Some central limit theorems for ℓ∞-valued semimartingales and their applications

This paper is devoted to the generalization of central limit theorems for empirical processes to several types of ℓ∞(Ψ)-valued continuous-time stocha...

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Probab. Theory Relat. Fields 108, 459 ± 494 (1997)

Some central limit theorems for ``-valued semimartingales and their applications Yoichi Nishiyama The Institute of Statistical Mathematics, 4-6-7 Minami-Azabu, Minato-ku, Tokyo 106, Japan (e-mail: [email protected]) Received: 6 May 1996 / In revised form: 4 February 1997

Summary. This paper is devoted to the generalization of central limit the1 orems for empirical processes to several ÿ n;wtypes of ` W-valued continuousn time stochastic processes t , Xt Xt jw 2 W , where W is a non-empty set. We deal with three kinds of situations as follows. Each coordinate process t , Xtn;w is: (i) a general semimartingale; (ii) a stochastic integral of a predictable function with respect to an integer-valued random measure; (iii) a continuous local martingale. Some applications to statistical inference problems are also presented. We prove the functional asymptotic normality of generalized Nelson-Aalen's estimator in the multiplicative intensity model for marked point processes. Its asymptotic eciency in the sense of convolution theorem is also shown. The asymptotic behavior of log-likelihood ratio random ®elds of certain continuous semimartingales is derived. Mathematics Subject Classi®cation (1991): 60F05, 60F17, 62E20 1. Introduction This paper is devoted to the generalization of central limit theorems for empirical processes to several types of `1 W-valued continuous-time stochastic processes. Here W is a non-empty set, and we denote by `1 W the space of bounded real-valued functions de®ned on W. In order to explain the motivation, let us mention the results for empirical processes developed by Bolthausen [8], Dudley [10], [11], GineÂ and Zinn [13], [14], Ossiander [28] and Pollard [29], [30], among others. Let E; E; P be a probability space, and fZi g be an independent sequence of E-valued random variables identically distributed with P . For given family W of square-integrÿ able functions on E, consider the stochastic process X n Xtn;w jt; w 2 0; 1 W de®ned by

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Y. Nishiyama

Xtn;w

Z nt 1 X p wZi ÿ wzP dz 8t 2 0; 1 8 w 2 W : n i1 E

1

Then, the central limit theorem says that, under appropriate conditions on the family W, the sequence of `1 0; 1 W-valued random elements X n converges in distribution to a Gaussian limit (but most authors considered only the terminal variables, i.e. t 1). Recently, those results are generalized to non-i.i.d. cases by several authors: to row-independent arrays by Alexander [2], Andersen et al. [4] and Pollard [31]; to stationary sequences by Arcone and Yu [5] and Doukhan et al. [9]; to stationary martingale dierence arrays by Levental [25] and Bae and Levental [6]. See also the review by Wellner [34]. Now, ®x afresh any non-empty set W and a positive constant s. Set S 0; s or fsg, and denote S S W. In this paper, we establish some central limit theorems for `1 W-valued continuous-time stochastic processes t , Xtn Xtn;w jw 2 W as `1 S-valued random elements. To be more speci®c, we consider three kinds of situations as follows: (i) each coordinate process t , Xtn;w is a general semimartingale; (ii) each t , Xtn;w is represented as a stochastic integral, namely, ÿ Xtn;w W n;w ln ÿ mn t Z W n;w x; s; xln x; ds; dx ÿ mn x; ds; dx ; 0;tE

where W n;w W n;w x; t; x is a predictable function on Xn R E, ln is an integer-valued random measure on R E, and mn is the predictable compensator of ln ; (iii) each t , Xtn;w is a continuous local martingale. The results for (ii) and (iii) are proved by using the one for (i). The empirical processes are the special case of (ii). Sections 2.1, 2.2 and 2.3 are corresponding to (i), (ii) and (iii) above, respectively. The central limit theorem for 1-dimensional semimartingales was established by Liptser and Shiryaev [26], and has been expanded further into the more general limit theorems for ®nite-dimensional semimartingales, including the cases of non-Gaussian limits. We can consult the excellent books by Jacod and Shiryaev [22] and Liptser and Shiryaev [27] for those results, and use some of them to show the ®nite-dimensional convergence in our situations. On the other hand, many techniques to show the tightness are due to the previous works [4], [6], [13], [25] and [28] for empirical processes, and to Chap. 11 of Ledoux and Talagrand [24]. Our approach is essentially same as the one in empirical process theory, however, our framework and results are much broader. Further, new applications to statistical inference problems for stochastic processes are presented in Sects. 4 and 5. In Sect. 4, we consider the multiplicative intensity model for point processes with general marks. Let E; E be a Blackwell space on which a rÿ ®nite measure k is de®ned. For every n 2 N, let Tin ; Zin ; i 2 N be an Emarked point process, where 0 < T1n < T2n < a.s. and each Zin is an E-

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valued random variable. Suppose that its predictable compensator mn is of the form mn x; dt; dz at; zY n x; t; zdtkdz ; where at; z is a non-negative real-valued measurable function on R E, and Y n x; t; z is a non-negative real-valued predictable function on Xn R E. This model is a generalization of Aalen's multiplicative intensity model which is widely used in the context of survival analysis (see Aalen [1] and Andersen et al. [3]). We introduce certain class W of measurable functions on 0; s E, and consider the estimation problems for two kinds of `1 W-valued unknown parameters. One is the (weighted) cumulative hazard function A Awjw 2 W given by Z wt; zat; z dtkdz ; 2 Aw 0;sE

and the other is the (weighted) distribution function F F wjw 2 W given by Z Z F w wt; zat; z exp ÿ as; xdskdx dtkdz : 3 0;sE

0;tE

We introduce the generalized Nelson-Aalen's estimator for Eq. (2) and certain natural estimator for Eq. (3), and derive their asymptotic behavior by using the result in Sect. 2. We also prove their asymptotic eciency in the sense of convolution theorem. In Sect. 5, we consider certain regression model of continuous semimartingales. Let W be a family of locally bounded measurable functions on R , and fan g be a sequence of positive constants such that an " 1. Let X n be a real-valued adapted process on a ®ltered probability space ÿ n n n continuous X ; F ; F ; Pn Phn ; h 2 W such that, under the probability measure Phn , it has the semimartingale decomposition given as follows: dXtn anh tZtn Ytn dt dMtn;h

with

anh t at aÿ1 n ht ;

where a at is a locally bounded measurable function on R , Y n and Z n are predictable and M n;h is a continuous local martingale with

n;h R processes, t n n;h 0 Ys ds. We derive the M ;M t ÿ asymptotic behavior of the log-likelihood ratio random ®elds t , Knt Kn ht jh 2 W where Kn ht log

dPhn jFnt : dP0n jFnt

See LeCam [23], Inagaki and Ogata [21] and Yoshida [35], among others, for such results in ®nite-dimensional parametric models. We apply it to construct a goodness of ®t test. Now, let us state some notations and de®nitions. When a pseudo-metric q is de®ned on S, we denote by Uq S the space of uniformly q-continuous real-valued functions on S. Convergence in distribution is considered in the Banach space `1 S with the sup-norm jj jj1 . Since this space is not nec-

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essarily separable, we use the following de®nition of convergence in distribution due to Homann-Jùrgensen and Dudley (see e.g. Homann-Jùrgensen [19] or Sect. A.8 of Bickel et ÿal. [7]). Let X; dX be a metric space. Let a n n n n? sequence ÿ of probability spaces X ; F ; P be given. We denote by E n? resp: P the upper expectation (resp. the outer probability). De®nition 1.1. (i) For given sequence of mappings X n : Xn ! X (which are not necessarily Borel measurable), we say X n converges in distribution to the Borel probability measure L on X; dX if Z ÿ ÿ n n? lim E f X f xLdx n!1

X

for every bounded dX -continuous function f : X ! R. We denote this converPn gence by ``X n ) L in X''. (ii) For givenn sequence of mappings X n : Xn ! Y, where X Y, the conP vergence ``X n ) L in X'' ÿ is de®ned to mean that P nthere exist mappings X~ n : Xn ! X such that P n? X n 6 X~ n 0 and that X~ n ) L in X in the sense of (i). Pn

P n?

We denote by X n ÿ! C (resp. X n ÿ! C) the convergence in P n -probability (resp. P n? -probability) when the limit C is deterministic. We follow [22] for notations and de®nitions in the theory of semimartingales. We need the following de®nitions to state some metric entropy conditions. (a) Let S; q be a totally bounded pseudo-metric space. De®nition 1.2. Given e > 0 we de®ne the e-covering number N S; q; e as the smallest number of closed balls, with centers in S and radius e in the pseudometric q, which form a covering of S. (b) Let W be a family of real-valued functions de®ned on a measurable space E; E. ÿ l;k u;k De®nition 1.3. An E-measurable bracket for W is a family w ;w ; k 2 Kg of pairs of E-measurable functions such that: for every w 2 W there exists k 2 K such that wl;k w wu;k . We de®ne the size of the bracket by CardK. Further, in the situation (b), let . be a pseudo-metric de®ned on an appropriate subset of the space of E-measurable functions. De®nition 1.4. Given e > 0 we de®ne the e-bracketing ÿ l;k u;k number N b W; .; e as ; w ; k 2 K for W such the smallest size of E-measurable brackets w ÿ that . wl;k ; wu;k e for every k 2 K.

2. Central limit theorems Recall the notation S S W, where S 0; s or fsg. All results in this section are available to both cases. Throughout this section, we shall assume

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that there exists a pseudo-metric q on S which satis®es the following condition: M The space S; q is totally bounded and satis®es the metric entropy condition: Z 1 p log N S; q; e de < 1 : 0

Further, in the case of S 0; s, it holds that: (i) qt; /; s; / qt; w; s; / for every t; w; s; / 2 S; (ii) the function t , qt; /; s; / is continuous for every s; / 2 S; (iii) the function t , qt; w; t; / is continuous and non-decreasing for every w; / 2 W. Remark 1. In the case of S fsg we may ignore the latter part of the condition M. In the case of S 0; s, if the pseudo-metric spaces S; .S and W; .W ) are totally bounded and satisfy the metric entropy condition respectively, and if the function t , .S t; s is continuous for every s 2 S, then either of the pseudo-metric q on S de®ned by q q .2S .2W or q maxf.S ; .W g satis®es the condition M.

2.1. Semimartingales ÿ For every n 2 N, let Bn Xn ; Fn ; Fn ; P n be a ®ltered probability space. Let ÿ X n X n;w jw 2 W be an RW -valued semimartingale de®ned on Bn ; that is, every coordinate process X n;w is a real-valued semimartingale on Bn . For every a > 0, let us introduce the truncation function ha x x1fjxjag . For every w 2 W, we consider the canonical decomposition of X n;w with respect to ha ; that is, X ÿ DXsn;w ÿ ha DXsn;w ; X n;w;a s

X

n;w

ÿ X n;w;a X0n;w Bn;w;a M n;w;a ;

4

where Bn;w;a is the predictable process with ®nite variation and M n;w;a is the locally square-integrable martingale such that n;w;a DB a and DM n;w;a 2a (see 75±76pp. of [22]). The decomposition in Eq. (4) is unique up to a negstochastic processes ligible ÿ set, however, that the RW -valued notice ÿ n;w;a n;a n;w;a n;a jw 2 W and M M jw 2 W are not necessarily unique B B unless the set W is countable.

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Y. Nishiyama

Theorem 2.1. For every n 2 N, let X n be an RW -valued semimartingale such conditions A1 )± for some that X0n 0. Suppose the following ÿ (A6 ) are satis®ed ÿ n n;a X n;w ÿ X n;w;a jw 2 W into Bn;a Bn;w;a j w 2 W ÿ X decomposition of X ÿ and M n;a M n;w;a jw 2 W : A1 ) supt;w2S Xtn;w x < 1 8x 2 Xn 8n 2 N; n;w;a P n? A2 ) supt20;s supw2W Xt 8a > 0; ÿ! 0 ÿ n;w;a P n? A3 ) supw2W Var B ÿ! 0 8a > 0; s n;w n;/ P n w;/ A4 ) X ; X ÿ! Ct 8t 2 S 8w; / 2 W, t w;/

where Ct 's are real constants such that for every w; / 2 W the w;/ is continuous on S; function t , Ct A5 ) there exists a pseudo-metric q on S, satisfying the condition M, such that q w;w /;/ w;/ Cs ÿ 2Ct^s qt; w; s; / Ct 8t; w; s; / 2 S ;

A6 ) for every e; g > 0 there exists a constant K > 0 such that: for every b > 0 there exists a constant a 2 0; b such that 0 1 lim sup P n? @ n!1

sup

t2S; w;/2W p qt;w;t;/K a

jMtn;w;a ÿ Mtn;/;a j > eA g :

Then, it holds that:

ÿ (CLT) there exists a Borel probability measure G on `1 S; jj jj1 , concentrated on the set Uq S, such that its ®nite-dimensional projection Gt1 ;w1 ;...;td ;wd is centered Gaussian distribution with w ;w ÿ Pn covariance matrix Cti ^ti j j , and that X n Xtn;w jt; w 2 S ) G in `1 S. Remark 2. According to De®nition 1.1ÿ(ii), the condition (A1 ) can be slightly weakened into the following form: P n? X n 62 `1 S 0 8n 2 N. Remark 3. In the case of S fsg, we may ignore the latter part of (A4 ) which w;/ , as well as the latter part requires the continuity of each function t , Ct of M. This remark is available also to (B2 ) and (C2 ) below. The proof is given in Sect. 3.2. The condition A6 plays the same role as (3.2) in Theorem 3.1 of [13], and (ii) in Theorem 1 of [25]. It is not necessarily easy to check that condition, hence we will present more tractable conditions in two special cases below. 2.2. Weighted integer-valued random measures Let E; E be a Blackwell space. For every n 2 N, let ln be an integervalued random measure on R E, de®ned on a ®ltered probability

CLT for `1 -valued semimartingales

465

ÿ space Xn ; Fn ; Fn ; P n . Let mn be a ``good'' version of the predictable compensator of ln . See Sect. II.1 of [22] for the de®nitions. Here we assume that P n -a.s. 5 mn 0; s E < 1 ÿ n n;w Further, let a family W W jw 2 W of predictable functions on ~ n Xn R E be given. This means that every W n;w is a P ~ n -measurable X n n n n ~ ~ P E, and P denotes the predictable r-®eld function on X , where P on Xn R (see 16p. of [22]). We assume that there exists a predictable ~ n , which we call an envelope function of W n , such that function V n on X n;w ~n 8 w 2 W W x; t; x V n x; t; x 8x; t; x 2 X and that V n lns < 1 n 2

and

V n mns < 1

P n -a.s.

6

n

and that the process jV j m is locally integrable. It is clear that a sucient condition for Eq. (6) is En V n mns < 1. Now we de®ne the RW -valued locally square-integrable martingale n X X n;w jw 2 W by X n;w W n;w ln ÿ mn

8w 2 W :

7

Then the predictable quadratic covariation is given by X

n;w n;/ n;w n;/ n W W m ÿ W^sn;w W^sn;/ ; X ;X t t W^tn;w x

st

R

where E W n;w x; t; xmn x; ftg dx. ~ n such that Here, for given two predictable functions W n;j j 1; 2 on X n; j 2 j m is locally integrable, we de®ne each jW q 2 n;2 qn W n;1 ; Wt jW n;1 ÿ W n;2 j mnt : Then it is trivial that q hX n;1 ÿ X n;2 ; X n;1 ÿ X n;2 it qn W n;1 ; W n;2 t ; where X n; j W n; j ln ÿ mn . Theorem 2.2. In the situation stated above, consider the RW -valued local martingale X n X n;w jw 2 W de®ned by Eq. 7. Then, CLT holds under the following conditions B1 ±B5 : Pn

B1 jV n j2 1fV n >eg mns ÿ! 0 n;w

n;/

Pn

w;/ Ct

8 e > 0;

B2 hX ; X it ÿ! 8 t 2 S 8 w; / 2 W, w;/ where Ct 's are real constants such that for every w; / 2 W the w;/ is continuous on S; function t , Ct B3 the condition A5 in Theorem 2.1 is satis®ed; B4 there exists a constant L1 > 0 such that

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Y. Nishiyama

0 lim lim sup P n? @ sup b#0

n!1

t2S; w;/2W qt;w;t;/b

1 ÿ qn W n;w ; W n;/ t > L1 bA 0 ;

B5 there exists a constant L2 > 0 such that: for every n 2 N and e > 0 ~ n -measurable bracket for W n W n;w jw 2 W with there exists a P ®nite size Nb n; e, namely fW n;e;l;k ; W n;e;u;k ; 1 k Nb n; eg, such that ! ÿ qn W n;e;l;k ; W n;e;u;k s n? > L2 0 sup max lim lim sup P b#0 n!1 e 0
Z lim lim sup b#0

n!1

0

b

p log Nb n; e de 0 :

The proof is given in Sect. 3.3. The condition B5 is a generalization of the metric entropy condition with L2 -bracketing due to [28] (see also Proposition 1.1 of [6]). That condition may seem to be arti®cial at ®rst sight, but it is weak enough for applications. We can derive, for instance, the asymptotic behavior of the Nelson-Aalen's estimator for marked point processes under quite natural conditions (Theorem 4.3 below). That result is interesting by itself in the context of survival analysis. Now, let us brie¯y see that Ossiander's central limit theorem [28] for i.i.d. sequences is also deduced from Theorem 2.2, in order to illustrate how to apply our theorem to discrete-time stochastic processes. Let E; E; P be a probability space, and set n X ei=n dtP dx ; mn x; dt; dx i1

where ea denotes the Dirac measure at point a. For given family W of squareintegrable functions on E, we set wx W n;w x; t; x p n

8w2W :

Then the stochastic process X n de®ned by Eq. (7) coincides with the empirical process Eq. (1). Here assume that the family W has a square-integrable envelope function u and satis®es s Z Z 1 p jwx ÿ /xj2 P dx : log Nb W; .; e < 1 with .w; / 0

E

Then all of the conditions in Theorem 2.2 are ful®lled if we de®ne the pseudo-metric q on S 0; 1 W by s Z qt; w; s; / jt ÿ sj juzj2 P dz j.w; /j2 : E

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It is clear from the observation above that we can obtain the results for empirical processes with random weights in quite general situations, including dependent cases. But we do not pursue them here in concrete fashions.

2.3. Continuous local martingales For every n 2 N, let X n X n;w jw 2 W be an RW -valued continuous local martingale de®ned on a ®ltered probability space Xn ; Fn ; Fn ; P n . For given w; / 2 W we de®ne q cn w; /t hX n;w ÿ X n;/ ; X n;w ÿ X n;/ it : Theorem 2.3. For every n 2 N, let X n be an RW -valued continuous local martingale such that X0n 0. Then, (CLT) holds under the following conditions C1 ±C5 : C 1 the condition A1 in Theorem 2.1 is satis®ed;

Pn w;/ 8 t 2 S 8 w; / 2 W, C 2 X n;w ; X n;/ it ÿ! Ct w;/ where Ct 's are real constants such that for every w; / 2 W the w;/ function t , Ct is continuous on S; C 3 the condition A5 in Theorem 2:1 is satis®ed for a proper metric q de®ned on S; C 4 each process X n is separable with respect to the metric q in the following sense: there exist a countable subset Wn W and a negligible set N n Xn such that for every x 62 N n , t; w 2 S and e > 0 Xtn;w x 2 Xtn;/ x; / 2 Wn ; qt; w; t; / < e ; where the closure is taken in R; C 5 there exists a constant L > 0 such that 0 1 n c w; /t > LA 0 : lim lim sup P n @ sup b#0 n!1 qt; w; t; / t2S; w;/2Wn 0
Remark 4. The condition C3 can be slightly weakened into the following form: the condition A5 in Theorem 2.1 is satis®ed for a pseudo-metric q de®ned on S such that qt; w; t; / 0 implies w / [i.e., qt; ; t; is a proper metric on W for every t 2 S]. The proof is given in Sect. 3.4. The condition C5 is similar to B4 and B5 . But we require a proper metric q in C3 and the separability of stochastic processes in C4 instead of the brackets, because the latter one does not work well for the processes which do not have ®nite variation. An application of the result above is presented in Sect. 5.

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3. Proofs 3.1. Auxiliaries The following fact is the starting point of our results (see e.g. Theorem 10.2 of Pollard [31] for the proof ). Lemma 3.1. Let S; q be a totally bounded pseudo-metric space. For every n 2 N, let X n X n sjs 2 S be an `1 S-valued random element de®ned on a probability space Xn ; Fn ; P n . Suppose the following conditions i and ii: i

the ®nite-dimensional distributions converge, that is, for every d 2 N and every s1 ; . . . ; sd 2 S there exists a Borel probability measure Ls1 ;...;sd on Rd ; Rd such that Pn

X n s1 ; . . . ; X n sd ) Ls1 ;...;sd

in

Rd ;

ii for every e; g > 0 there exists a constant d > 0 such that ! lim sup P n? n!1

sup jX n s ÿ X n tj > e

qs;t
g :

Then, there exists a Borel probability measure L on `1 S; jj jj1 , concenits ®nite-dimensional projections are Ls1 ;...;sd trated on the set Uq S, such that Pn n appeared in (i), and that X ) L in `1 S. Here are some useful inequalities (see e.g. Sect. 4.13 of [27] for the proof ). Lemma 3.2. (i) If X is a real-valued local martingale such that X0 0 and that jDX j a for some a > 0, then it holds that for every t; C; e; k > 0 ! expka ÿ 1 ÿ ka P sup jXs j > e; h X ; X it C 2 exp ÿke C : a2 s20;t ii If X is a real-valued continuous local martingale such that X0 0, then it holds that for every t; C; e > 0 ! e2 : P sup jXs j > e; hX ; X it C 2 exp ÿ 2C s20;t We shall use the preceding lemma in the following forms, in which (a) is the Bernstein's inequality for continuous-time local martingales with bounded jumps. Corollary 3.3. Let X ; Y be real-valued local martingales such that X0 Y0 0 and that jDX j a; jDY j a for some a > 0. a

It holds that for every t; e; C > 0

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469

! P b

sup jXs j > e; hX ; X it C

s20;t

e2 2ae C

:

If 0 e Ca then it holds that for every t > 0 ! P

c

2 exp ÿ

sup jXs j > e; hX ; X it C

s20;t

e2 : 2 exp ÿ 4C

C If 0 e 2a then it holds that for every t; s > 0

ÿ

P jXt ÿ Ys j > e; hX ; X it hY ; Y is ÿ 2hX ; Y it^s

2 e C 2 exp ÿ : 4C

Proof. By the same calculation as Freedman [12], the inequality (a) is easily derived from (i) of Lemma 3.1. Next, the assertion (b) is immediate ÿfrom (a). In order to show (c) it is enough to apply (b) to the process Z Zu u2R , where Zu Xu^t ÿ Yu^s . (

3.2. Proof of Theorem 2.1 Let us begin with two lemmas, in which we use the notation cn;a t; w; s; / q hM n;w;a ; M n;w;a it hM n;/;a ; M n;/;a is ÿ2hM n;w;a ; M n;/;a it^s : Lemma 3.4. Assume the conditions A2 ±A5 , and ®x any ®nite subset Sf S. Then, it holds that for every a > 0 and d > maxt;w;s;/2Sf qt; w; s; / n n;a max c t; w; s; / > d 0 : lim P n!1

t;w;s;/2Sf

Proof. By Theorem VIII.3.6 and Lemma VIII.3.16 of [22], it holds that for every a > 0

n;w;a n;/;a P n w;/ ;M ÿ! Ct 8 t 2 S 8 w; / 2 W : M t Thus for every t; w; s; / 2 Sf q Pn w;w /;/ w;/ cn;a t; w; s; / ÿ! Ct Cs ÿ 2Ct^s qt; w; s; / : This fact yields the claim.

(

The next lemma plays the key role in our context. In the proof we shall follow the chaining argument which is used in those for Theorem 3.2 of [13] and Theorem 2 of [25]. See also Sect. VII.6 of [30].

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Y. Nishiyama

Lemma 3.5. Assume the conditions A2 ±A5 . Then, for every e; g; K > 0 there exist some constants d; b > 0 such that for every > 0 and a 2 0; b ! lim sup P n? n!1

sup

qt;w;s;/
jMtn;w;a ÿ Msn;/;a j > e 2

0

g lim sup P n? @ n!1

1 sup

t2S; w;/2W p qt;w;t;/K a

jMtn;w;a ÿ Mtn;/;a j > A :

Proof. Let e; g; K > 0 be given, and ®x p any J > 1. Set R K=2 and D 10 _ e=4J 2 R2 . We denote H x logN x=x, where N x N S; q; x. Here notice that Z xH x

x 0

Z H y dy

and

lim x#0

0

x

H y dy 0 :

Hence we can ®nd a constant x0 > 0 such that the following inequalities hold for any x 2 0; x0 : Z x e 8 8J H y dy ; 5 0 xH x

JR2 ; 2

x2 8 e2 g exp 2 jx=2j2 H x=22 ÿ ; 2 20000 x 3 1 e2 g : 4x exp 2 x2 H x2 ÿ 2 2 16D J x 3

9 10 11

p Then, we set ÿ p d g=6 ^ x0 and de®ne the constant b > 0 by R b R 125d2 =2e ^ d. For p every a 2 0; b, let us choose ka 2 N [ f0g p such that d=2 < 2ka R a d. For every i 0; 1; . . . ; ka , setting dai 2i R a, let us ®x a subset Sai S consists of the centers of closed balls which form a dai -covering of S, such that CardSai N dai . Then, we introduce the mappings kai : S ! Sai such that qt; w; kai t; w dai

8t; w 2 S :

Further we de®ne the mappings tia pS kai kaiÿ1 ka0

and

wai pW kai kaiÿ1 ka0 ;

where pS (resp. pW ) is the projection from S to S (resp. W ). Now, observe that for every t; w; s; / 2 S n;w;a M t ÿ Msn;/;a a b c d ; where each term in the right hand side is given by:

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471

a n;wa t;w;a (a) Mtn;w;a ÿ Mt 0 Msn;/;a ÿ Msn;w0 s;/;a ; n;wa t;w;a a n;wa0 t;w;a n;wa0 s;/;a ÿ Mta t;w (b) Mt 0 Msn;w0 s;/;a ÿ Mta s;/ ; 0

0

ka X n;waiÿ1 t;w;a n;wai t;w;a ÿ Mta t;w (c) Mta t;w

i

iÿ1

i1

ka X n;waiÿ1 s;/;a n;wai s;/;a ÿ Mta s;/ Mta s;/ ; i1

i

iÿ1

n;waka s;/;a n;waka t;w;a ÿ Mta s;/ (d) Mta t;w : ka

ka

So it holds that for every > 0 P

n?

sup

qt;w;s;/
! n;w n;/ Xt ÿ Xs > e 2 (I) (II) (III) (IV) ;

where each term in the right hand side is given by: ! n;wa0 t;w;a n;w;a sup Mt ÿ Mt > ;

(I) P

n?

(II) P

n

e n;wa0 t;w;a n;wa t;w;a sup Mt 0 ÿ Mta t;w > 0 5 t;w2S

(III) P

n

ka e X n;waiÿ1 t;w;a n;wai t;w;a sup ÿ Mta t;w Mta t;w > i iÿ1 5 t;w2S i1

t;w2S

(IV) P n

! ; !

e n;waka s;/;a n;waka t;w;a sup ÿ Mta s;/ Mta t;w > ka ka 5 qt;w;s;/
; ! :

Here notice that the term (II) vanishes in the case of S fsg. The following arguments about the terms (I), (III) and (IV) are available to both of the cases S 0; s and fsg. Estimation of (I). It follows from (i) in the condition M that qt; w; t; wa0 t; w qt; w; ka0 t; w qka0 t; w; t; wa0 t; w qt; w; ka0 t; w qka0 t; w; t; w p p 2da0 2R a K a :

Hence we obtain

0

1 (I) P n? @ sup Mtn;w;a ÿ Mtn;/;a > A : t2S; w;/2W p qt;w;t;/K a

472

Y. Nishiyama

ÿ Estimation of (III). For every i 1; 2; . . . ; ka we set eai 2 J dai H daiÿ1 . Then it holds that ka X i1

eai

8J

ka X da

iÿ1

i1

2

H

ÿ

daiÿ1

Z 8J

0

d

H x dx

e ; 5

where the last inequality follows from Eq. (8). Next it is immediate from Eq. (9) that 2 p ÿ p ÿ p aH R a J dai jJ dai j2 a a : e i 2 J di H R a 2a 2a 2iÿ2 JR n Here we de®ne the set Xn;a 1 2 Fs by 8 9 > > k < = a \ n;a a n;a X1 : max c t; w; s; / J d i >t;w2Saiÿ1 ; s;/2Sai > ; i1: qt;w;s;/
Then we obtain by using Corollary 3.3 (c) that P

n

ka e X n;waiÿ1 t;w;a n;wai t;w;a n;a sup ÿ Mta t;w Mta t;w > ; X1 i iÿ1 5 t;w2S i1

ka X i1

P

n

n;waiÿ1 t;w;a n;wai t;w;a n;a sup Mta t;w ÿ Mta t;w > eai ; X1

t;w2S

iÿ1

ka X ÿ jea j2 N daiÿ1 2 exp ÿ i a 2 4jJ di j i1 ka X i1

!

2daiÿ1 2d

!

!

i

g ; 3

where the last ÿ inequality follows from the de®nition of d. So we have (III) g3 P n Xn n Xn;a 1 . Estimation of (IV). Note that if qt; w; s; / < d then qtkaa t; w; waka t; w; tkaa s; /; waka s; / qt; w; s; /

qt; w; t0a t; w; wa0 t; w qs; /; t0a s; /; wa0 s; /

ka X i1

ka X i1

a qtiÿ1 t; w; waiÿ1 t; w; tia t; w; wai t; w a qtiÿ1 s; /; waiÿ1 s; /; tia s; /; wai s; /

< d 4daka ÿ 2da0 < 5d :

CLT for `1 -valued semimartingales

473

n So we de®ne the set Xn;a 28 2 Fs by 9 < = n;a Xn;a max c t; w; s; / 5d : 2 : t;w;s;/2Saka ; qt;w;s;/<5d

2

It is immediate from the de®nition of b that 5e j5dj 2a . Hence we obtain by using Corollary 3.3 (c) that ! e a a n;w t;w;a n;w s;/;a n;a ka ka Pn sup ÿ Mta s;/ Mta t;w > ; X2 ka ka 5 qt;w;s;/
ta0 t; w supfu 2 S; qu; wa0 t; w; t0a t; w; wa0 t; w da0 g :

Then it follows from (ii) in the condition M that

p qta0 t; w; wa0 t; w; ta0 t; w; wa0 t; w 2da0 < 2 JR a :

n So we de®ne the set Xn;a 3 2 Fs by (

Xn;a 3

sup c

t;w2S

n;a

ta0 t; w; wa0 t; w; ta0 t; w; wa0 t; w

p 2 JR a

) :

p 2 It is immediate from the de®nition of D that De j2 JRa aj . Hence we obtain by using Corollary 3.3(b) that for every t; w 2 S ! e n;wa0 t;w;a n;wa0 t;w;a n;a n sup ÿ Mta t;w > ; X3 P Ms a 0 10 s2 ta0 t;w;t0 t;w ! e n;wa0 t;w;a n;wa0 t;w;a n;a n sup ÿ Mta t;w > ; X3 P Ms a 0 D s2 ta0 t;w;t0 t;w ! je=Dj2 : 2 exp ÿ p 4j2 JR aj2

It is clear from (i) in the condition M that ta0 t; w t ta0 t; w, hence it follows from the above inequality that

474

Y. Nishiyama

P

e n;wa t;w;a n;wa0 t;w;a n;a sup Mt 0 ÿ Mta t;w > ; X3 0 5 t;w2S

n

P

n

!

e n;wa0 t;w;a n;wa t;w;a n;a sup Mt 0 ÿ Mta t;w > ; X3 0 10 t;w2S

!

! e n;wa0 t;w;a n;wa0 t;w;a n;a sup Mta t;w ÿ Mta t;w > ; X3 P 0 0 10 t;w2S p e2 2N R a 2 exp ÿ 2 16D J 2 R2 a p p e2 4R a exp H R a2 ÿ 16D2 J 2 R2 a p p 2 1 e2 g 2 4R a exp 2 R a H R a ÿ ; 16D2 J 2 R a 3 n

ÿ where the last inequality follows from Eq. (11). So (II) g3 P n Xn n Xn;a 3 . By Lemma 3.4 it holds that limn!1 P n Xn n Xn;a j 0 for j 1; 2; 3. So the assertion of the lemma follows from the estimates of (I), (II), (III) and (IV). ( Proof of Theorem 2.1. We shall check the conditions in Lemma 3.1. The convergence of ®nite-dimensional distributions follows from the usual semimartingale central limit theorem (see Theorem VIII.3.6 and Lemma VIII.3.16 of [22]) using A2 ±A4 . To show (ii) in Lemma 3.1, ®rst notice that for every t; w; s; / 2 S ( ) Mtn;w;a ÿ M n;/;a : jXtn;w ÿ X n;/ j 2 sup Xtn;w;a sup Bn;w;a t s

t;w2S

s

t;w2S

For given e; g > 0 choose K > 0 according to A6 . Next, choose d; b > 0 according to Lemma 3.5. Finally, if we choose a 2 0; b such that 0 1 n;w;a n;/;a M t ÿ Mt > eA g ; lim sup P n? @ sup t2S; w;/2W n!1 p qt;w;t;/K a then it follows from A2 and A3 that lim sup P

n?

n!1

sup

qt;w;s;/
lim sup P n? n!1

lim sup P n!1

n;w Xt ÿ X n;/ > 7e

!

s

>e sup Xtn;w;a > e; sup Bn;w;a t

t;w2S n?

t;w2S

sup

qt;w;s;/
n;w;a M t ÿ M n;/;a > 3e s

!

! 2g :

CLT for `1 -valued semimartingales

475

This completes the proof.

(

3.3. Proof of Theorem 2.2 Throughout this subsection, we will use the following notations: for every n; p; r 2 N and a 1 v u r Y u n Nb n; 2ÿj ; fr tlog 2r j1

enp

1 X rp

ga sup

2ÿr fnr

;

1 r X Y

n2N r1

ÿ

Nb n; 2

ÿj

!

j1

ÿ exp ÿ ajfnr j2 :

Here Nb ; denotes the integer which appeared in the condition B5 . To prove Theorem 2.2 we shall check the conditions in Theorem 2.1. The following three lemmas concern the condition A6 . The idea to show the ®rst one is taken from [4]. Lemma 3.6. Under the condition B5 it holds that: (i ) lima!1 ga 0 ; (ii ) limp!1 lim supn!1 enp 0

:

Proof. Observe that 1 r Y X r1

ÿ

Nb n; 2

ÿj

!

j1

1 X

2

ÿar

r1

1 X

r Y

ÿ exp ÿ ajfnr j2 ÿ

Nb n; 2

ÿj

!1ÿa

j1

2ÿar whenever a 1

r1 ÿa

2 ; 1 ÿ 2ÿa

which converges to 0 as a ! 1. So we obtain (i). To prove (ii) we set nnj Since fnr

Pr

j1

p log 2Nb n; 2ÿj :

nnj we have for every integer p 2

476

Y. Nishiyama 1 X rp

2ÿr fnr

1 X

2ÿr

r X

rp

j1

1 X

1 X

j1

nnj

2ÿp1

nnj 2ÿr

rj_p

p=2 X j1

nnj

2ÿp1p=2

p=2 X j1

1 X jp=21

2ÿj1 nnj

2ÿj nnj 2

1 X jp=21

2ÿj nnj :

The condition B5 implies lim sup n!1

1 X j1

2ÿj nnj < 1 and lim lim sup p!1

n!1

1 X jp=21

2ÿj nnj 0 ;

hence we obtain (ii).

(

By virtue of (ii) in the above lemma, we have in particular that: there exist p0 ; n0 2 N such that p p0 ; n n0 ) 2ÿp fnp

1 : 2

12

Based on this fact, let us state Lemma 3.7 which plays the key role in our context. The bracketing argument in the proof is basically due to [28]. It is shown by [6] that certain martingale inequality, which is Corollary 3.3 (a) above, works well instead of the Bernstein's inequality in the i.i.d. case. See van de Geer [32] for a generalization of Corollary 3.3 (a) and its application. Lemma 3.7. Fix any a 1 and n; p; q 2 N such that p0 p < q and n n0 , where p0 ; n0 are the integers appeared in Eq. (12 ). De®ne the local martingale M n;w;p , the set Xna;p;q 2 Fns and the stopping time snq in the following way: M n;w;p W n;w 1fV n 2ÿ2p g ln ÿ mn ; ) ÿ ÿj ÿj qn W n;2 ;l;k ; W n;2 ;u;k s p n Xa;p;q max max a ; pjq 1kNb n;2ÿj 2ÿj n o snq inf t 2 R ; mn 0; t E 4jfnq1 j2 ÿ 1 ^ s : (

Then, it holds that for every > 0

13

14

CLT for `1 -valued semimartingales

0 P n? @

sup

t2S; w;/2W qt;w;t;/2ÿp

477

1 n;w;p n;/;p ÿ Mt Mt > 20aenp A

P n Xn n Xna;p;q P n snq < s 2ga=4 2ga=10 2 2p ÿ2p1 ÿp 2 exp 2 2 log Nb n; 2 ÿ 4 18a 0 1 p P n? @ sup qn W n;w ; W n;/ t > 2ÿp aA : t2S; w;/2W qt;w;t;/2ÿp

Before the proof of above lemma, let us show that: Lemma 3.8. Under the conditions B4 and B5 , it holds for every e > 0 0 1 n;w;p n;/;p lim lim sup P n? @ sup Mt ÿ Mt > eA 0 ; p!1 n!1

t2S; w;/2W qt;w;t;/2ÿp

where M n;w;p is de®ned by Eq. (13 ). Proof. Fix any ; g > 0. By Lemma 3.6 p(i) we can choose a large constant a such that 2ga=4 2ga=10 g and that a maxf1; L1 ; L2 g, where L1 and L2 are the constants in the conditions B4 and B5 . On the other hand, since p fnq log 2q , it holds for the stopping times snq de®ned by Eq. (14) that for every n 2 N P n snq < s P n mn 0; s E 4jfnq1 j2 ÿ 1 P n mn 0; s E 4q 1 log 2 ÿ 1 ; and the right hand side converges to zero as q ! 1 because of Eq. (5). Further, observe that p lim lim sup 2ÿp log Nb n; 2ÿp 0 ; p!1

n!1

and thus

lim lim sup exp 22p 2ÿ2p1 log Nb n; 2ÿp ÿ

p!1

n!1

2 4 18a

0 :

Hence, it follows from the estimate in Lemma 3.7 that 0 1 n;w;p n;/;p ÿ Mt lim sup lim sup P n? @ sup Mt > 20aenp A p!1

n!1

t2S; w;/2W qt;w;t;/2ÿp

lim sup lim sup lim sup P n Xn n Xna;p;q g g : p!1

n!1

q!1

478

Y. Nishiyama

This fact and Lemma 3.6 (ii) yield the assertion.

(

Proof of Lemma 3.7. For every n; j 2 N, let us introduce a mapping k; n; j : W ! f1; 2; . . . ; Nb n; 2ÿj g such that W n;2

ÿj

;l;kw;n;j

ÿj

W n;w W n;2

;u;kw;n;j

:

For every w 2 W and every integer r such that p r q, we de®ne the n;w;r ~ n by on X predictable functions W n;w;r and W " # r _ n;w;r n n;2ÿj ;l;kw;n;j W ÿV _ W 1fV n 2ÿ2p g jp

and

" W

n;w;r

n

V ^

r ^ jp

# W

n;2ÿj ;u;kw;n;j

1fV n 2ÿ2p g :

Here notice that if r1 r2 then W n;w;r1 W n;w;r2 W n;w 1fV n 2ÿ2p g W

n;w;r2

W

n;w;r1

:

15

~ n given by Next we introduce the predictable subsets of X n o n;w;r ÿ W n;w;r > 2r1 fnr1 ÿ1 : Anr w W Now, for every w 2 W we consider the disjoint partition fBnr w; p r qg ~ n de®ned by of predictable subsets of X 8 n for r p , > < Ap w; S rÿ1 n n n Br w Ar w n jp Aj w; for p 1 r q ÿ 1 , > :X ~ n n Sqÿ1 Bn w; for r q . jp j We deal with three types of local martingales given as follows: M n;w;p W n;w 1fV n 2ÿ2p g ln ÿ mn q X W n;w 1fV n 2ÿ2p g 1Bnr w ln ÿ mn ; rp

Ln;w;p;q

q X rp

W n;w;r 1Bnr w ln ÿ mn ;

Ln;w;p W n;w;p ln ÿ mn q X W n;w;p 1Bnr w ln ÿ mn : rp

Then it holds that

CLT for `1 -valued semimartingales

0 P n? @ P

sup

t2S;w;/2W qt;w;t;/2ÿp

479

1 n;w;p n;/;p ÿ Mt M t > 20aenp ; Xna;p;q A

n;w;p sup Mt ÿ Ltn;w;p;q > 9aenp ; Xna;p;q

n?

t;w2S

P

n;w;p sup Ltn;w;p;q ÿ Lt > aenp ; Xna;p;q

n?

t;w2S

0 P n? @

sup

t2S; w;/2W qt;w;t;/2ÿp

! !

1 n;w;p n;/;p ÿ Lt Lt > ; Xna;p;q A

I II III : Hereafter we shall estimate (I), (II) and (III). Estimation of (I). Observe that n;w;p M ÿ Ln;w;p;q

q X ÿ rp

W n;w 1fV n 2ÿ2p g ÿ W n;w;p;r 1Bnr w ln

q X ÿ

rp q X

W n;w 1fV n 2ÿ2p g ÿ W n;w;r 1Bnr w mn

W

n;w;r

rp

q X rp

q X

W

ÿ W n;w;r 1Bnr w ln

n;w;r

ÿ W n;w;r 1Bnr w mn

U n;w;r ln ÿ mn 2

q X

rp

U n;w;r mn ;

16

rp

n;w;r ÿ W n;w;r 1Bnr w . Let us consider the last term in the where U n;w;r W right hand side of Eq. (16) at ®rst. For p r q ÿ 1, it is clear from Bnr w Anr w that jU n;w;r j2 2r1 fnr1 ÿ1 U n;w;r , hence we have ( ) qÿ1 qÿ1 X X n;w;r n ÿr1 n U ms > 4a 2 fr1 sup w2W rp

(

(

rp

n;w;r

U mn max sup ÿr1 n s > a prqÿ1 w2W 2 fr1

)

jU n;w;r j2 mns max sup >a prqÿ1 w2W 2ÿ2r

) Xn n Xna;p;q

:

480

Y. Nishiyama

As for r q, since mn 0; snq E 4jfnq1 j2 , it follows from the Schwarz's inequality that ( ) sup U n;w;q mnsnq > 4a 2ÿq1 fnq1

w2W

(

) sup jU

(

n;w;q 2

j

w2W

sup

\

snq

0; snq

>a

(

o

n

s sup

2

q X

w2W rp

(

E > j4a

2ÿq1 fnq1 j2

)

2ÿ2q

w2W

n

m

jU n;w;q j2 mnsnq

From these facts we get Xna;p;q

mnsnq

sup 2

Xn n Xna;p;q

U

n;w;r

q X

t;w2S

U

mns

n;w;r

4a

recall a 1 :

q X rp

rp

mnt

) 2ÿr1 fnr1 )

8aenp

;

which implies that q X n;w;r U sup ln ÿ mn t > aenp ; Xna;p;q

(I) P n?

! 17

t;w2S rp

P n snq < s : Here, for every p r q, it holds that jU n;w;r j2 mns 2ÿ2r a and that

on the set

Xna;p;q

ÿ ÿ1 0 U n;w;r 2r fnr

n ÿ[asn for r c p, use Eq. (12); as for p 1 r q, notice that Br w Arÿ1 w and use Eq. (15)]. So Corollary 3.3 (a) yields that ! P n sup U n;w;r ln ÿ mn > 2ÿr fn a; Xn t

t;w2S

2 exp ÿ

r

a;p;q

!

j2ÿr fnr aj2

22r fnr ÿ1 2ÿr fnr a 2ÿ2r a

ajfn j2 2 exp ÿ r 4

! :

Now, it is clear that r Y ÿ Nb n; 2ÿj ; Card U n;w;r ; w 2 W jp

hence the ®rst term in the right hand side of Eq. (17) is not larger than

CLT for `1 -valued semimartingales

P

481

q q X X U n;w;r ln ÿ mn > sup 2ÿr fnr a; Xna;p;q t

n

t;w2S rp

q X

r Y

rp

jp

ÿ

Nb n; 2

ÿj

rp

!

ajfn j2 2 exp ÿ r 4

!

! 2ga=4 :

Consequently we obtain (I) 2ga=4 P n snq < s. Estimation of (II). To begin with, observe that Ln;w;p;q ÿ Ln;w;p

q X ÿ rp1

W n;w;r ÿ W n;w;p 1Bnr w ln ÿ mn

qÿ1 X rÿ1 ÿ X rp1 up

qÿ1 X ÿ up

qÿ1 X

W n;w;u1 ÿ W n;w;u 1Bnr w ln ÿ mn

W n;w;u1 ÿ W n;w;u 1Bnq w ln ÿ mn

Z n;w;u ln ÿ mn ;

up

ÿ S where Z n;w;u W n;w;u1 ÿ W n;w;u 1Cun w with Cun w qru1 Bnr w. Here, for every p u q ÿ 1, it follows from 0 W n;w;p;u1 ÿ W n;w;p;u W

n;w;p;u

ÿ W n;w;p;u

that jZ n;w;u j2 mns 2ÿ2u a and that

on the set

Xna;p;q

ÿ ÿ1 0 Z n;w;u 2u1 fnu1

[notice also Cun w Anu wc to get the latter fact]. So Corollary 3.3 (a) yields that n;w;u n n ÿu1 n n l ÿ m t > 2 fu1 a; Xa;p;q P sup Z n

t2S

2 exp ÿ

j2ÿu1 fnu1 aj2

!

22u1 fnu1 ÿ1 2ÿu1 fnu1 a 2ÿ2u a ! ajfnu1 j2 2 exp ÿ : 10

~ n n Su Bn w, it is clear that Since Cun w X rp r

482

Y. Nishiyama u1 Y ÿ Card Z n;w;u ; w 2 W Nb n; 2ÿj ; jp

hence we obtain (II) P n?

qÿ1 qÿ1 X X n;w;u Z sup ln ÿ mn t > a 2ÿu1 fnu1 ; Xna;p;q

t;w2S up

qÿ1 X

u1 Y

up

jp

ÿ Nb n; 2

! ÿj

!

up

2 exp ÿ

ajfnu1 j2 10

!

2ga=10 :

Estimation of III. Here we consider the case of S 0; s only. The argument for the case of S fsg is easier. Notice that D

E Ln;w;p ÿ Ln;/;p ; Ln;w;p ÿ Ln;/;p t D E n;w;p n;w;p n;w;p 3 L ÿM ;L ÿ M n;w;p t D E n;w;p n;/;p n;w;p n;/;p 3 M ÿM ;M ÿM D E t n;/;p n;/;p n;/;p n;/;p 3 M ÿL ;M ÿL t ÿ n ÿ n;w n;/ 2 n n;w;p n;w;p 2 3 q W ;W 3 q W ;W t t ÿ n;/;p 2 3 qn W n;/;p ; W : t

For every pair w; / 2 W, recalling that the function t , qt; w; t; / is continuous, we set rp w; / supft 2 S; qt; w; t; / 2ÿp g : Then it follows from Corollary 3.3 (a) that for every > 0 ! n;w;p n;/;p n n? (III) P sup sup Lt ÿ Lt > ; Xa;p;q w;/2W t20;rp w;/

Nb n; 2ÿp 2 2 exp ÿ P n?

2 22 2ÿ2p 9a 2ÿ2p ! ÿ 2 n n;w n;/ ÿ2p sup q W ; W >a2 : rp w;/

w;/2W

These estimates of (I), (II) and (III) complete the proof.

(

Proof of Theorem 2.2. First notice that the condition B1 implies Pn

V n 1fV n >eg mns ÿ! 0

8e > 0 :

18

CLT for `1 -valued semimartingales

483

Hereafter we shall check the conditions of Theorem 2.1. It is clear from Eq. (6) that the condition A1 is satis®ed (recall also Remark 2). Next, the canonical decomposition of X n;w W n;w ln ÿ mn is given as follows: X0n;w 0 ; X n;w;a W n;w 1fjW n;w j>ag ln ; Bn;w;a ÿW n;w 1fjW n;w j>ag mn ; M n;w;a W n;w 1fjW n;w jag ln ÿ mn : Now observe that for every e > 0 ! n;w;a n? Xt > e P n? sup P t;w20;sW

sup

t;w20;sW

! n;w n W 1fjW n;w j>ag l > e t

ÿ P n V n 1fV n >ag lns > e ÿ e P n V n 1fV n >ag mns > e2 ;

where the last inequality follows from the Lenglart's inequality (e.g. Lemma I.3.30 of [22]). Hence Eq. (18) implies the conditions A2 and A3 . Also, under B1 , the condition A4 is deduced from B2 . Further, by virtue of Lemma 3.8, it is sucient for A6 to show that for every e; g > 0 and every p2N ! n;w;2ÿ2p n;w;p n? sup Mt ÿ Mt lim sup P 19 >e g : n!1

t;w2S

To do it, notice that n;w;2ÿ2p n;w;p ÿ Mt Mt n;w W 1fjW n;w j2ÿ2p g ln ÿ mn t ÿW n;w 1fV n 2ÿ2p g ln ÿ mn t W n;w 1fjW n;w j2ÿ2p
V n 1fV n >2ÿ2p g lnt V n 1fV n >2ÿ2p g mnt : So the Lenglart's inequality and Eq. (18) yield Eq. (19). The proof is ®nished. (

3.4. Proof of Theorem 2.3. Let us denote by Ns e N W; qs ; e the e-covering number of W with respect to the metric qs de®ned by qs w; / qs; w; s; /. Notice that Ns e N S; q; e. We introduce the following notations, which are similar to those in Sect. 3.3: for every p; r 2 N and a 1

484

Y. Nishiyama

p fr log 2r Ns 2ÿr ; 1 X 2ÿr fr ; ep rp

ga

1 X r1

Ns 2ÿr exp ÿajfr j2 :

Then the following facts are derived from the same argument as for Lemma 3.6 (in fact, the proofs are easier): under the condition C3 , lim ga 0

a!1

and

lim ep 0 :

20

p!1

In order to prove Theorem 2.3. we shall check the conditions in Theorem 2.1. The direct proof is also possible, but it is essentially same as the one presented here. The chaining argument below is taken from Theorem 11.6 of [24]. Proof of Theorem 2.3. By virtue of Theorem 2.1, it is enough to show that 0 lim lim sup P n @

p!1

n!1

sup

t2S; w;/2Wn 0
1 n;w Xt ÿ Xtn;/ > eA 0

8e > 0 :

21

To do it, ®x any n 2 N for a while. Let fWnm gm2N be a sequence of ®nite subsets of Wn such that Wnm " Wn as m ! 1. For every m; p 2 N let us denote by qn; m; p the smallest integer such that qn; m; p > p and that each of closed balls with centers in Wnm and radius 2 2ÿqn;m;p in the proper metric qs contains exactly one point in Wnm . Then we have CardWnm Ns 2ÿqn;m;p . of Wnm , p r < qn; m; p, such that: Next we choose some subsets Wn;m;p r i CardWn;m;p Ns 2ÿr ; r : Wnm ! Wn;m;p such that qs w; krn;m;p w ii there exists a mapping kn;m;p r r n ÿr 2 2 for every w 2 Wm . n;m;p n n Set Wn;m;p qn;m;p Wm , and denote by kqn;m;p the identical mapping on Wm . Now, n;m;p n n;m;p : Wm ! Wr , p r qn; m; p, by we de®ne the mappings wr n;m;p kn;m;p kn;m;p wn;m;p r r r1 kqn;m;p :

Further, for given a > 0 let us de®ne the set Xna;p 2 Fns by Xna;p Since

8 < :

sup

t2S; w;/2Wn 0
9 p= cn w; /t a : ; qt; w; t; / ÿp

CLT for `1 -valued semimartingales

485

qn;m;p X n;wn;m;p w n;wn;m;p w n;w n;/ ÿ Xt rÿ1 Xt ÿ Xt Xt r rp1

qn;m;p X rp1

n;wn;m;p / n;wn;m;p / ÿ Xt rÿ1 Xt r

n;wn;m;p / n;wn;m;p w ÿ Xt p Xt p ; it holds that for every > 0 0 B P n@

sup

t2S; w;/2Wnm 0
1 n;w C n;/ Xt ÿ Xt > 2aep1 A

P n Xn n Xna;p (I) (II) ; where the terms (I) and (II) in the right hand side are given by: (I) P

n

qn;m;p X

sup

t2S; w2Wnm rp1

0 B (II) P n @

sup

t2S; w;/2Wnm 0
n;wn;m;p w n;wn;m;p w ÿ Xt rÿ1 > aep1 ; Xna;p Xt r

22 ! ;

1 w n;wn;m;p / n;wn;m;p C ÿ Xt p Xt p > ; Xna;p A :

Hereafter we shall estimate (I) and (II). Estimation of (I). It follows from Lemma 3.2 (ii) that (I)

qn;m;p X

X

rp1 w2Wn;m;p r

n;kn;m;p w P n sup Xtn;w ÿ Xt rÿ1 > 2ÿr fr a; Xna;p t2S

! j2ÿr fr aj2 Ns 2 2 exp ÿ 2 2ÿ2r4 a rp1 ! qn;m;p X ajfr j2 ÿr Ns 2 2 exp ÿ 2ga=32 : 32 rp1 qn;m;p X

ÿr

Estimation of (II). Here we consider the case of S 0; s only. The argument for the case of S fsg is easier. Recall (iii) in the condition M: the functions t , qt; w; t; / are assumed to be continuous and nondecreasing. For every t 2 S; w; / 2 Wnm such that qt; w; t; / 2ÿp , we have X ÿÿ ÿ qn;m;p ÿ n;m;p ÿÿ w ; t; wpn;m;p / q t; wn;m;p w ; t; wrÿ1 w q t; wn;m;p p r rp1

486

Y. Nishiyama

qn;m;p X rp1

ÿÿ ÿ q t; wrn;m;p / ; t; wn;m;p qt; w; t; / rÿ1 /

9 2ÿp : So, for every pair w; / 2 Wpn;m;p we set w; / supft 2 S; qt; w; t; / 9 2ÿp g : rn;m;p p Then it follows from Lemma 3.2 (ii) that ! X n;w n;/ n n (II) P sup Xt ÿ Xt > ; Xa;p w;/2Wn;m;p p

t20;rn;m;p w;/ p

2 Ns 2 2 exp ÿ 2 81a 2ÿ2p ÿp 2

:

From these estimates of (I) and (II), by letting m ! 1 in the left hand side of Eq. (22) we obtain 0 P n@

sup

t2S; w;/2Wn 0
1 n;w n;/ Xt ÿ Xt > 2aep1 A

P n Xn n Xna;p 2ga=32 2 2p ÿ2p1 ÿp : 2 exp 2 2 log Ns 2 ÿ 162a Therefore we can deduce Eq. (21) by using Eq. (20): ®rst choose a large ( constant a, and then, take limp!1 lim supn!1 .

4. Nonparametric estimation for marked point processes In this section we concentrate on the case of S fsg for simplicity. Let E; E be a Blackwell space on which a r-®nite measure k is de®ned. For every n 2 N, let ln be an integer-valued random measure on R E, de®ned on a ®ltered probability space Xn ; Fn ; Fn ; P n . Notice that ln can be identi®ed with an E-marked point process fTin ; Zin ; i 2 Ng through the equality X eTin x;Zin x dt; dz ; ln x; dt; dz i

T1n

T2n

< < a.s. and each Zin is an E-valued random variable. where 0 < We assume that the predictable compensator mn of ln is given by mn x; dt; dz at; zY n x; t; zdtkdz ;

CLT for `1 -valued semimartingales

487

where at; z is a non-negative real-valued measurable function on R E, and Y n x; t; z is a non-negative real-valued predictable function on Xn R E. Further, for some ®xed constant s > 0, we also assume Z at; zdtkdz < 1 0;sE

and sup

t;z20;sE

Y n x; t; z < 1

8x 2 Xn :

We will consider the estimation problems for unknown function a, based on the information of Fns (hence, in addition to ln , the predictable function Y n is also assumed to be observable on 0; s E). Here we make the following condition, which is a natural generalization of (8.4.1) in [3]. Condition 4.1. There exist a measurable function y yt; z on 0; s E, which is bounded and bounded away from zero, and a sequence fan g of positive constants such that an " 1 and that sup

t;z20;sE

ÿ2 n P n? a Y ; t; z ÿ yt; z ÿ !0 : n

Based on the function y appeared above, we set H L2 0; s E; a=y and equip it with the inner product Z at; z dtkdz : h1 ; h2 H h1 t; zh2 t; z yt; z 0;sE p Let us de®ne the pseudo-metric q on H by qh1 ; h2 h1 ÿ h2 ; h1 ÿ h2 H . Now we ®x a subset W H which satis®es the following condition. Condition 4.2. The set W H has the envelope u 2 H, that is jwt; zj ut; z 8t; z 2 0; s E 8w 2 W : Further W; q satis®es the metric entropy condition with bracketing: Z 1 p log Nb W; q; e de < 1 : 0

1

We equip ` W with the sup-norm jj jj1 . We can consider A Awjw 2 W and F F wjw 2 W, which are given by Eq. (2) and Eq. (3) respectively, as `1 W-valued unknown parameters. First, in order to estimate the (weighted) cumulative hazard function A Awjw 2 W, we introduce the generalized Nelson-Aalen's estimator A^n A^n wjw 2 W de®ned by Z n ^ wt; zY nÿ x; t; zln x; dt; dz A w 0;sE

wY nÿ lns ;

488

Y. Nishiyama

where Y nÿ x; t; z

1 Y n x;t;z

if Y n x; t; z > 0 ; if Y n x; t; z 0 :

0

Theorem 4.3. Under Condition 4.1 and 4.2, it holds that Pn an A^n ÿ A ) G

in

`1 W ;

where the Borel probability measure G on `1 W; jj jj1 is concentrated on the set Uq W, and its ®nite-dimensional projection Gw1 ;...;wd is the centered Gaussian distribution with covariance matrix R fRij g given by Rij wi ; wj H . Proof. We shall apply Theorem 2.2 in the following way: W n;w an wY nÿ n

V an uY

nÿ

8w 2 W ; :

The conditions B1 and B2 are straight from jV n j2 1fV n >eg mns Z 2 an jut; zj2 Y nÿ t; z1fjan ut;zY nÿ t;zj>eg at; z dtkdz 0;sE

and W

n;w

W

n;/

mns

a2n

Z 0;sE

wt; z/t; zY nÿ t; zat; z dtkdz ;

respectively. Next, B3 follows from Condition 4.2. Further, under Condition 4.1, there exists a constant L > 0 such that if we set ( XnL

x;

sup

a2n Y nÿ x; t; z

t;z20;sE

yt; zÿ1

) L

then limn!1 P n? Xn n XnL 0. Since Z n n;w n;/ 2 q W ; W a2 jwt; z ÿ /t; zj2 Y nÿ t; zat; zdtkdz n s Z L

0;sE

0;sE

jwt; z ÿ /t; zj2

at; z dtkdz on the set XnL ; yt; z

we obtain B4 . In order to check B5 , for every n 2 N and e > 0 we in~ n -measurable bracket fW n;e;l;k ; W n;e;l;k ; 1 k Nb W; q; eg troduce the P n for W given by W n;e;l;k an we;l;k Y nÿ

and

W n;e;u;k an we;u;k Y nÿ ;

CLT for `1 -valued semimartingales

489

where fwe;l;k ; we;u;k ; 1 k Nb W; q; eg is the B0; s E-measurable bracket for W corresponding to Condition 4.2. The same argument as for ( B4 yields B5 . Secondly, in order to estimate the (weighted) distribution function F F wjw 2 W given by Eq. (3), we introduce the estimator F^n F^n wjw 2 W de®ned by ÿ F^n w wY nÿ Kÿn lns ; Q where Ktn st 1 ÿ DY nÿ lns . Corollary 4.4. Under Condition 4.1 and 4.2, it holds that Pn an F^n ÿ F ) G

in

`1 W ;

where the Borel probability measure G on `1 W; jj jj1 is concentrated on the set Uq W, and its ®nite-dimensional projection Gw1 ;...;wd is the centered Gaussian distribution with covariance matrix R fRij g given by ÿ R wi t; zwj t; zat; z exp ÿ 2 0;tE as; xdskdx

Z Rij

yt; z

0;sE

dtkdz :

Proof. It is well known that ! Z n n P sup Kt ÿ exp ÿ as; xdskdx ÿ! 0 t20;s 0;tE (see e.g. Theorem IV.3.1 of [3]). Hence we obtain the assertion by the same argument as for Theorem 4.3. ( Finally, let us discuss the asymptotic eciency of proposed estimators. According to Sect. VIII.3.1 of [3], we shall check the local asymptotic normality of the sequence of statistical experiments, and the dierentiability of unknown parameters. See [7], Ibragimov and Khas'minskii [20] and van der Vaart [33] for more details about the asymptotic eciency theory in in®nitedimensional statistical models. [Local Asymptotic Normality] Let us ®x a convex cone C H such that for every h 2 C there exists a constant l 2 R such that h l. Let Pn fPhn ; h 2 Cg be a family of probability measures on the ®ltered space Xn ; Fn ; Fn such that: the predictable compensator mn;h of ln with respect to Phn is given by mn;h x; dt; dz anh t; zY n x; t; zdtkdz ; where anh af1 ahn y g. Here we make the following condition.

490

Y. Nishiyama

T Condition 4.5. The ®ltration Fn Fnt t2R satis®es Fnt s>t Hns with Hns Fn0 _ rln 0; r U : r s; U 2 E. Also, for every h 2 C it holds that Phn P0n on Fn0 and that Phn P0n on Fns . Under the preceding condition, the log-likelihood ratio is given by dP nh jFns h h n lns ÿ mn;0 K h log n n log 1 dP 0 jFs an y an y s

23

(see e.g. Theorem III.5.43 of [22]). Hence, it follows from the usual semimartingale central limit theorem that, under Condition 4.1. and 4.5, the sequence of statistical experiments Xn ; Fns ; Pn fPhn ; h 2 Cg is locally asymptotic normal; that is, for every d 2 N and h1 ; . . . ; hd 2 C P0n ÿ Kn h1 ; . . . ; Kn hd ) N ÿ12 diagR; R

in

Rd

where Rij hi ; hj H . [Dierentiability of Parameters] We prepare some notations. We set B; jj jjB `1 W; jj jj1 , and denote by B the dual space of B. For given T : H ! B and g 2 B , we de®ne Tg by the unique element in H such that h; Tg H g T h for every h 2 H. We denote by pw , which belongs to B , the projection to w. The parameter A. Let us de®ne the mapping An : H ! B by n A h An hwjw 2 W where Z n wt; zanh t; zdtkdz : A hw 0;sE

Then, it is trivial that An is dierentiable with rate an and its derivative A0 : H ! B is given by A0 h A0 hwjw 2 W where Z at; z A0 hw dtkdz : wt; zht; z yt; z 0;sE Further, we have A0pw w for every w 2 W. The parameter F . Let us de®ne the mapping F n : H ! B by n F h F n hwjw 2 W where ! Z Z n n n wt; zah t; z exp ÿ ah s; xdskdx dtkdz : F hw 0;sE

0;tE

Then, it is trivial that F n is dierentiable with rate an and its derivative F 0 : H ! B is given by F 0 h F 0 hwjw 2 W where ! Z Z at; z 0 exp ÿ F hw wt; zht; z as; xdskdx dtkdz : yt; z 0;sE 0;tE R Further, we have Fp0 w Fp0 w t; z wt; z expÿ 0;tE as; xdskdx for every w 2 W. From the discussion above, we can conclude:

CLT for `1 -valued semimartingales

491

Corollary 4.6. Under Condition 4.1, 4.2 and 4.5, if the set W is included by the closed linear span of C, then the estimators A^n for A and F^n for F are respectively asymptotically ecient in the sense of convolution theorem. 5. Log-likelihood ratio random ®elds of continuous semimartingales For every n 2 N, let Xn ; Fn ; Fn be a ®ltered space, on which a real-valued continuous adapted process X n is de®ned. Let C be a family of locally bounded measurable functions on R such that 0 0t 2 C. Let fan g be a sequence of positive constants such that an " 1. Let Pn fPhn ; h 2 Cg be a family of probability measures on the ®ltered space Xn ; Fn ; Fn such that: under Phn , the process X n is a semimartingale with the local characteristics Bn;h ; C n;h ; 0 given by Z t anh sZsn Ysn ds with anh t at aÿ1 Bn;h t n ht ; 0 Z t Ctn;h Ysn ds ; 0

where Y n and Z n are predictable processes. In other words, under Phn , the process X n has the semimartingale decomposition dX nt anh tZtn Ytn dt dM n;h t

Rt where Mtn;h is a continuous local martingale with hM n;h ; M n;h it 0 Ysn ds. It is well known that, under some mild conditions, the log-likelihood ratio process t , Kn ht is given by dP nh jFnt dP n0 jFnt Z 2 ÿ 1 t ÿ1 n ÿ an hsZsn Ysn ds aÿ1 Mtn;0 n hZ 2 0

Kn ht log

24

(see e.g. Theorem III.5.34 of [22]). Here we make the following condition. Condition 5.1. There exists an integrable function g gt on 0; s, which is bounded away from zero, such that ÿ Pn 0 n 2 n Yt ÿ gt ÿ! 0 : sup aÿ1 n Zt

t20;s

2 Using the function g appeared above, we R s set H L 0; s; gtdt and equip h1 th2 tgtdt. Let it with the inner product h1 ; h2 H p 0 us de®ne the pseudo-metric . on H by .h1 ; h2 h1 ÿ h2 ; h1 ÿ h2 H . Now we ®x a subset W C which satis®es the following condition.

Condition 5.2. The set W C has the envelope u 2 H, that is

492

Y. Nishiyama

jhtj ut

8t 2 0; s

8h 2 W :

Also . is reduced to the proper metric on W. Further W; . satis®es the metric entropy condition: Z 1 p log N W; .; e de < 1 : 0

We de®ne the pseudo-metric q on S 0; s W by s Z qt1 ; h1 ; t2 ; h2

t1 _t2

t1 ^t2

jusj2 gsds h1 ÿ h2 ; h1 ÿ h2 H :

Theorem 5.3. Suppose that each log-likelihood ratio process t , Kn ht is given by the right hand side of Eq. (24), and that Condition 5.1 and 5.2 are satis®ed. Suppose also that Kn Kn ht jt; h 2 S is separable with respect to the pseudo-metric q under P0n , and that a version of Kn takes values in `1 S. Then, it holds that P0n

Kn ) G

in

`1 S ;

where the Borel probability measure G on `1 S; jj jj1 is concentrated on the set Uq S, and its ®nite-dimensional projection R t ^t Gt1 ;h1 ;...;td ;hd is the Gaussian distribution N ÿ12 diag R; R where Rij 0i j hi shj sgsds. Proof. Notice that for every t 2 0; s and h1 ; h2 2 W

ÿ ÿ1 ÿ n an h1 Z n M n;0 ; aÿ1 M n;0 t n h2 Z

Z

t 0

n 2 n h1 sh2 s aÿ1 n Zs Ys ds :

We can easily obtain the assertion from Theorem 2.3 (repeat the same argument as in the proof of Theorem 4.3). ( Next, ®x a subset W1 C which satis®es Condition 5.2 and jjhjjH 1 for every h 2 W1 . Let us consider testing hypothesis H 0 : a a0 against H1 : a a0 aÿ1 n h; h 2 W1 : We introduce the test statistics Tn

1 sup Kn hs : 2 h2W1

Then, it directly follows from Theorem 5.3 that: Corollary 5.4. Under the same conditions as in Theorem 5.3, it holds that P0n

T n ) L

in R ;

CLT for `1 -valued semimartingales

493

~ where L denotes the distribution of random variable suph2W1 Kh, and where ~ ~ K Khjh 2 W1 is a U. W1 -valued random element whose ®nite-dimen~ d N 0; R with ~ 1 ; . . . ; Kh sional distributions are given by: Kh Rij hi ; hj H . 6. Final remarks It is possible to derive the asymptotic behavior of log-likelihood ratio random ®elds of marked point processes, given by Eq. (23), in the same way as Theorem 5.3. R s Conversely, we can also construct an estimator for A Aw 0 wtatdt in Sect. 5, and show its functional asymptotic normality and asymptotic eciency as in Sect. 4. Greenwood and Wefelmeyer [15], [16], [17], [18] have successfully taken such an approach to estimate some ®nite-dimensional parameters in nonparametric models for stochastic processes (i.e. the function w in our notations is ®xed). Further they suggested the possibility of generalization to the cases of in®nite-dimensional parameters (i.e. the function w runs through W), referring the work [5] (see 9p. of [16] and 138p. of [18]). The crucial point in those problems is to show the tightness of proposed estimators, and our central limit theorems in Sect. 2 are useful to solve it. Hopefully, the results in Sects. 4 and 5 will be the prototypes of other various applications. Acknowledgements. I am grateful to Dr. S. Aki for his lectures on empirical processes in the winter of 1993±1994 at Osaka University, which inspired me to do this work. My thanks also go to Prof. J. Jacod and Prof. N. Yoshida for their valuable comments in several stages of the project.

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12. Freedman, D.A.: On tail probabilities for martingales. Ann. Probab. 3, 100±118 (1975) 13. GineÂ, E., Zinn, J.: Some limit theorems for empirical processes. Ann. Probab. 12, 929±989 (1984) 14. GineÂ, E., Zinn, J.: Lectures on the central limit theorem for empirical processses. In: Bastero, J., San Miguel, M.: Probability and Banach Spaces (Lect. Notes Math., vol. 1221, pp. 50±113) Berlin Heidelberg: Springer 1986 15. Greenwood, P.E., Wefelmeyer, W.: Ecient estimation in a nonlinear counting-process regression model. Canadian J. Statist. 19, 165±178 (1991) 16. Greenwood, P.E., Wefelmeyer, W.: Nonparametric estimators for Markov step processes. Stochastic Process. Appl. 52, 1±16 (1994) 17. Greenwood, P.E., Wefelmeyer, W.: Optimality properties of empirical estimators for multivariate point processes. J. Multivariate Anal. 49, 202±217 (1994) 18. Greenwood, P.E., Wefelmeyer, W.: Eciency of empirical estimators for Markov chains. Ann. Statist. 23, 132±143 (1995) 19. Homann-Jùrgensen, J.: Stochastic processes on Polish spaces. (Various Publication Series No. 39) Aarhus: Mathematisk Institut, Aarhus Univ. 1991 20. Ibragimov, I.A., Has'minskii, R.Z.: Asymptotically normal families of distributions and ecient estimation. Ann. Statist. 19, 1681±1724 (1991) 21. Inagaki, N., Ogata, Y.: The weak convergence of likelihood ratio random ®elds and its applications. Ann. Inst. Statist. Math. 27, 391±419 (1975) 22. Jacod, J., Shiryaev, A.N.: Limit Theorems for Stochastic Processes. Berlin Heidelberg: Springer 1987 23. LeCam, L.: On the assumptions used to prove asymptotic normality of maximum likelihood estimates. Ann. Math. Statist. 41, 802±828 (1970) 24. Ledoux, M., Talagrand, M.: Probability in Banach Spaces. Berlin Heidelberg: Springer 1991 25. Levental, S.: A uniform CLT for uniformly bounded families of martingale dierences. J. Theoret. Probab. 2, 271±287 (1989) 26. Liptser, R.S., Shiryaev, A.N.: A functional central limit theorem for semimartingales. Theory Probab. Appl. 25, 667±688 (1980) 27. Liptser, R. S., Shiryayev A. N.: Theory of Martingales. Dordrecht: Kluwer Academic Publishers 1989 28. Ossiander, M.: A central limit theorem under metric entropy with L2 bracketing. Ann. Probab. 15, 897±919 (1987) 29. Pollard, D.: A central limit theorem for empirical processes. J. Australian Math. Soc. Ser. A 33, 235±248 (1982) 30. Pollard, D.: Convergence of Stochastic Processes. New York: Springer 1984 31. Pollard, D.: Empirical Processes: Theory and Applications. (NSF-CBMS Regional Conference Series in Probability and Statistics 2) Hayward: Institute of Mathematical Statistics 1990 32. van de Geer, S.: Exponential inequalities for martingales, with application to maximum likelihood estimation for counting processes. Ann. Statist. 23, 1779±1801 (1995) 33. van der Vaart, A.W.: Statistical Estimation in Large Parameter Spaces (CWI Tract 44) Amsterdam: Centrum voor Wiskunde en Informatica 1988 34. Wellner, J.A.: Empirical processes in action: a review. Internat. Statist. Rev. 60, 247±269 (1992) 35. Yoshida, N.: Asymptotic behavior of M-estimator and related random ®eld for diusion process. Ann. Inst. Statist. Math. 42, 221±251 (1990)

Some central limit theorems for ℓ∞-valued semimartingales and their applications

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