Journal of Statistical Theory and Applications

Volume 18, Issue 4, December 2019, Pages 367 - 374

On Moments Properties of Generalized Order Statistics from Marshall-Olkin-Extended General Class of Distribution

Authors
M. A. Khan1, *, Nayabuddin2
1Department of Statistics and Operations Research, Aligarh Muslim University, Aligarh, India
2Department of Epidemiology, Jazan University, Jazan, Kingdom of Saudia Arabia
*Corresponding author. Email: khanazam2808@gmail.com
Corresponding Author
M. A. Khan
Received 21 February 2018, Accepted 11 August 2019, Available Online 22 November 2019.
DOI
10.2991/jsta.d.191112.004How to use a DOI?
Keywords
Marshall-Olkin extended general class of distribution; Generalized order statistics; Order statistics; Record values and recurrence relations
Abstract

Marshall and Olkin [Biometrika. 84 (1997), 641–652. https://doi.org/10.1093/biomet/84.3.641] introduced a new method of adding parameter to expand a family of distribution. In this paper the Marshall-Olkin extended general class of distribution is used. Further, some recurrence relations for single and product moments of generalized order statistics gos are studied. Also the results are deduced for order statistics and record values.

Copyright
© 2019 The Authors. Published by Atlantis Press SARL.
Open Access
This is an open access article distributed under the CC BY-NC 4.0 license (http://creativecommons.org/licenses/by-nc/4.0/).

1. INTRODUCTION

Kamps [2] introduced the unifying concept of generalized order statistics gos, the use of such concept has been steadily growing along the years. This is due to the fact that such concept describes random variables arranged in ascending order of magnitude and includes important well known concept that have been separately treated in statistical literature. Examples of such concepts are the order statistics, sequential order statistics, progressive type II censored order statistics, record values and pfeifer's records. Application is multifarious in a variety of disciplines and particularly in reliability.

Let n2 be a given integer and m~=m1,m2,,mn1n1,k1 be the parameters such that

γi=k+ni+j=in1mj0   for   1in1.

The random variables X1,n,m~,k,X2,n,m~,k,,Xn,n,m~,k are said to be generalized order statistics from an absolutely continuous distribution function F with the probability density funtion pdf f, if their joint density function is of the form

k(j=1n1γj)(i=1n1[1F(xi)]mif(xi))[1F(xn)]k1f(xn),
on the cone F10<x1x2xn<F11.

If mi=0,i=1,2,,n1 and k=1, we obtain the joint pdf of the order statistics and for mi=1,kN, we get the joint pdfkth record values.

Let the Marshall-Olkin extended general form of distribution be

F¯x=λehxc11λehxc,   αxβ,λ>0,
where c is such that Fα=0,Fβ=1 and hx is a monotonic and differentiable function of x in the interval α,β.

Also we have,

F¯(x)=ch(x)[1(1λ)eh(x)c]f(x),
where, F¯x=1Fx. The relation (3) will be utilized to establish recurrence relations for moments of gos.

2. RELATIONS FOR SINGLE MOMENTS

Case I: γiγj;ij=1,2,,n1.

In view of (1) the pdf of rth generalized order statistic Xr,n,m~,k is

fX(r,n,m~,k)(x)=Cr1f(x)i=1rai(r)F¯(x)γi1,
where,
Cr1=i=1rγi,γi=k+ni+j=in1mj>0,
and
ai(r)=j=1jir1(γjγi),1irn.

Theorem 2.1.

For the Marshall-Olkin extended general class of distributions as given in (2) and nN,m~,k>0,1rn,λ>0

E[ξ{X(r,n,m~,k)}]=E[ξ{X(r1,n,m~,k)}]+cγrE[ϕ{X(r,n,m~,k)}]c(1λ)γrE[ψ{X(r,n,m~,k)}],
where ϕ(x)=ξ(x)h(x) and ψ(x)=ξ(x)h(x)eh(x)c.

Proof:

We have by Athar and Islam [3],

EξXr,n,m~,kEξXr1,n,m~,k          =Cr2αβξxi=1rairF¯xγidx.

Now on using (3) in (6), we get

E[ξ{X(r,n,m~,k)}]E[ξ{X(r1,n,m~,k)}]=cCr1γrαβξ(x)h(x)i=1rai(r)[F¯(x)]γi1[1(1λ)eh(x)c]f(x)dx.
which after simplification yields (5).

Case II: mi=m,i=1,2,,n1.

The pdf of Xr,n,m,k is given as

fXr,n,m,kx=Cr1r1!F¯xγr1fxgmr1Fx,
where,
Cr1=i=1rγi,γi=k+nim+1,
hmx=1m+11xm+1,  m1.log1x,  m=1.
and
gmx=hmxhm0,x0,1.

Theorem 2.2.

For the Marshall-Olkin extended general class of distributions as given in (2) and nN,m~,k>0,1rn,λ>0

E[ξ{X(r,n,m,k)}]=E[ξ{X(r1,n,m,k)}]+cγrE[ϕ{X(r,n,m,k)}]c(1λ)γrE[ψ{X(r,n,m,k)}].

Proof:

It may be noted that for γiγj but at mi=m,i=1,2,,n1,

air=1m+1r11ri1i1!ri!.

Therefore the pdf of X(r,n,m~,k) given in (4) reduces to (7) (cf Khan et al. [4]).

Hence it can be seen that (8) is the partial case of (5) and is obtained by replacing m~ with m in (5).

Remark 2.1.

Recurrence relation for single moments of order statistics (at m=0,k=1) is

EξXr:n=EξXr1:n+cnr+1EϕXr:n1λ  EψXr:n,
at λ=1, we get
EξXr:n=EξXr1:n+cnr+1  EϕXr:n,
as obtained by Ali and Khan [5].

Remark 2.2.

Recurrence relation for single moments of kth upper record (at m=1) will be

EξXr,n,1,k=EξXr1,n,1,k+ckEϕXr,n,1,k1λEψXr,n,1,k.

Remark 2.3.

Setting λ=1 in (8), we get

EξXr,n,m,k=EξXr1,n,m,k+cγrEϕXr,n,m,k,
as obtained by Anwar et al. [6].

EXAMPLES

  1. Marshall-Olkin-Extended Exponential Distribution

    F¯x=λeθx1+1λeθx,   0<x<,  λ>0,
    we have,
    c=1θ and hx=x,
    let ξx=xj+1, then
    ϕx=j+1xj and ψx=j+1p=01pp!θpxj+p.

    Thus from relation (8), we have

    EXj+1r,n,m,kEXj+1r1,n,m,k=j+1θγrp=08(-1)pp!EXjr,n,m,k1λp=01pp!θp  EXj+pr,n,m,k.

  2. Marshall-Olkin-Extended Erlang Truncated Exponential Distribution

    F¯x=λeα1eβx11λeα1eβx,   0<x<,λ>0,α,β>0,
    here we have
    c=1α1eβ and hx=x,
    assuming ξx=xj+1, we get
    ϕx=j+1xj and ψx=j+1p=01pp!α1eβpxj+p.

    Thus from relation (8),

    EXj+1r,n,m,k=EXj+1r1,n,m,k+j+1γrα1eβp=0(1)pp!EXjr,n,m,k1λp=01pp!α1eβpEXj+pr,n,m,k.

  3. Marshall-Olkin-Extended Rayleigh Distribution

    F¯x=λex22θ21+1λex22θ2,   0<x<,λ>0,θ>0.
    we have,
    c=2θ2 and hx=x2,
    let ξx=xj+1, then
    ϕx=j+12xj1 and ψx=j+1p=01pp!12p+11θ2px2p+j1.

    Thus from relation (8), we have

    EXj+1r,n,m,kEXj+1r1,n,m,k=θ2j+1γrp=0(1)pp!EXj1r,n,m,k1λp=01pp!12θ2pEXj+2p1r,n,m,k.

3. RELATIONS FOR PRODUCT MOMENTS

Case I: γiγj;ij=1,2,,n1.

The joint probability density function pdf of X(r,n,m~,k) and X(s,n,m~,k), 1r<sn is given as

fX(r,n,m~,k),X(s,n,m~,k)(x,y)=Cs1(i=r+1sai(r)(s)F¯(y)F¯(x)γi)(i=1rai(r)F¯(x)γi)×(i=1rai(r)[F¯(x)]γi)f(x)F¯(x)f(y)F¯(y),αx<yβ,
where,
airs=j=r+1  jis1γjγi,  r+1isn.

Theorem 3.1.

For the Marshall-Olkin extended general class of distributions as given in (2). Fix a positive integer k and for nN, m~,1r<sn,

E[ξ{X(r,n,m~,k),X(s,n,m~,k)}]=E[ξ{X(r,n,m~,k),X(s1,n,m~,k)}]+cγsE[ϕ{X(r,n,m~,k),X(s,n,m~,k)}]c(1λ)γsE[ψ{X(r,n,m~,k),X(s,n,m~,k)}],
where,
ϕx,y=yξx,yhy,   ψx,y=ehycyξx,yhy,   ξx,y=ξ1x.ξ2y.

Proof:

We have by Athar and Islam [3],

E[ξ{X(r,n,m~,k),X(s,n,m~,k)}]E[ξ{X(r,n,m~,k),X(s1,n,m~,k)}]=Cs2αx<yβyξ(x,y)i=r+1sai(r)(s)F¯(y)F¯(x)γii=1rai(r)[F¯(x)]γif(x)F¯(x)dydx.

Now in view of (3) and (14), we have

E[ξ{X(r,n,m~,k),X(s,n,m~,k)}]E[ξ{X(r,n,m~,k),X(s1,n,m~,k)}]=cγsCs1αx<yβyξ(x,y)h(y)(i=r+1sai(r)(s)F¯(y)F¯(x)γi)(i=1rai(r)[F¯(x)]γi)×{[1(1λ)eh(y)c]}f(x)F¯(x)f(y)F¯(y)dydx,
which leads to (13).

Case II: mi=m;i=1,2,,n1.

The joint pdf of Xr,n,m,k and Xs,n,m,k,1r<sn is given as

fXr,n,m,k,Xs,n,m,kx,y=Cs1r1!sr1!F¯xmfxgmr1Fx×hmFyhmFxsr1F¯yγs1fy,αx<yβ.

Theorem 3.2.

For distribution as given in (2) and condition stated as in Theorem 3.1.

EξXr,n,m,k,Xs,n,m,k=EξXr,n,m,k,Xs1,n,m,k+cγsEϕXr,n,m,k,Xs,n,m,kc1λγsEψXr,n,m,k,Xs,n,m,k.

Proof:

We have when γiγj but at mi=mj=m,

airs=1m+1sr11si1ir1!si!,
hence, joint pdf of X(r,n,m~,k) and X(s,n,m~,k) given in (12) reduces to (16). (cf Khan et al. [4]). Therefore, Theorem 3.2 can be established by replacing m~ with m in Theorem 3.1.

Remark 3.1.

Recurrence relation for product moments of order statistics (at m=0,k=1) is

EξXr,s:n=EξXr,s1:n+cns+1EϕXr,s:n1λEψXr,s:n,
at λ=1, we get
EξXr,s:n=EξXr,s1:n+cns+1  EϕXr,s:n,
as obtained by Ali and Khan [7].

Remark 3.2.

Recurrence relation for product moments of kth record values will be

EξXr,n,1,k,Xs,n,1,k=EξXr,n,1,k,Xs1,n,1,k+ckEϕXr,n,1,k,Xs,n,1,k1λEψXr,n,1,k,Xs,n,1,k.

Remark 3.3.

Set λ=1 in (17), we get

EξXr,n,m,k,Xs,n,m,k=EξXr,n,m,k,Xs1,n,m,k+cγsEϕXr,n,m,k,Xs,n,m,k,
as obtained by Anwer et al. [6].

EXAMPLES

  1. Marshall-Olkin-Extended Exponential Distribution

    F¯x=λeθx1+1λeθx,   0<x<,  λ>0,
    we have,
    c=1θ and hx=x,
    let ξx,y=xiyj+1, then
    ϕx,y=j+1xiyj  and  ψx=j+1p=01pp!θpxiyj+p.

    Thus from relation (8), we have

    EXir,n,m,k,Xj+1s,n,m,kEXir,n,m,k,Xj+1s1,n,m,k=j+1θγsEXir,n,m,k,Xjs,n,m,k1λp=01pp!θpEXir,n,m,k,Xj+ps,n,m,k.

  2. Marshall-Olkin-Extended Erlang Truncated Exponential Distribution

    F¯x=λeα1eβx11λeα(1eβ)x,   0<x<,  λ>0,α,β>0.

    Here we have

    c=1α1eβ and hx=x,
    assuming ξx,y=xiyj+1, we get
    ϕx,y=j+1xiyj  and  ψx,y=j+1p=01pp!α1eβpxiyj+p.

    Thus from relation (8),

    EXir,n,m,k,Xjs,n,m,k=EXir,n,m,k,Xjs1,n,m,k+j+1γsα1eβp=01pp!EXir,n,m,k,Xjs,n,m,k1λp=01pp!α1eβpEXir,n,m,k,Xj+ps,n,m,k.

  3. Marshall-Olkin-Extended Rayleigh Distribution

    F¯x=λex22θ21+1λex22θ2,   0<x<,  λ>0,  θ>0.

    We have,

    c=2θ2 and hx=x2,
    let ξx,y=xiyj+1, then
    ϕx,y=j+12xiyj1 and ψx,y=j+1p=01pp!12p+11θ2pxiy2p+j1.

    Thus from relation (8), we have

    EXir,n,m,k,Xj+1s,n,m,kEXir,n,m,k,Xj+1s1,n,m,k        =θ2j+1γrp=0(1)pp!EXir,n,m,k,Xj1s,n,m,k1λp=01pp!12θ2pEXir,n,m,k,Xj+2p1s,n,m,k.

CONFLICT OF INTEREST

The authors declare that they have no competing interests.

AUTHORS' CONTRIBUTIONS

All authors equally contributed in the manuscript. All authors read and approved the final manuscript.

ACKNOWLEDGMENTS

The authors acknowledge with thanks to the referees and the Editor-in-Chief for their fruitful suggestions and comments which led to the overall improvement in the manuscript.

REFERENCES

3.H. Athar and H.M. Islam, Metron, Vol. LXII, 2004, pp. 327-337.
4.A.H. Khan, R.U. Khan, and M. Yaqub, J. Appl. Prob. Statist., Vol. 1, 2006, pp. 115-131.
5.M.A. Ali and A.H. Khan, J. Statist. Assoc., Vol. 35, 1997, pp. 1-9.
6.Z. Anwar, H. Athar, and R.U. Khan, J. Statist. Res., Vol. 40, 2007, pp. 93-102.
7.M.A. Ali and A.H. Khan, Metron, Vol. LVII, 1998, pp. 107-119.
Journal
Journal of Statistical Theory and Applications
Volume-Issue
18 - 4
Pages
367 - 374
Publication Date
2019/11/22
ISSN (Online)
2214-1766
ISSN (Print)
1538-7887
DOI
10.2991/jsta.d.191112.004How to use a DOI?
Copyright
© 2019 The Authors. Published by Atlantis Press SARL.
Open Access
This is an open access article distributed under the CC BY-NC 4.0 license (http://creativecommons.org/licenses/by-nc/4.0/).

Cite this article

TY  - JOUR
AU  - M. A. Khan
AU  - Nayabuddin
PY  - 2019
DA  - 2019/11/22
TI  - On Moments Properties of Generalized Order Statistics from Marshall-Olkin-Extended General Class of Distribution
JO  - Journal of Statistical Theory and Applications
SP  - 367
EP  - 374
VL  - 18
IS  - 4
SN  - 2214-1766
UR  - https://doi.org/10.2991/jsta.d.191112.004
DO  - 10.2991/jsta.d.191112.004
ID  - Khan2019
ER  -