assumed to be independent with a common d.f. which lies in some appropriate neighbourhood of the d.f. F
v
.The d.f.'s of this neighbourhood are interpreted as the
d.f.'sof the observations which are somewhat contaminated. The degree of contamination is measured by a number
e , O:!':
C
said to be an £ -neighbourhood of d. f. ;:;;
f{, .
ed a deviation of d. f. define a deviation
If = U
} of
HE (
1
. Then a class 11£ . The family
If the deviations of
.:F
11
11
0:6 e
of d. f. !E
I
S
is
I} is call-
for each velR are given"we may
by sett ing
r;,.)
tJ' IR Examples of deviations are the so-called gross error model and deviations based on neighbourhoods generated by some probability metric.
K
Let
be defined by (1.1) for K::: F
t
K(t) : == f- K (-t +) ,
E
IR
,
(A-2)
lie
(A-3)
H(K)=nH(K),
cf
E
(K) c He ( K) , 2
a: >£
7
IX
(A-4) (A-5)
8
'
1 (/() = 1(K)
,
by
For a general deviation we need the following
assumptions: (A-1)
and introduce the d. f. K
£2
,
135
(A-6) For each d. f. (J,
{t :
E
HE (/() }
is compact.
The assumptions (A-1), (A-Z) and (A-3) should be satisfied if preted as an
-neighbourhood. The assumption (A-4) means that the
is inter-
c
-neighbour-
c-
hood is equivariant with respect to any translation. By assumption (A-5) the
K
neighbourhood of the d.f.
c
can be easily obtained from the
-neighbourhood of
the d. f. K • As estimators of the locat ion parameter we choose statist ical functionals introduced by von Mises (1947), which are currently used in the theory of robust estimation. Denote the empirical d. f. of £n: = (%, •
r
the set of all d. f. • s , The functional
by
defined on a subset lJ
r
tional
r,
r
II,
contains
7!
where
{Tn: n = "
i(K)(
with values
n
is meas-
r (E £n)
T.' n ' --
2 , • . . } of est imators of the
• I f the observations X" %.2""
are
is wealdy continuous then { in}
independent with common underlying d. f. K and i f i is consistent to
jI be
and all empirical d. f. "s , Given a statistical func-
we may introduce a sequence
locat ion parameter
Let
n
of Jf
on JR will be called a statistical functional if the urable and i f lJ
C£.
see Hampel (1971) or Huber (1981), Proposition Z.6.1).Then
it is convenient to discuss the quantitative large sample robustness of the behaviour of its asymptotic values
irK)
terms
.For this reason, it may be use-
ful to consider the maximum asymptotic bias
r
of the stat ist ical functional criterion
in an
e
-neighbourhood H£ as a robustness
.
Since statistical functionals are used to construct estimates of the location parameter they should satisfy some add it ional conditions. Here we require that the statistical functionals are translation equivariant and antisymmetric. For further conditions on statistical functionals we refer to Bi ckel and Lehmann (1975) and Staudte (1980). Note that a funct ional T is translation equi variant i f for each
J'
E:
that
IR we have
i ( K) = - i ( K)
irK)
+J'
.The antisymmetric property of r
. Here and in the sequel
with respect to any translat ion and symmetric, i ,e . lJ
r
means
17; is assumed to be closed
:= {
Jt :K e 4 .j't' R }={K: Ke 4}.
136 Let jP be the set of all translation equivariant and antisymmetric functionals containing
in their domain of definition. Our main purpose is to determine
the minimum risks
4( e, hi):
Bt(c,hi): = inJ{
in! { 6 ( e, 7') :
6(8, 7'): 7'(£ j ,
reF) = o}
The second risk des-
cribes the case where the true location parameter of the d.f. ed by a functional
F ,which is measur-
7' , is zero. We remark that this risk is well defined if there
does not exist any symmetric d. f. $ we
and
7' .:f }
such that F =
for some
I
=P 0 . Besides,
will derive the most robust functionals which attain one of the minimum risks. The location parameter
family
J
zr
can be extended to the
e -neighbourhood
of the
in the following way. Define the minimum location parameter of the d. f.
K in the
E -neighbourhood
hi by
Similarly, the maximum location parameter of K in HE is given by
at i«, e , 1):
sup { ! : )( c
1 ( fj.) }
These location parameters considered as funct ionals of K are translation equi variant but not necessarily antisymmetric. However, if the d.f. F is symmetric, then the functionals
are antisymmetric. As we shall see the minimum
can
be expressed by means of these extensions of the location parameter. In the
case where the d.f. F
is symmetric and unimodal, Huber (1981) has
shown that the median is most robust with respect to B, ( e ,
1-)
{1t
where
is the
gross error model or the deviation induced by the levy metric. Our aim is to get rid of assumptions concerning the unimodality and symmetry of d. f. F • In section 2 a presentation of the minimum risks by means of the minimum and maximum location parameter is given for general deviations
of!f and arbitrary d.f.'s
F .
Section 3 deals with the minimum r i sks with respect to deviations based on metrics. An upper bound which is given in Theorem 3.1 turns out to be strict i f the d. f.
F
is symmetr rc , Moreover, it is shown t hat Huber's result cannot be
extended to location models with symmetric d. f.
F . For deviations
based on the
137
Kolmogorov metric and the Levy metric, respectively, the minimum
can be ex-
F . Finally, we
pressed as some quantiles of a symmetrized version of the d.f.
establish the most robust functionals with respect to these deviations. It is worth noting that these functionals coincide for both deviations.
2. RESULTS FOR GENERAL DEVIATIONS. Let
be an arbitrary deviation of the
family .;: and suppose that all assumptions (A-1) , (A-2), .•. , (A-b) are satisfied. Putting 1
.
- -
C ( K) : = ;- min (at ( K,£ ) - ao ( 1(, c), a, ( 11, c) - ao ( 11, c)) where we have written 0(11,£) for
fj(f(,c,1)
we may formulate the result concerning
the minimum risks.
THEOREM 2.1. (a) The minimum risk
t e, He) = sup
{ O( K) : K
4(£,1) (F)}
is given by .
(b) Suppose that there exists some funet ional Tc minimum risk
4 (e, 1-)
J
such that
T ( F)
=0
. Then the
is well defined and we have
B, (£·1)= max ( Bo (c .1
) , mine '!lax J =0,1
I (y F, £)),
r;'a.r I aj (,;;£)/))
J=O,1
For the proof of Theorem 2.1 we refer to Riedel (1985). The same method as used in Riedel
(1985) gives the minimum r i sks in the case where the functionals
considered
only
are
translation
equivariant.
Zi e.l i nak i (1985) have obtained the minimum risk
for general d. f. 's
the
.B, (£,1-)
latter
case
and
for unimodal d. f. 's F
• Applications of Theorem 2.1 to gross error devia-
and the gross error model tions
In
F
and symmetric ones are studied in Riedel
(1985).
COROLLARY 2.1. Let F be a symmetric d.f. (a) Then
(b) The functional
fa
defined by
is most robust.
3.MINIMUH RISKS OF DEVIATIONS BASED ON METRICS. Consider a deviation which is given by the
e
-neighbourhood with respect to the topology induced by a proba-
138
d
bility on metric
on
He ( K) =: {
II : L
: d ( K, L)
e ;u
E }
£,
For this deviation the assumpt ions (A-1), Moreover, if the metric
(A-2),
(A-3) are obviously satisfied.
has the properties
for all rf G!R and
d ( i,l)
(3.2)
= d ( K, L) , K, L £ I' '
then the assumptions (A-4)
and
(A-5)
are also satisfied.
variation distance, the Kolmogorov metric
Note that
,the Levy metric
the total
, the bounded
Lipschitz metric and the Prohorov metric are examples of metrics for which the corresponding deviations satisfy the assumptions (A-1), (A-2), ... ,(A-6) First we start with an upper bound of the minimum rislts.
THEOREM 3.1. The following inequality holds:
4 (E,1)
(3.3)
PROll':
Choose
{ Kn
sequence
a
lim
(3.4)
a,( F, 2 E , He )
;
n.."oo
C(Kn )
t
of
Kn e
d. f.' s
1: (F)
such
that
= BT (£,1>
and put
s.:
a·(K.n , £ ) and
In
for
.i »
J
t.In
:a.(kn , £ ) J
0 ,1. For analogy, we restrict ourselves to the case where
finite for all numbers (3.5)
n . Then (Kn )_ s. e He ( F) ;;n
and
are
;this is equivalent to
d(F,(Knts. ) e e . In
Hence (3.6)
Similarly,
it
follows
(3.7)
d (If
In
_t
On
from
,F)
£,
(3.1),
2 e .
(3.2)
and
the
triangle
inequality
that
139
From (3.6) and (3.7) we get
=f
C(Kn )
min
sOn ,tIn - tOn ):6
(SIn
-2'
a, ( F, 2
)
and in view of Theorem 2.1 and (3.4) the proof of the statement (3.3) is complete. It is interesting to
when does the inequality (3.3) become an equality.
Let us first introduce the following assumption on d (A-7)
For
any
two
d.f.'s
K
L
and
there
is
a
G
d.f.
such
that
d ( K,Ll ma.x(d(K,B),d(L,G)):6 - 2 -
(3.8)
Using the triangle inequality we see that that
:
K
(A-7) holds if for any d. f. 's
in fact,
an equality. Note
L
dCK,L)
/(fL
2
d(K'-2-)
(3.9)
and
(3.8) is,
is true. The assumption (3.9) holds for the total variation distance, the Kolmogorov metric, the bounded Lipschitz metric and for many others. However, for the Levy metric (3.9) is not satisfied. To see this, choose /(:=
0
c{ (I(,L)
K
and
L
with
+
let us define the d. f.
%rt ):=
(ma.r(/((t-E), L(f-e»+ min (/(Cf+c) , L t t» E))
From the definit ion of the Levy metric we conclude that L (i-E)-E :6 K(t+ E) -I- e As this inequality is also true for K:=:L tf
we get
.
max(KCt-E),Lft-E))-c
min (/((ttE),LdfEJ)+c and consequently
(3.10)
Using now the fact that implies (A-7) since
B£
converges weak Iy to
metrizes the
&;'0
(3.10)
as
convergence.
Unfortunately, neither (3.9) nor (A-7) are fulfilled for the Prohorov metric. For this fact we give an indirect proof and assume that (A-7) is true. Then, in particular, for /(:
= 80
and L:
{Wi th 0< E 0 . This inequality means that F is concave for t >0 and the sym
l/
F
is convex for t '" 0
F
yields that
; i ;e , F
is an unimodal d. f.
For the proof of the sufficiency we assume that F is symmetric and unimodal. Then (3.19) is again valid and entails that F=F
because for symmetric d.f.'s
supremum in the definition of F can be restricted to
F the
0 . In view of Corollary
{j
3.2, (3.18) holds. It is worth noting that for an arbitrary symmetric and unimodal d.f.
Eo ( e , dr-v)
establ ish that Let us
£:
Eo ( e,
However,
in the general case we can only
dl() •
now turn to the problem of finding
THEOREM 3.5.
Let
F
the
dr v or on the Kolmogorov
deviation based either on the total variation distance metric has the same minimum risk.
F
be a symmetr i c d. f.
the most
robust functionals.
Then the most robust functionals
relevant to the deviation based on the Levy metric and on the Kolmogorov metric, respectively , coincide and the common most robust functional is given by T(K)= -;- CSl/p{
t- !1,( F, I((f)
+ C' J :
t < ()O( 1(, IE) }
+ inf{t-QoCF,K(f)-eJ:t>a,(K, J}J. PROOF: In view of Corollary 3.1 the most robust functional with respect to the devi-
ation based on 1'( K)
is given by
=
ao ( 1(, e ,
l
2
a, (/c.s ,
)
Therefore, we have to derive S(K,e, df,) ( j
= 1,0)
when these expressions are
finite. By assumption, there is some SE/R such that 00
« ao ( /(, e , c{)
£: S
at ( /(, s )
O,k= 1,2, is bounded. Thus we see from k , , H the above proof that LI, ' Llz are bounded in +' 1. Clearly, we may assume
U;
02 .
Now we combine (3.7') and (3.13) to ob-
tain first
Thus
I I ' =0 /..J,
by L.2.2. Now the same relations imply Li" z(tS)=OCexP(-'l 222 Sf )+ 8X,) whence
Ll; =0 follows from L. 2.2. 2.
Let
In
this
case
rewrite
(3.7)
in
the
form whence
follows. Sin"e we already I0 there
x(Ll) e [0, Ll J
exists ing
on
the
such that the funet ion
interval (-
00 ,
XC Ll »
FrXl-F(X-Ll) is non-decreas-
and non-increasing on [x(Ll) ,+ oo } •
PROOF. By the unimodality of F,
.f'or :r < 0
.for The function F(x)-F(X-Ll) has no negative jump at
(0, Ll)
,and has no positive jump at
Ll . •
X
> Ll
0 , is concave on the interval
160 1
F be a unimodal cdf with the mode at 0, let £ et t), '2), and let
L£tI4I\ 2. let (2.8)
Ll
»; Svp{ Ll : sup (FeX)- Fux- Ll») X
6 -E, }
-E
Then (1)
"*= 0
Ll
P=
iff
Z
(ii) There exists
T
(2.9)
z
,If.
F ( OJ - F ( O- )
Z
p
In particular, if
_c_ 1-
PROtF. (1) L)
*" is
e
«! - e) F + e) ::: Ll *" .
then (2.9) holds iff
c
U-E)F(O-)+
(2.10)
1-
EO [E,!-EJ such that
(i ]: E) F) - T "
ff.
=::
e
==
(I-£)F(O)
Z7f
*"=0
a finite non-neqat ive number. Obviously, Ll
¢;;f; 17 {.x: FrxJ-Fex-Ll) > ---.L} {.x:
.
d>O
f-E
The only possible jump of F is (ii) First suppose that
P
p
0
:!f. such that F( x)- F(x - L'.J)
O.
and, according to lemma 1, we can choose
is non-increasing for X
=
X (L'.J 'f). It is easy
to checl00.
Ll* and Z
such
additional condition liminf'liiCn-fL(n)-Z"»Uor
n
liminf C
>0
n
res-
pectively. We claim that
71'*=(%L Z
(n):n
-TJI'(F))co Z n= 1
is uniformly asymptotically most bias-robust statistic in the class
Ji . The state-
ment is based upon the following theorem.
ZE"Cc,r-eJ
THEOREM 2. If for any fixed
(L (T7))
n": 1
the sequence of integers
satisfies the conditions
,
(i)
=0
(3.1 ) (Li )
lim (n-fL(nJ-Z)
(3.2) (iii)
liminl n
(3.3) (iv)
liminfVii(1-c-n-'L(nJ»0,
J
Vii (n-fU ni- c) > 0
J
T1
then
lim n...,oo
PROOf.
The
(3.5) 13
and (3.6)
c)
r;«(1-£)F)-
(3.4)
idea
1XL cm :n
of
the
proof
as
follows.
7' «(;')-o} < 2' Z
(Vv> 0) (3!1o(oJ) (lin >
p{x G t tn y r n
is
VG'e TlCO))
Z
This implies that (Vn > maxi no (oJ ,
(O)}) (V G' e Tl({lJ)
We
show
that
164
7'z ((])- 0
/;f (
IJ, XL
tn ri n
)
T (IJ) ... Z
rJ
cn i: n
and hence
)
I-z{U- JF)+J
which proves (3.4). Taite
cS > 0
if = Cfr;
and define
C(
p{](X . == L (n).n 1ft]
is such that
k=Lrn)
fir;
(X /] Lt m t n
('k)7kU-Q)n-k.
, then
7: (B)-O)
p
(/] )-rJ) • Then
Z
,f:
rt
k=:L(n)
(kn ) e
k
n k
(/-C) -
and according to the Berry-Essen theorem
PIi(X l
(3,7)
L.
where
t/J
(ri ) :
tjJ (
n
6I- (/]) - 0 } Z
2
c+(/-£J
nE-L(n) )
Vnett-e)
+
2
VE(f-E)
is the standard normalcdf and c is the universal constant (cf . e.g. Bhatta-
charya, Rao [1976], th.12.4). Taite an arbitrary a (O,liminfVii(n-'L(nJ-Z») . Since V!i(E-ti'L(nJ) I, Ilmtn n V2E(1-£)nloglogn n instead
of
(3.2)
and
(3.3)
(cf.
Feldman,
nt t-se) - Len)
V2 E (t -
Tucl I, 5).
REMARK 2. Actually our solution is optimal in a wider class of estimators, namely in the class of asymptotically invariant ones. Obviously, i f then our sequence is the best one in the class of all estimators.
P .=
e
-1-
-£
166
4. Asymptotically most bias-robust estimators for particular models. In this section we give simple applications of the general result of the previous parts of the paper. Namely, for some specified parent cdf jC we write down explicit formulas for the asymptotically most bias-robust estimators of location under £ -contamination of the model J={F(x-B):B R}. Once aqa i.n we put a special emphasis on the Huber's solution, which covers many very important cases when F is symmetric. Our results allow us to extend the class of solutions also in the symmetric case (see e.g. examples 1 and 2 below). Observe that in order to determine the optimal se-
.:r we have
quence 71''N E Z
to find the appropriate Z:N' E [E,
t-
EJ
• Then we calculate
and choose the sequence of integers L tn} =L * (n) , which fulZ fils the conditions (3.1)-(3.3). We add the index z* to L *(17) to stress the
the values
rZ if ( F)
Z
correspondence expressed by (3.1) -(3.3). In the examples we omit the calculations which are trivial, and confine ourselves to presentation of formulas for the optimal
z", I*(F)
and the measure Ll
z
if
B
or,,) of
the asymptotic bias-robustness.
£ Z"
EXAMPLE 1. Degenerate parent cdf. Let F(x) 1
CO,=)
order stat istics (X
)
00
L(I7): 17 17= 1
(X).
Then every sequence of
such that (l (17»);' 1 satisfies (3.2) and (3.3)
is absolutely asymptotically bias-robust estimator of location under
S -contami-
nation.
EXAMPLE 2. Uniform parent cdf. Consider the cdf
FrXJ={ Z
For every
Z
L(I7):n
_
Z
x
1
-Z+
E
B (71')--E
1
x+y
E [£,1-£J
F=(X
1 -
e
1
:x:
O} ,
J = 0, .. . ,M
by
Let us denote
REMARK. The condition C1 trivially holds for N= 1 or
N > 2
Denote
are independent and they
Jk
}k ?: 1
-I
P( (N-I) 0901 < Sjr < ( N- t )
in the case
notation.
a sequence of i.i.d.r.v.-s on the probability space
are not dependent on the sequence
C1.
we introduce
j
M . Since the r , v .-s
are independent, from the condi tion C2 follows
O«N-lf'xo"" ll'...,;;
J
a:;.fr*«N-J)X*':
(N-l)
(N-1) S,,) > 0 S01)
:>
generation points must be considered on the 1-st queue.
0
, because an
. In this case the re-
185
=/'.;.(1),
Let us denote
(4)
{ k :
j == 0, ... ,,H M
-I
(N-tJl'f
J
=2
J
and K= N
.' s
I=R(k)-1(+1
R(k)-1
B.
t > 1'
!=Rrkj-N+1
and let us define recurrently the sequence of r , v , -s
where [xJ +==
max (x, 0) .
It is clear that the r.v.-s
of virtual waiting times in the inter-arr i val and serv ice times
YI(.== min
{
k : C* k
B
k,1
}
BIG)!
f R} k,1
f Ck if}k * Ck,k
.S , k I
f
1 , as follows:
mean the sequence
system with the sequence of independent
{(]k } If
c":» k k,1
Let us denote holds for eachk;;'J ,
186
then we have Y*
=00.
*
Let us define the events
fk
is easy to see that if the event
k::2
plementary part of the event
c
(
c
n ... n Fk
If
P ([e1
::::
.o"I J n [B',2 > eR
It is clear that
c
,
P(v=k)
c
where F: denotes the comk
. It is simple to prove that
C
(1 ) J
C
n fj; n '" n
* t
',I
n
In...nCCkIf-1 >.B.k -1
If
k
k,l
On the other hand the sequences
,{
K Ck+l- C k+1
the equal i. t y
notation lIo = l , Uk ",P(v=kJ;:{=O, (7)
From (3)
I'j
(1')
= . Uk_ 1+ ••. -I-{-1 we get ["Ok < E4,1 •
8' , J
assume
M the d. f. 1
SOM
that
the
fj IX)
condition
C2
is
satisfied.
is not degenerative, then from the
follows that there exists a number Ll > 0
+ Ll ) + P(
$'1). So J 1
+ Ll)J >0
•
,for
188
Without loss of generality we may assume that
P ( SOt::>
S"
+ L1 ) + P ( Sf! > SOl + Ll ) > 0
P( So, > SIt + Ll)
We prove the theorem in the case
:> 0
. I f the condition
P(Stt':>
So,+,1»O
holds, then we can prove the theorem in a similar way. ( In this case we examine the
sequence
of
regenerative
moments
of
time
in
the
1-st
queue
).
Denote
Let us define the sequence of r , v. . (11) the re.Iat ion (/(- 1M 2
*
'Jt1?
?:(IV-t):ro >(N-t):J:,j ;
=([
(N-fl L1
J> t, ... ,M
RW), R (f)
IS
»:0 ] + 1).:1
according to (5). From (2) and
follows, therefore in the
moment of time
T( R (kl)-eR(kJ the customers may be only in the CQ and the 1-st queue. Those customers which are in the moment of time T(R(kJ)-eR(k) , in the 1-st queue ,arrived at the queue after the moment of time i(R(kJ)- eR(k)
IV-I
the first queue is not greater than
• The number of customers in
and the sum of required service time is
not greater than
R(k)-'
r: =.;;E:7, k
denote
l:::
V
S
I, == max (R(k)-K+ 1, R(k)-N+ 1)
,where
.l
=mrn fl: Fl
Since the sequences { fk }k
eRa) }
?: f
.Let us and
f
are independent and on the basis of theorem 3 [7, p.199) they do not depend on the sequence {R( k) } and
PCv=k)= P( k
where
, then the r , v . V does not depend on the sequence
r, > eR(f) , ... , fk _t > eR(k_O •
eR(k)=
a- P (ifi (Soz- S,z) > k!J ) > 0 .
From (6) follows that there exists some
> 0 ,for which
member
('-(J)Eexp(4o lf )< ! ' Thus
£exppoR(v)} =£exp {ito co
k
k=f
i=!
'=.L': c J('i=k) exp{
i/
1::::f
1
r.}
0 1
fl eso k == 11-1 i5[U-I))(Eexp{Ao '1 }J] < from which the theorem follows.
OQ
,
{R(k ) J f1 ,
189
REFERENCES
1. Sauer C.H., Chandy K.M. Computer systems performance modelling, Prentice-Hall, Inc., Englewood Cliffs, New Jersey, 1981. 2. Iglehart D.l., Shedler G.S. Regenerative simulation of response times in network of queues, lecture Notes in Control and Information Sciences, SpringerVerlag, New-York, 1980, 26. 3. Kalashnikov V.V., Qualitative analysis of the behaviour of complex systems by a
trial
functions
method
in
Russian
),
Nauka,
Moscow,
1978.
4. Szeidl l. On the estimation of moments of regenerative cycles in a closed Central-server queueing network ( in Russian ), Teorija Verojatn. i Primenen. (in print ). 5. Feller W. An introduction to probability theory and its applications, John Wiley, New York, 1970. 6. Szeidll.On the estimation of rate of convergence in the renewal theorem for a discrete irreversible case, ( in Russian ), Stability Problems for Stochastic Models. Proceedings of the Seminar,
Moscow, The Institute for Systems Studies,
1985, 121-126. 7. Borovkov A.A.
Probability
theory
in
Russian
),
Nauka,
Moscow,
l.Szeidl, Eotvos lorand University Computing Centre' Budapest, H-1117 Bogdanfy u.10/b
Received: May 10th,1985
1978.
ON F-PROC£SS£S AN> THEIR APPLICATIONS
L. Vostri"ova
ABSTRACT.We consider the f-divergences of probability measures on filtered spaces and define the corresponding f-processes. how the f -processes can perties
of
probability
We show
be used for the investigation of the promeasures
and
statistical
estimators.
KEYWORDS: f-divergence, Hellinger distance, Matusita distance, f -process, Hellinger process, Matusita process,convergence in variation, entire asymptotic separation,(Cn)-consistency. INTRODUCTION. The investigation of such properties of probability measures as absolute continuity and singularity, contiguity and entire asymptotic separation has brought the notion of Hellinger process
liptser and Shiryayev [10],
Memin and Shiryayev [11], Jacod [4], which seems to be useful for obtaining simple "predictable" criteria in the above problems. The Hellinger process is also useful in many statistical problems, for example
in studying the
(ell)
-consistency of estimators,
in obtaining limit
theorems for the likelihood ratio processes and statistical estimators etc. In these problems the general statistical parametric models are
usually considered
and the conditions on the Hellinger process becomes restrictive when the dimensionality of the parametric space grows. This makes it necessary to generalize the notion of Hellinger process, more precisely to investiagate f-diveregences and f-processes. This paper consists of three parts: in the first one we introduce the notion of the f -diveregences, in the second part we investigate the f -processes and the third part contains some applications.
191
lor-DIFFERENCE
OF TWO PROBABILI TV MEASURES. Let (Sl.,F) be a measurable space
P
with two probability measures P and
a .Denote
P« Q ,P«
= dP/dlJ and
by
=0
0/0
Letj=.!(x,Y)
and
¢ =dP IdQ
P with
Radon-Nil0
every
be a nonnegative homogeneous convex finite function on R x R
OCF INITION 1.1. (Csiszar [3]) The
.f -divergence of two probability measures
P
and P is
.P; ( P, P) : : :.
£Q.f ( ( ,
where £61 is the expectation with respect to
61 .
REMARK 1.1. From the homogeneity of .f we get that the j -divergence does not
a and
depend on the dominating measure () . Indeed, i f Q« Z'= dQ/d{)'
dP/dQ',?'=dPldf:J.:
then
In the general case we use these equalities for the pairs of measures Q, and Q', ( Q + Q')
12 .
REMARK 1.2. The f-diveregence of P and true for Q = (P + P) /2
measure
Q'
P t akes only finite values. This is
because of the continuity of convex finite functions on
open set and the inequalities 0 dominating
(61 + Q')12
we
=
0 }nF= r, the
Lebesque monotone convergence theorem.
COROLlARY2.2.For every stopping time
.P U;., fiT ) ==..P/ f
T
T we have
! 9 ( I, Zs-) dhe
+ E 0
result follows from the
196
IT = PI Fr '
where
= PI
.
let .¥ be the set of all
1F -stopping times and IfJ{Zrl=Rf,Z7:) -:I CO, 1)21: for
gO,zsl,C2 =SlIp{£/ rp(Zrl!r:t:/kx.
to,]'. For a given a>! we set
s>O 'l" ,J: there isa>!thatq.O we
THEOREM 2.2. have
_
Pa) + c, E + 2 c2 P
(P, p ) ..p;/ (
jJ
where
=IX /
(
ex -
flfJ
( hco
?:
8)
1) •
.Since h is a predictable process,
PROOf. Let
re
is a
predictable stopping time and there is a sequence of stopping times (z,/lk 1 such k
that I" < r • r '"
II
k
as k-+oo.
t7:
II
For every
and
t >0 we
get
;
,15 k )+,?,(P k 'eAt f 't:'e Af
reAt
f
,Prk/l t e/l
)
and by corollary 2.2 (8)
e
+ Cf
e
8
'
,
the process h is being nondecreasing. Since.p, (. , .) does not depend on dominating measure we can t ake 11
f
=(P+ PJI/?
Changing the measure ( see Liptser,Shiryayev [10] we have
= E:I(f,Zt)+f(O,n p (
l=
(9)
't
=0)=
«(l,IJ
By (9) and the Cauchy-Schwartz inequality we obtain -
P
f
(10 )
:f
E I
0
198
n n tx n wherejJe is the Hellinger process corresponding to P, P and
IF
n
.By theorem
3 of (12] we also have
n
n
2
e)
P (dt'oo
E + (f + 2/ e
) .fJ2 (P n, P-n)
2
,
which together with (11) gives the result. REMARK 3.1. In discrete time this result was proved in Vos t r Ikova [15], for point processes in Liese [6] and in the general case it was obtained by Liptser and Shiryayev [10] and Kabanov[5].
n -/? DEF INITION 3.2. (Le Cam [7]). The sequence (P, P )
is called entirely
n
asymptotically separable ( denoted (P ) Ll (P
) ) if there exists a sequence . . . n' n' I and P (A )-+1 as n-+oo.
n r n' n' n' A e F such that P (A Let
n
e" and
be the Radon-Nikcdym derivatives
n -n (P + P ) /2
to
Q::::
for
a >0.
defined as in (1) and
Z/ Z:!
We also set (Xn=
PROPOSITION 3.2.
lim
n
-n
I {
Z =
wi th (;(on=
of
P
n
n
with respect
supposing OIO=o,aIO=oo
1.
Suppose that
lim pn( inf ex; S >0
1/ R)
n-,>oo
O.
n
_n
for the entire asymptotic separation (P ') Ll (P)
Then
-rn
P
and
a necessary and
sufficient condition is
lim
L.,.oo
lim Clo
-n ri c-r: n xn ,r:r;::::nPROOf. Notice that (P)L1(P ) if lim f{(P,P )=0 where f{(P,P )=EnVSS"
n
rr-o cx:
is the Hellinger integral of
1/2.
oe
0, = (JRL)
REMARK 3.2. Liptser,
-1
theorem £:;
4
of
,c2 = ex p ( c,-2+ 2)
(13]
we
get
2L)}'/2
n( inl cr n C, + C f1 ( p7 pn) + p 2 8>0 t
L)
pn(/}fn
{J
From
H(P7p,)
(12 )
where
order
fiR)
,which proves the proposition.
The similar result in discrete time has been obtained by
Pul
•
Thus the sequence (C ) is such that the distributions of random variables
n
CnlBn - a')
with respect to Pen, are tight uniformly over the set
and it also has the maximum order of magnitude. In order to formulate the results we introduce some notations. We say that a nonnegative function 0.
(15)
where JJ' is a constant independent of
L.
PROOf. Using theorem 1 of [14] wi th r-emarks 4 and
q
-
lim
1)
Sl/P
n.o,oo
2)
lim
Wherep
q
n
fltj (PO
sup
n
I
PO+C-f l/ 13 n
luI
IO/£:L. IU/6L.
n
n
) 6 IlL
N)
and mave use of inequality (12). Let us go over to the proof of point 2°, i. e. to the proof of
02 c -indepen.
2 dence statistics X and SN • It is not difficult to get convinced that N
(13)
$;
u,
0 and A is defined on the
CJ ( £) 2': C/a ( E)
Thus, let us choose a variable
(see (32),
-1
(n-1)
N (t .. nIt j
where fJo==goCc)=V2Alnl/E basis of inequality
4
. Making use of (30), we obtain:
/RitJj
Repeating
IR (t)/
R ( t) with 4
•
A .
Since for
It I
q
221
2
(41)
Let us get convinced that if lJA=
eO i.e.
,then for
V(3ln 1/£)/(]](n+2)) .
that This
n- no 8/2
is
carried
If(tJl
out
by
a
direct
exp(-17Aln f/c) 4£
For the given value lJA:=:
substitution
of
(39)
N
(102 + nqo3 /8)
!-no- 0/2 the right-hand part of this inequality is not
constant, depending only on
n.
X1
where
ep )
Substituting the value
C5 ( Zn 11£)
1J
q/=
is some positive
1/£
F;(X)=P(Z