Performance of stochastic restricted and unrestricted two-parameter estimators in linear mixed models

Latest revision as of 15:51, 14 December 2021

Abstract

In this article, two parameter estimation using penalized likelihood method in the linear mixed model is proposed. In addition, by considering the stochastic linear restriction for the vector of fixed effects parameters we are introduced the stochastic restricted two parameter estimation. Methods are proposed for estimating variance parameters when unknown. Also, the superiority conditions of the two parameter estimator over the best linear unbiased estimator, and the stochastic restricted two parameter estimator over the stochastic restricted best linear unbiased estimator are obtained under the mean square error matrix sense. Methods are proposed for estimating of the biasing parameters. Finally, a simulation study and a numerical example are given to evaluate the proposed estimators.

Keywords: Linear mixed model, two parameter estimation, stochastic restricted two parameter estimation, matrix mean square error

1. Introduction

Today many datasets lack the assumption of data independence, which is the main presupposition of many statistical models. For example data collected by cluster or hierarchical sampling, lengthwise studies and frequent measurements or in medical research that simultaneously provides data from one or more body members, the assumption of data independence is unacceptable because the data of a cluster, a group, or an individual are interdependent over time [1]. The default requirement for fitting linear models is the assumption of data independence that does not exist so the use of these models although it leads to unbiased estimates but the variance of estimating coefficients is strongly influenced by the default of data independence. In other words if the data are not independent then the standard error and therefore the confidence interval and the result test result will be for non-trust regression coefficients. Therefore in analyzing these data it is necessary to use methods that can consider this dependence. One of the most important ways to solve this problem is linear mixed models which are generalizations of simple linear models that provide the possibility of random and fixed effects with each other. Linear mixed models are used in many fields of physical, biological, medical and social sciences [2-5].

We consider the linear mixed model (LMM) as follows:

,

(1)

where ${\textstyle y}$ is an ${\textstyle n\times 1}$ vector of observations, ${\textstyle {\mathit {\boldsymbol {Z}}}=}$ $\left[{\mathit {\boldsymbol {Z}}}_{1},\ldots ,{\mathit {\boldsymbol {Z}}}_{b}\right]$ with ${\textstyle {\mathit {\boldsymbol {Z}}}_{i}}$ is an ${\textstyle n\times {q}_{i}}$ design matrix corresponding to the ${\textstyle i}$ -th random effects factor and ${\textstyle q}$ , ${\textstyle {q}_{i},\,X}$ is an ${\textstyle n\times p}$ observed design matrix for the fixed effects, ${\textstyle \beta }$ is a ${\textstyle p\times 1}$ parameter vector of unknown fixed effects, ${\textstyle {\mathit {\boldsymbol {u}}}={\left[{\mathit {\boldsymbol {u}}}_{1}^{'},\ldots ,{\mathit {\boldsymbol {u}}}_{b}^{'}\right]}^{'}}$ is a ${\textstyle q\times 1}$ unobservable vector of random effects and ${\textstyle {\mathit {\boldsymbol {\epsilon }}}}$ is an ${\textstyle n\times 1}$ unobservable vector of random errors. ${\textstyle u}$ and ${\textstyle \epsilon }$ are independent and have a multivariate normal distribution as

where ${\textstyle \zeta }$ and ${\textstyle \xi }$ are ${\textstyle {r}_{1}\times 1}$ and ${\textstyle {r}_{2}\times 1}$ vectors of variance parameters corresponding to ${\textstyle u}$ and ${\textstyle \epsilon }$ , respectively. Henderson et al. [6-7] introduced the set of equations called mixed model equations, and obtained ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ and ${\textstyle {\tilde {\mathit {\boldsymbol {u}}}}}$ as

where ${\textstyle \mathrm {Var} \,({\mathit {\boldsymbol {y}}})={\sigma }^{2}{\mathit {\boldsymbol {H}}}}$ and ${\textstyle {\mathit {\boldsymbol {H}}}=}$ ${\mathit {\boldsymbol {ZG}}}{\mathit {\boldsymbol {Z}}}^{'}+{\mathit {\boldsymbol {W}}}$ . They ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ and ${\textstyle {\tilde {\mathit {\boldsymbol {u}}}}}$ are called the best linear unbiased estimator (BLUE) and the best linear unbiased predictor (BLUP), respectively. One of the most common estimators in linear regression is the ordinary least squares (OLS) estimator, which in the case of multicollinearity may lead to estimates with adverse effects such as high variance [8]. To reduce the effects of multicollinearity. Liu et al. [9-10] proposed the ridge estimator and the Liu estimator respectively, which are the well-known alternatives of the OLS estimator. Yang and Chang [11] obtained the two parameter estimator ${\textstyle {\overset {\mbox{ˆ}}{\mathit {\boldsymbol {\beta }}}}(k,d),}$ “Using the mixed estimation technique introduced by Theil et al. [12-13]. They considered the prior information about ${\textstyle {\mathit {\boldsymbol {\beta }}}}$ in the form of restriction as ${\textstyle (d-}$ $k){\overset {\mbox{ˆ}}{\mathit {\boldsymbol {\beta }}}}(k)={\mathit {\boldsymbol {\beta }}}+$ ${\mathit {\boldsymbol {\epsilon }}}_{0},$ where ${\textstyle k,d}$ and ${\textstyle {\overset {\mbox{ˆ}}{\mathit {\boldsymbol {\beta }}}}(k)}$ are respectively the ridge, Liu parameters and the ridge estimator”.

In ${\textstyle LMM}$ , authors such as Gilmour et al. [14], Jiming and Lahiri [15] and Patel and Patel [16], considered a state where the matrix ${\textstyle {X}^{'}{H}^{-1}X}$ is singular. Liu and Hu [10] and Eliot et al. [17] inquired the ridge prediction in LMM. Liu and Hu [10] are obtained ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k)}$ and ${\textstyle {\tilde {\mathit {\boldsymbol {u}}}}(k)}$ as

where ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k)}$ and ${\textstyle {\tilde {\mathit {\boldsymbol {u}}}}(k)}$ are the ridge estimator of ${\textstyle {\mathit {\boldsymbol {\beta }}}}$ and the ridge predictor of ${\textstyle {\mathit {\boldsymbol {u}}},}$ respectively. Özkale and Can [18] gave “an example from kidney failure data” to evaluate ridge estimator in linear mixed model. Kuran and Özkale [19] obtained the mixed and stochastic restricted ridge predictors by using Gilmour approach. They introduced “stochastic linear restriction as ${\textstyle r=}$ $R\beta +\Phi$ where ${\textstyle r}$ is an ${\textstyle m\times 1}$ vector, ${\textstyle {\mathit {\boldsymbol {R}}}}$ is an ${\textstyle m\times p}$ known matrix of rank ${\textstyle m\leq p}$ and ${\textstyle \Phi }$ is an ${\textstyle m\times 1}$ random vector that is assumed to be distributed with ${\textstyle E(\Phi )=}$ $0$ and ${\textstyle \mathrm {Var} \,(\Phi )={\sigma }^{2}{\mathit {\boldsymbol {V}}}({\mathit {\boldsymbol {v}}}),}$ where ${\textstyle v}$ is ${\textstyle v\times 1}$ vector of variance parameters corresponding to ${\textstyle \Phi .}$ Also ${\textstyle \Phi }$ and ${\textstyle \epsilon }$ are independent”

Then derived the stochastic restricted estimator of ${\textstyle \beta }$ and the stochastic restricted predictor of ${\textstyle {\mathit {\boldsymbol {u}}}}$ respectively, as

Furthermore, they obtained the stochastic restricted ridge estimator of ${\textstyle \beta }$ and the stochastic restricted ridge predictor of ${\textstyle {\mathit {\boldsymbol {u}}}}$ respectively, as

{\tilde {\mathit {\boldsymbol {\beta }}}},(k)={\left({\mathit {\boldsymbol {X}}}^{'}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {R}}}+{\mathit {\boldsymbol {H}}}_{p}\right)}^{-1}\left({\mathit {\boldsymbol {X}}}^{'}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {y}}}+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {r}}}\right)

In this article, we obtain the new two parameter estimations in linear mixed models by taking Yang and Chang’s ideas [11] and considering restriction ${\textstyle (d-}$ $k){\tilde {\beta }}(k)=\beta +{\epsilon }_{0}.$ In Section ${\textstyle 2,}$ we follow the idea of Henderson’s mixed model equations to get the two parameter estimator. Then, by setting stochastic linear restrictions ${\textstyle r=}$ $R\beta +\Phi$ on the vector of fixed effects parameters, we derive the stochastic restricted two parameter estimation. In Section 3, estimates for the variance parameters are obtained when unknown. In Section 4, under the mean square error matrix (MSEM) sense we offer comparisons of new two parameter estimators. In Section 5, Methods are proposed for estimating of the biasing parameters. In Sections 6 and 7, a simulation study and a real data analysis is given. Finally, summary and some conclusions are given in Section 8.

2. The proposed estimators

Under model (1), we have

and the joint distribution of ${\textstyle u}$ and ${\textstyle y}$ is given by

{\frac {\mathrm {exp} \,\left\{{\frac {-1}{2{\sigma }^{2}}}\left(({\mathit {\boldsymbol {y}}}-{\mathit {\boldsymbol {X\beta }}}-{\mathit {\boldsymbol {Zu}}}{)}^{'}{\mathit {\boldsymbol {W}}}^{-1}({\mathit {\boldsymbol {y}}}-{\mathit {\boldsymbol {X\beta }}}-{\mathit {\boldsymbol {Zu}}})+{\mathit {\boldsymbol {u}}}^{'}{\mathit {\boldsymbol {G}}}^{-1}{\mathit {\boldsymbol {u}}}\right)\right\}}{{\left.{\left(2\pi {\sigma }^{2}\right)}^{(n+q)/2}{\mathit {\boldsymbol {W}}}\right|}^{1/2}\vert {\mathit {\boldsymbol {G}}}{\vert }^{1/2}}}

where ${\textstyle G}$ and ${\textstyle W}$ are nonsingular. If the restriction used by Yang and Ghang [11] in linear regression is transferred to linear mixed model, we can produce the two parameter estimator using “penalized term” idea. So by unifying restriction ${\textstyle (d-}$ $k){\tilde {\beta }}(k)=\beta +{\epsilon }_{0}$ with model (1) to give

(2)

where

with

{\begin{array}{lll}{I}_{\ast }={\sigma }^{2}{I}_{p},&\quad {y}_{\ast }=\left[{\begin{matrix}y\\(d-k){\tilde {\beta }}(k)\end{matrix}}\right],&\quad {X}_{\ast }=\left[{\begin{matrix}X\\{I}_{p}\end{matrix}}\right],\\{Z}_{\star }=\left[{\begin{matrix}Z\\0\end{matrix}}\right],&\quad {\epsilon }_{\ast }=\left[{\begin{matrix}\epsilon \\{\epsilon }_{0}\end{matrix}}\right],&\quad {W}_{\star }=\left[{\begin{matrix}W&0\\0&{I}_{\star }\end{matrix}}\right]\end{array}}

Then ${\textstyle u}$ and ${\textstyle {y}_{\ast }}$ are jointly distributed as

where ${\textstyle {H}_{\star }=Z,G{Z}_{\star }^{'}+{W}_{\star }=\left[{\begin{matrix}H&0\\0&{I}_{\star }\end{matrix}}\right]}$ .The conditional distribution of ${\textstyle {y}_{\ast }}$ given ${\textstyle u}$ is ${\textstyle {y}_{\ast }\mid u\sim N\left(X,\beta +\right.}$ $\left.{Z}_{\ast }u,{W}_{\ast }\right)$ and the logarithm joint density of ${\textstyle {y}_{\ast }}$ and ${\textstyle u}$ given by

{\begin{array}{ll}\mathrm {ln} \,f(y,u)&\,=\displaystyle {\frac {-1}{2{\sigma }^{2}}}\left[{\left({y}_{\ast }-{X}_{+}\beta -{Z}_{\ast }u\right)}^{'}{W}_{\ast }^{-1}\left({y}_{\ast }-{X}_{+}\beta -{Z}_{+}u\right)+{u}^{'}{G}^{-1}u\right]\\&\,\,\,-\displaystyle {\frac {n+p+q}{2}}\mathrm {ln} \,\left(2\pi {\sigma }^{2}\right)-\displaystyle {\frac {1}{2}}\mathrm {ln} \,\left|{W}_{\ast }\right|-\displaystyle {\frac {1}{2}}\mathrm {ln} \,\vert G\vert \end{array}}

The penalized log-likelihood function is obtained by succession ${\textstyle {y}_{\ast },{X}_{\ast },{Z}_{\ast }}$ and ${\textstyle {W}_{+in}}$ ${\textstyle {\left({y}_{\ast }-{X}_{\ast }\beta -{Z}_{\ast }u\right)}^{'}{W}_{\ast }^{-1}\left({y}_{\ast }-\right).}$ $\left.{X}_{\ast }\beta -{Z}_{\ast }u\right),$ as follows:

{\begin{array}{ll}\mathrm {ln} \,f(y,u)&=\displaystyle {\frac {-1}{2{\sigma }^{2}}}\left[{y}^{'}{W}^{-1}y+(d-k{)}^{2}{\tilde {\beta }}^{'}(k){\tilde {\beta }}(k)-2{\beta }^{'}{X}^{'}{W}^{-1}y-2(d-k){\tilde {\beta }}^{'}(k)\beta \right.\\&\left.-2{u}^{'}{Z}^{-1}y+2{\beta }^{'}{X}^{'}{W}^{-1}Zu+{\beta }^{'}\left(X{W}^{-1}X+{I}_{p}\right)\beta +{u}^{'}{Z}^{'}{W}^{-1}Zu+{u}^{'}{G}^{-1}u\right]\\&\,-\displaystyle {\frac {n+p+q}{2}}\mathrm {ln} \,\left(2\pi {\sigma }^{2}\right)-\displaystyle {\frac {1}{2}}\mathrm {ln} \,\vert W\vert -\displaystyle {\frac {1}{2}}\mathrm {ln} \,\vert G\vert \end{array}}

(3)

From Eq. (3), we get the partial derivative with respect to ${\textstyle \beta }$ and ${\textstyle {\mathit {\boldsymbol {u}}},}$ then set the equations to zero and by using ${\textstyle {\tilde {\beta }}(k,d)}$ and ${\textstyle {\tilde {u}}(k,d)}$ to denote the solutions give

\left({\mathit {\boldsymbol {X}}}^{'}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {I}}}_{p}\right){\tilde {\mathit {\boldsymbol {\beta }}}}\left(k,d\right)+{\mathit {\boldsymbol {X}}}^{'}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {Z}}}{\tilde {\mathit {\boldsymbol {u}}}}\left(k,d\right)={\mathit {\boldsymbol {X}}}^{'}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {y}}}+\left(d-k\right){\tilde {\mathit {\boldsymbol {\beta }}}}\left(k\right)

(4)

(5)

By solving the Eq. (5), ${\tilde {u}}(k,d)$ is

{\begin{array}{ll}{\tilde {u}}(k,d)&={\left({\mathit {\boldsymbol {Z}}}^{'}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {Z}}}+{\mathit {\boldsymbol {G}}}^{-1}\right)}^{-1}\left({\mathit {\boldsymbol {Z}}}^{'}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {y}}}-{\mathit {\boldsymbol {Z}}}^{'}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {X}}}{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)\right)\\&={\left({\mathit {\boldsymbol {Z}}}^{'}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {Z}}}+{\mathit {\boldsymbol {G}}}^{-1}\right)}^{-1}{\mathit {\boldsymbol {Z}}}^{'}{\mathit {\boldsymbol {W}}}^{-1}({\mathit {\boldsymbol {y}}}-{\mathit {\boldsymbol {X\beta }}}(k,d))\end{array}}

(6)

Using ${\textstyle {\tilde {u}}(k,d)}$ into Eq. (4) we get

{\begin{matrix}\left({\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {I}}}_{p}\right){\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)+{\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {Z}}}{\left({\mathit {\boldsymbol {Z}}}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {Z}}}+{\mathit {\boldsymbol {G}}}^{-1}\right)}^{-1}{\mathit {\boldsymbol {Z}}}{\mathit {\boldsymbol {W}}}^{-1}({\mathit {\boldsymbol {y}}}-{\mathit {\boldsymbol {X}}}{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d))\\={\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {y}}}+(d-k){\tilde {\mathit {\boldsymbol {\beta }}}}(k)\end{matrix}}

(7)

Also using ${\textstyle {H}^{-1}={\left({Z}^{'}GZ+W\right)}^{-1}={W}^{-1}-}$ ${W}^{-1}Z{\left({Z}^{'}{W}^{-1}Z+{G}^{-1}\right)}^{-1}{Z}^{'}{W}^{-1},$ this equation equals to

(8)

In Eq. (8), if we put ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k)=}$ ${\left({\mathit {\boldsymbol {X}}}^{'}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {k}}}{\mathit {\boldsymbol {I}}}_{p}\right)}^{-1}{\mathit {\boldsymbol {X}}}^{'}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {y}}},{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)$ is obtained as follows

(9)

Due to ${\textstyle \left({Z}^{'}{W}^{-1}Z+{G}^{-1}\right)G{Z}^{'}={Z}^{'}{W}^{-1}ZG{Z}^{'}+{Z}^{'}={Z}^{'}{W}^{-1}\left(ZG{Z}^{'}+W\right)={Z}^{'}{W}^{-1}H,}$ we get

(10)

Using Eq. (10), ${\textstyle {\tilde {u}}(k,d)}$ equals to ${\textstyle {\tilde {u}}(k,d)=GZ{H}^{-1}(y-X{\tilde {\beta }}(k,d))}$ .

In section, we obtain the stochastic restricted two parameter estimation. For this, the stochastic Linear restrictions ${\textstyle r=R\beta +\Phi }$ can be unified to model (1) and the restriction ${\textstyle (d-k){\tilde {\beta }},(k)=\beta +{\epsilon }_{0}}$ to give

(11)

where

{y}_{{r}^{\ast }}=\left[{\begin{matrix}y\\(d-k){\tilde {\beta }}_{r}(k)\\r\end{matrix}}\right],\quad {X}_{{r}^{\ast }}=\left[{\begin{matrix}X\\{I}_{p}\\R\end{matrix}}\right],\quad {Z}_{{r}^{\ast }}=\left[{\begin{matrix}Z\\0\\0\end{matrix}}\right],\quad {\epsilon }_{{r}^{\ast }}=\left[{\begin{matrix}\epsilon \\{\epsilon }_{0}\\\Phi \end{matrix}}\right],\quad {W}_{{r}^{\star }}=\left[{\begin{matrix}W&0&0\\0&{I}_{\ast }&0\\0&0&V\end{matrix}}\right]

Then, the conditional distribution of ${\textstyle {y}_{\ast }}$ given ${\textstyle {\mathit {\boldsymbol {u}}}}$ is ${\textstyle {\mathit {\boldsymbol {y}}}_{{r}^{\ast }}\mid {\mathit {\boldsymbol {u}}}\sim {\mathit {\boldsymbol {N}}}\left({\mathit {\boldsymbol {X}}}_{{r}^{\ast }}{\mathit {\boldsymbol {\beta }}}+{\mathit {\boldsymbol {Z}}}_{{r}^{\ast }}{\mathit {\boldsymbol {u}}},{\mathit {\boldsymbol {W}}}_{{r}^{\ast }}\right)}$ and the logarithm joint density of ${\textstyle {y}_{r}}$ and ${\textstyle u}$ given by

{\begin{array}{ll}\mathrm {ln} \,g({\mathit {\boldsymbol {y}}},{\mathit {\boldsymbol {u}}})=&\displaystyle {\frac {-1}{2{\sigma }^{2}}}\left[{\left({\mathit {\boldsymbol {y}}}_{{r}^{\ast }}-{\mathit {\boldsymbol {X}}}_{{r}^{\ast }}{\mathit {\boldsymbol {\beta }}}-{\mathit {\boldsymbol {Z}}}_{{r}^{\ast }}{\mathit {\boldsymbol {u}}}\right)}^{'}{\mathit {\boldsymbol {W}}}_{{p}^{\ast }}^{-1}\left({\mathit {\boldsymbol {y}}}_{{r}^{\ast }}-{\mathit {\boldsymbol {X}}}_{{r}^{\ast }}{\mathit {\boldsymbol {\beta }}}-{\mathit {\boldsymbol {Z}}}_{{r}^{\ast }}{\mathit {\boldsymbol {u}}}\right)+{\mathit {\boldsymbol {u}}}^{'}{\mathit {\boldsymbol {G}}}^{-1}{\mathit {\boldsymbol {u}}}\right]\\&-\displaystyle {\frac {n+m+p+q}{2}}\mathrm {ln} \,\left(2\pi {\sigma }^{2}\right)-\displaystyle {\frac {1}{2}}\mathrm {ln} \,\left|{\mathit {\boldsymbol {W}}}_{r\ast }\right|-\displaystyle {\frac {1}{2}}\mathrm {ln} \,\vert {\mathit {\boldsymbol {G}}}\vert \end{array}}

Substituting ${\textstyle {y}_{r},{X}_{{r}^{\ast }}{Z}_{{r}^{\ast }}}$ and ${\textstyle {W}_{{r}^{+}}}$ to ${\textstyle {\left({y}_{{r}^{\ast }}-{X}_{{r}^{\ast }}\beta -{Z}_{{r}^{\ast }}u\right)}^{'}{W}_{{\gamma }^{\ast }}^{-1}\left({y}_{{r}^{\ast }}-{X}_{{r}^{\ast }}\beta -{Z}_{{r}^{\ast }}u\right)}$ , the penalized log-likelihood function is obtained as follows:

{\begin{matrix}\mathrm {ln} \,g(y,u)=\displaystyle {\frac {-1}{2{\sigma }^{2}}}\left[{y}^{'}{W}^{-1}y+(d-k{)}^{2}{\tilde {\beta }}_{r}^{'}(k){\tilde {\beta }}_{r}(k)+{r}^{'}{V}^{-1}r-2{\beta }^{'}X{W}^{-1}y-2(d-k){\tilde {\beta }}_{r}^{'}(k)\beta \right.\\-2{u}^{'}{Z}^{'}{W}^{-1}y-2{\beta }^{'}{R}^{'}{V}^{-1}r+\beta {R}^{'}{V}^{-1}R\beta +\beta \left(X{W}^{-1}X+{I}_{p}\right)\beta +2{u}^{'}Z{W}^{-1}X\beta \\\left.+{u}^{'}Z{W}^{-1}Zu+{u}^{'}{G}^{-1}u\right]-\displaystyle {\frac {n+m+p+q}{2}}\mathrm {ln} \,\left(2\pi {\sigma }^{2}\right)-\displaystyle {\frac {1}{2}}\mathrm {ln} \,{W}_{{r}^{\star }}\left|-\displaystyle {\frac {1}{2}}ln\right|G\mid \end{matrix}}

(12)

From Eq. (12), we get the partial derivative with respect to ${\textstyle \beta }$ and ${\textstyle {\mathit {\boldsymbol {u}}},}$ then set the equations to zero and by using ${\textstyle {\tilde {\beta }}_{r}(k,d)}$ and ${\textstyle {\tilde {u}}_{r}(k,d)}$ to denote the solutions give

\left({\mathit {\boldsymbol {X}}}^{'}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {R}}}+{\mathit {\boldsymbol {I}}}_{p}\right){\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)+{\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {Z}}}{\tilde {\mathit {\boldsymbol {u}}}}_{r}(k,d)={\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {W}}}^{-1}{\mathit {\boldsymbol {y}}}+(d-k){\tilde {\mathit {\boldsymbol {\beta }}}},(k)+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {r}}}

(13)

(14)

By solving these equations similar to Eqs. (4) and (5), the following results are obtained

{\begin{array}{ll}{\tilde {\mathit {\boldsymbol {\beta }}}}_{r}\left(k,d\right)&={\left({\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {R}}}+{\mathit {\boldsymbol {I}}}_{p}\right)}^{-1}\left({\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {R}}}+d{\mathit {\boldsymbol {I}}}_{p}\right)\\&\times {\left({\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {R}}}+k{\mathit {\boldsymbol {I}}}_{p}\right)}^{-1}\left({\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {y}}}+{\mathit {\boldsymbol {R}}}^{\boldsymbol {'}}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {r}}}\right)\end{array}}

(15)

(16)

3. Estimation of variance parameters

In linear mixed models, the variance parameter within ${\textstyle G}$ and ${\textstyle W}$ are often unknown that several methods have been proposed by [16,20-22] to estimate them. In this section, we estimate the variance parameters using the ML method. The marginal distribution of ${\textstyle {y}_{\ast }}$ is ${\textstyle N\left({\mathit {\boldsymbol {X}}}\cdot {\mathit {\boldsymbol {\beta }}},{\sigma }^{2}{\mathit {\boldsymbol {H}}}_{\ast }\right)}$ , therefore we can write the marginal log-likelihood function of ${\textstyle {\mathit {\boldsymbol {y}}}}$

(17)

where ${\textstyle \phi ={\left({\mathit {\boldsymbol {K}}}^{'},{\sigma }^{2}\right)}^{'},{\mathit {\boldsymbol {k}}}={\left({\zeta }^{'},{\xi }^{'}\right)}^{'}}$ and ${\textstyle \left({r}_{1}+{r}_{2}+1\right)\times 1}$ and ${\textstyle \left({r}_{1}+{r}_{2}\right)\times 1}$ are vectors of unknown parameters, respectively. Differentiating the Eq. (17) with respect to ${\textstyle \beta ,{\sigma }^{2}}$ and ${\textstyle {\kappa }_{j}=}$ $1,\ldots ,{r}_{1}+{r}_{2}$ the partial derivatives is obtained as

(18)

\displaystyle {\frac {-(n+p)}{2{\sigma }^{2}}}+\displaystyle {\frac {{\left({\mathit {\boldsymbol {y}}}_{\ast }-{\mathit {\boldsymbol {X}}}\cdot {\mathit {\boldsymbol {\beta }}}\right)}^{'}{\mathit {\boldsymbol {H}}}_{\cdot }^{-1}\left({\mathit {\boldsymbol {y}}}_{\ast }-{\mathit {\boldsymbol {X}}}\cdot {\mathit {\boldsymbol {\beta }}}\right)}{2{\sigma }^{4}}},

(19)

\displaystyle {\frac {{\left({\mathit {\boldsymbol {y}}}_{\ast }-{\mathit {\boldsymbol {X}}}_{\ast }{\mathit {\boldsymbol {\beta }}}\right)}^{'}{\mathit {\boldsymbol {H}}}_{\ast }^{-1}{\dot {\mathit {\boldsymbol {H}}}}_{\ast }{\mathit {\boldsymbol {H}}}_{\ast }^{-1}\left({\mathit {\boldsymbol {y}}}_{\ast }-{\mathit {\boldsymbol {X}}}\cdot {\mathit {\boldsymbol {\beta }}}\right)}{2{\sigma }^{2}}}

(20)

where ${\textstyle {\dot {H}}_{\ast j}=\partial {H}_{\ast }/\partial {\kappa }_{j}}$ . Setting Eqs. (18)-(20) equal to zero and using ${\textstyle {\tilde {\beta }}(k,d),{\tilde {\sigma }}^{2}(k,d)}$ and ${\textstyle {\tilde {H}}}$ and instead of ${\textstyle {\mathit {\boldsymbol {\beta }}},{\sigma }^{2}}$ and ${\textstyle {\mathit {\boldsymbol {H}}}}$ gives

(21)

(22)

(\mathrm {tr} \,\left({\tilde {H}}_{\ast }^{-1}{\tilde {H}}_{\ast j}\right)=\displaystyle {\frac {{\left({y}_{\star }-{X}_{\ast }{\tilde {\beta }}\left(k,d\right)\right)}^{'}{\tilde {H}}_{\ast }^{-1}{\tilde {H}}_{\ast j}{\tilde {H}}_{\ast }^{-1}\left({y}_{\star }-{X}_{\star }{\tilde {\beta }}\left(k,d\right)\right)}{{\tilde {\sigma }}^{2}\left(k,d\right)}}

(23)

Solving Eqs. (21) and (23) yields the estimators

{\begin{array}{ll}{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)&={\left({\mathit {\boldsymbol {X}}}_{\ast }^{'}{\tilde {\mathit {\boldsymbol {H}}}}_{\ast }^{-1}{\mathit {\boldsymbol {X}}}_{\ast }\right)}^{-1}{\mathit {\boldsymbol {X}}}_{\ast }^{'}{\tilde {\mathit {\boldsymbol {H}}}}_{\ast }^{-1}{\mathit {\boldsymbol {y}}}_{\ast }\\&={\left({\mathit {\boldsymbol {X}}}^{'}{\tilde {\mathit {\boldsymbol {H}}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {I}}}_{p}\right)}^{-1}\left({\mathit {\boldsymbol {X}}}^{'}{\tilde {\mathit {\boldsymbol {H}}}}^{-1}{\mathit {\boldsymbol {X}}}+d{\mathit {\boldsymbol {I}}}_{p}\right){\left({\mathit {\boldsymbol {X}}}^{'}{\tilde {\mathit {\boldsymbol {H}}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {k}}}{\mathit {\boldsymbol {I}}}_{p}\right)}^{-1}{\mathit {\boldsymbol {X}}}^{'}{\tilde {\mathit {\boldsymbol {H}}}}^{-1}{\mathit {\boldsymbol {y}}}\end{array}}

(24)

{\begin{array}{ll}{\tilde {\sigma }}^{2}(k,d)&=\displaystyle {\frac {1}{(n+p)}}{\left({\mathit {\boldsymbol {y}}}_{\ast }-{\mathit {\boldsymbol {X}}}_{\ast }{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)\right)}^{'}{\tilde {\mathit {\boldsymbol {H}}}}_{\cdot }^{-1}\left({\mathit {\boldsymbol {y}}}_{\ast }-{\mathit {\boldsymbol {X}}}_{\ast }{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)\right)\\&=\displaystyle {\frac {1}{(n+p)}}\left\{({\mathit {\boldsymbol {y}}}-{\mathit {\boldsymbol {X}}}{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d){)}^{'}{\tilde {\mathit {\boldsymbol {H}}}}^{-1}({\mathit {\boldsymbol {y}}}-{\mathit {\boldsymbol {X}}}{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d))\right.\\&\,\,+\left.({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)-(d-k){\tilde {\mathit {\boldsymbol {\beta }}}}(k){)}^{'}({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)-(d-k){\tilde {\mathit {\boldsymbol {\beta }}}}(k))\right\}\end{array}}

(25)

Eq. (23) depends on ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)}$ and ${\textstyle {\tilde {\sigma }}^{2}(k,d),}$ so iterative procedures must be used to solve ${\textstyle {K}_{j}}$ 's. In the statistical literature, there are four iterative procedures to estimates variance parameters, which include: "Newton-Raphson (NR), Expectation Maximization algorithm (EM), Fisher Scoring (FS) and the Average Information (AI) algorithms". See [22] for details of these procedures. Note that in the stochastic restricted two parameter methods, the ML estimators is obtained similar Eqs. (21),(22) and (23).

4. Comparison of estimators

In this section, we compare the estimator ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)}$ with ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ and the estimator ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)}$ with ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{r}}$ using the mean squares error matrix (MSEM) sense. The estimator ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{2}}$ is superior to ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{1}}$ with respect to the MSEM sense, if and only if ${\textstyle \Delta \left({\tilde {\beta }}_{1},{\tilde {\beta }}_{2}\right)=}$ $MSEM\left({\tilde {\beta }}_{1}\right)-MSEM\left({\tilde {\beta }}_{2}\right)>0,$ that is, ${\textstyle \Delta \left({\tilde {\beta }}_{1},{\tilde {\beta }}_{2}\right)}$ is a positive definite (pd) matrix. The mean-square error matrix for the estimator ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)}$ is given as

The variance matrix of ${\textstyle {\tilde {\beta }}(k,d)}$ is

where ${\textstyle {T}_{1}={\left({X}^{'}{H}^{-1}X+{I}_{p}\right)}^{-1}\left({X}^{'}{H}^{-1}X+\right.}$ $\left.d{I}_{p}\right){\left({X}^{'}{H}^{-1}X+k{I}_{p}\right)}^{-1}.$ The bias ${\textstyle ({\tilde {\beta }}(k,d))}$ is given as

bias

The mean-square error matrix for the estimator ${\textstyle {\tilde {\beta }}_{r}(k,d)}$ is given as

where

and

{\begin{array}{ll}{\rm {bias}}\,\left({\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)\right)&=-{\left({\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {R}}}+{\mathit {\boldsymbol {I}}}_{p}\right)}^{-1}{\left({\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {R}}}+k{\mathit {\boldsymbol {I}}}_{p}\right)}^{-1}\\&\times \left((k+1-d)\left({\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}+{\mathit {\boldsymbol {R}}}^{'}{\mathit {\boldsymbol {V}}}^{-1}{\mathit {\boldsymbol {R}}}\right)+k{\mathit {\boldsymbol {I}}}_{p}\right){\mathit {\boldsymbol {\beta }}}\end{array}}

4.1 Comparison the Estimator β̃(k,d) with β̃

The ${\textstyle MSEM}$ of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ is ${\textstyle \mathrm {MSEM} \,({\tilde {\mathit {\boldsymbol {\beta }}}})=}$ ${\sigma }^{2}{\mathit {\boldsymbol {A}}}^{-1},$ where ${\textstyle {\mathit {\boldsymbol {A}}}_{1}=}$ $\left({\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}\right),$ and the ${\textstyle MSEM}$ of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)}$ is

The estimator ${\textstyle {\tilde {\beta }}(k,d)}$ is superior to the estimator ${\textstyle {\tilde {\beta }}}$ under the MSEM sense, if and only if ${\textstyle \mathrm {MSEM} \,({\tilde {\mathit {\boldsymbol {\beta }}}})-\mathrm {MSEM} \,({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d))>0}$ then

According to Farebrother ${\textstyle (1976),}$ if ${\textstyle {\sigma }^{2}\left({A}_{1}^{-1}-\right.}$ $\left.{T}_{1}{A}_{1}{T}_{1}\right)>0,$ then the necessary and sufficient condition for ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)}$ to be superior to ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ is ${\textstyle {\mathit {\boldsymbol {\beta }}}^{'}{\left({\mathit {\boldsymbol {T}}}_{1}{\mathit {\boldsymbol {A}}}_{1}-{\mathit {\boldsymbol {I}}}_{p}\right)}^{'}{\left[{\sigma }^{2}\left({\mathit {\boldsymbol {A}}}_{1}^{-1}-{\mathit {\boldsymbol {T}}}_{1}{\mathit {\boldsymbol {A}}}_{1}{\mathit {\boldsymbol {T}}}_{1}\right)\right]}^{-1}\left({\mathit {\boldsymbol {T}}}_{1}{\mathit {\boldsymbol {A}}}_{1}-\right.}$ $\left.{\mathit {\boldsymbol {I}}}_{p}\right){\mathit {\boldsymbol {\beta }}}<1$ .

5. Selection of parameters k and d

In the linear regression model, choosing the parameter ${\textstyle k}$ is important so many statisticians were suggested several methods for obtaining this parameter. These methods were proposed by many researchers [23-29] and others. According to Ozkale and Can [18], we rewrite model (1) in the form of a marginal model in which random effects are not explicitly defined:

(26)

Because ${\textstyle {\mathit {\boldsymbol {H}}}}$ is pd, then there is a nonsingular symmetric matrix ${\textstyle {\mathit {\boldsymbol {N}}}}$ such that ${\textstyle {\mathit {\boldsymbol {H}}}=}$ ${\mathit {\boldsymbol {N}}}^{'}{\mathit {\boldsymbol {N}}}$ . If we multiply both sides of model (42) by ${\textstyle {\boldsymbol {N}}^{-1}}$ , we get ${\textstyle {\mathit {\boldsymbol {y}}}^{\ast }=}$ ${\mathit {\boldsymbol {X}}}^{\ast }{\mathit {\boldsymbol {\beta }}}+{\mathit {\boldsymbol {S}}}^{\ast }$ , where ${\textstyle {\dot {\mathit {\boldsymbol {y}}}}={\mathit {\boldsymbol {N}}}^{-1}{\mathit {\boldsymbol {y}}},{\mathit {\boldsymbol {X}}}^{\ast }=}$ ${\mathit {\boldsymbol {N}}}^{-1}{\mathit {\boldsymbol {X}}}$ , ${\textstyle {\mathit {\boldsymbol {S}}}^{\ast }={\mathit {\boldsymbol {N}}}^{-1}{\mathit {\boldsymbol {S}}}}$ and ${\textstyle \mathrm {Var} \,\left({\mathit {\boldsymbol {S}}}^{\ast }\right)={\mathit {\boldsymbol {I}}}_{n}}$ . The matrix ${\textstyle {\mathit {\boldsymbol {X}}}^{\ast }{\mathit {\boldsymbol {X}}}^{\ast }=}$ ${\mathit {\boldsymbol {X}}}^{'}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}$ is symmetric, so there is an orthogonal matrix ${\textstyle {\mathit {\boldsymbol {P}}}}$ such that ${\textstyle {\mathit {\boldsymbol {P}}}^{'}{\mathit {\boldsymbol {P}}}=}$ ${\mathit {\boldsymbol {P}}}{\mathit {\boldsymbol {P}}}^{'}={\mathit {\boldsymbol {I}}}_{p}$ and ${\textstyle {\mathit {\boldsymbol {P}}}^{'}{\mathit {\boldsymbol {X}}}^{\ast }{\mathit {\boldsymbol {X}}}^{\ast }{\mathit {\boldsymbol {P}}}=}$ ${\boldsymbol {\Lambda }}=\mathrm {diag} \,\left({\lambda }_{1},\ldots ,{\lambda }_{p}\right),$ where ${\textstyle {\lambda }_{1}\geq {\lambda }_{2}\geq \ldots \geq {\lambda }_{p}}$ are the ordered eigenvalues of ${\textstyle {\mathit {\boldsymbol {X}}}^{\ast }{\mathit {\boldsymbol {X}}}^{\ast }}$ . Then model (26) can be rewritten in a canonical form as ${\textstyle {\mathit {\boldsymbol {y}}}^{\ast }=}$ ${\mathit {\boldsymbol {X}}}^{\ast \ast }{\mathit {\boldsymbol {\gamma }}}+{\mathit {\boldsymbol {S}}}^{\ast }$ , where ${\textstyle {\mathit {\boldsymbol {X}}}^{\ast \ast }=}$ ${\mathit {\boldsymbol {X}}}^{\ast }{\mathit {\boldsymbol {P}}}$ and ${\textstyle {\mathit {\boldsymbol {\gamma }}}=}$ ${\mathit {\boldsymbol {P}}}^{'}{\mathit {\boldsymbol {\beta }}}''$ . Under this model, we get the following representation:

We use ${\textstyle \mathrm {MSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d),{\mathit {\boldsymbol {\beta }}})}$ to find the optimal values of ${\textstyle k}$ and ${\textstyle d}$ , where ${\textstyle \mathrm {MSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d),{\mathit {\boldsymbol {\beta }}})}$ is the mean square error. Let ${\textstyle d}$ fixed, the optimal value of the ${\textstyle k}$ can be obtained by minimizing the following statement

Notice that ${\textstyle \mathrm {MSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d),{\mathit {\boldsymbol {\beta }}})=\mathrm {MSE} \,({\tilde {\gamma }}(k,d),\gamma )=\mathrm {tr} \,[\mathrm {MSEM} \,({\tilde {\gamma }}(k,d),\gamma )].}$ Therefore, getting ${\textstyle \displaystyle {\frac {\partial \mathrm {MSE} \,({\tilde {\gamma }}(k,d),\gamma )}{\partial k}}=}$ $0,$ we obtain ${\textstyle k=\displaystyle {\frac {{\sigma }^{2}\left({\lambda }_{i}+d\right)-{\lambda }_{i}{\gamma }_{i}^{2}(1-d)}{{\gamma }_{i}^{2}\left({\lambda }_{j}+1\right)}}.}$ Since the optimal ${\textstyle k}$ depends on unknown ${\textstyle \gamma }$ and ${\textstyle {\sigma }^{2},}$ then according Hoerl and Kennard [9] we can get the estimate of ${\textstyle k}$ by substituting ${\textstyle {\tilde {\gamma }}}$ and ${\textstyle {\tilde {\sigma }}^{2}}$ as follows:

(27)

where ${\textstyle {\tilde {\gamma }}}$ and ${\textstyle {\tilde {\sigma }}^{2}}$ are the unbiased estimators ${\textstyle {\mathit {\boldsymbol {\gamma }}}}$ and ${\textstyle {\sigma }^{2}}$ . According to the estimator of ${\textstyle k,}$ which Kibria [25] and Hoerl and Kennard [9] proposed, the harmonic mean value of ${\textstyle k}$ in (27) is

Now, let ${\textstyle k}$ fixed, and we get the optimal value ${\textstyle d}$ by minimizing ${\textstyle \mathrm {MSE} \,({\tilde {\gamma }}(k,d),\gamma )}$ . Therefore getting ${\textstyle \displaystyle {\frac {\partial \mathrm {MSE} \,({\tilde {\gamma }}(k,d),\gamma )}{\partial d}}=}$ $0,$

{\textstyle {\tilde {d}}_{opt}=\displaystyle {\frac {\sum _{i=1}^{p}\displaystyle {\frac {[\left(\left(k+1\right){\lambda }_{i}+k\right){\lambda }_{i}{\tilde {\gamma }}_{i}^{2}-\,{\lambda }_{i}^{2}{\tilde {\sigma }}^{2}\,]}{[{(\,{\lambda }_{i}+k)}^{2}\ast {({\lambda }_{i}\,+1)}^{2}]}}}{\sum _{i=1}^{p}\displaystyle {\frac {[\left({\tilde {\sigma }}^{2}\,+\,\,{\lambda }_{i}{\tilde {\gamma }}_{i}^{2}\right){\lambda }_{i}]}{[{({\lambda }_{i}+k)}^{2}\ast {({\lambda }_{i}+1)}^{2}]}}}}}

(28)

Since ${\textstyle k}$ is always be positive, in this section we get the positive condition of the estimator in Eq. (27). For this purpose, we use the following theorem.

Theorem 5.1

If ${\textstyle {\tilde {d}}>max\left\{\displaystyle {\frac {1-{\tilde {\sigma }}^{2}{\tilde {\gamma }}_{i}^{2}}{1+{\tilde {\sigma }}^{2}/\left({\lambda }_{i}{\tilde {\gamma }}_{i}^{2}\right)}}\right\}}$ , for all ${\textstyle i,}$ then ${\textstyle {\tilde {k}}_{HM}}$ are always positive.

Proof.

If ${\textstyle \displaystyle {\frac {{\sigma }^{2}\left({\lambda }_{i}+d\right)-{\lambda }_{i}{\gamma }_{i}^{2}(1-d)}{{\gamma }_{i}^{2}\left({\lambda }_{i}+1\right)}}>0}$ , then the values of ${\textstyle k}$ are positive. Since ${\textstyle {\gamma }_{i}^{2}\left({\lambda }_{i}+1\right)>0}$ and ${\textstyle {\sigma }^{2}\left({\lambda }_{i}+\right.}$ $\left.d\right)-{\lambda }_{i}{\gamma }_{i}^{2}(1-d)$ must be positive for all ${\textstyle i}$ . Then we get ${\textstyle d>\displaystyle {\frac {1-{\sigma }^{2}/{\gamma }_{i}^{2}}{1+{\sigma }^{2}/\left({\lambda }_{i}{\gamma }_{i}^{2}\right)}}}$ and because depends on the unknown parameters ${\textstyle {\gamma }_{i}^{2}}$ and ${\textstyle {\sigma }^{2},}$ so their unbiased estimators are replaced. Therefore ${\textstyle {\tilde {k}}_{HM}}$ is always positive if ${\textstyle {\tilde {d}}}$ is selected as ${\textstyle {\tilde {d}}>max\left\{\displaystyle {\frac {1-{\tilde {\sigma }}^{2}{\tilde {\gamma }}_{i}^{2}}{1+{\tilde {\sigma }}^{2}/\left({\lambda }_{j}{\tilde {\gamma }}_{i}^{2}\right)}}\right\}}$ .

Note that ${\textstyle \displaystyle {\frac {1-{\tilde {\sigma }}^{2}/{\gamma }_{i}^{2}}{1+{\tilde {\sigma }}^{2}/\left({\lambda }_{i}{\tilde {\gamma }}_{i}^{2}\right)}}}$ is always less than one and since ${\textstyle d}$ must be between zero and one, we consider the inequality ${\textstyle {\tilde {d}}>max\left\{\displaystyle {\frac {1-{\tilde {\sigma }}^{2}{\tilde {\gamma }}_{i}^{2}}{1+{\tilde {\sigma }}^{2}/\left({\lambda }_{i}{\tilde {\gamma }}_{i}^{2}\right)}}\right\}}$ as follows

(29)

Since ${\textstyle {\tilde {d}}_{opt~}}$ in (28) depends on ${\textstyle k}$ and the estimators of ${\textstyle k}$ in ${\textstyle {\tilde {k}}_{HM}}$ depend on ${\textstyle d}$ , we consider an iterative method for these parameters by applying the following method. Step ${\textstyle 1,}$ calculate ${\textstyle {\tilde {d}}}$ from Eq. (29). Step 2, calculate ${\textstyle {\tilde {k}}_{HM}}$ by using ${\textstyle {\tilde {d}}}$ in step 1 . Step ${\textstyle 3,}$ calculate ${\textstyle {\tilde {d}}_{opt~}}$ from Eq. (28) by using the estimator ${\textstyle {\tilde {k}}_{HM}}$ in Step 2 . Step ${\textstyle 4,}$ if ${\textstyle {\tilde {d}}_{opt~}}$ is not between zero and one use ${\textstyle {\tilde {d}}_{opt~}=}$ ${\tilde {d}}$

6. A simulation study

In this section, we compare the performance of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}},{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d),{\tilde {\mathit {\boldsymbol {\beta }}}}_{t}}$ and ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)}$ with a simulation study. For this purpose, we calculate the estimated mean square error (EMSE) with various values of sample size, variance and degree of collinearity. Following McDonald and Galarneau [27], we are computed the fixed effects as

(30)

where ${\textstyle {w}_{ijc}}$ independent standard normal are pseudo-random numbers and ${\textstyle {\rho }^{2}}$ is the correlation between any two fixed effects. Three different sets of ${\textstyle {\rho }^{2}}$ were considered as 0.75,0.85 and ${\textstyle 0.95.}$ The ${\textstyle {\mathit {\boldsymbol {Z}}}}$ matrix is produced in a completely randomized design. Observation on responses are then determined by

(31)

We consider two designs that in the first design ${\textstyle {n}_{i}=}$ $3$ and in the second design ${\textstyle {n}_{i}=7}$ . Also, the same value ${\textstyle t=}$ $9,p=4$ and ${\textstyle q=9}$ are taken in both designs. Following Ozcale and Can [18], the ${\textstyle {\mathit {\boldsymbol {\beta }}}}$ vector was chosen as the eigenvector corresponding to the largest eigenvalue of the ${\textstyle {\boldsymbol {X}}^{'}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}}}$ matrix”. The variances matrix of random effects ${\textstyle {u}_{i}}$ and ${\textstyle {\epsilon }_{ij}}$ are ${\textstyle {\mathit {\boldsymbol {G}}}=}$ ${\sigma }_{1}^{2}{\mathit {\boldsymbol {I}}}_{q}$ and ${\textstyle {\mathit {\boldsymbol {W}}}=}$ ${\sigma }^{2}{\mathit {\boldsymbol {I}}}_{a}$ , respectively. They ${\textstyle {u}_{i}}$ are generated from the normal distribution ${\textstyle N(0,G)}$ . We are considered ${\textstyle {\sigma }^{2}=}$ $0.5,1$ and ${\textstyle {\sigma }_{1}^{2}=0.5,1}$ .The trial was replicated 1000 times by generating ${\textstyle {u}_{i}}$ and ${\textstyle {\epsilon }_{ij}.}$ For each simulated data set derived ${\textstyle {\tilde {k}}_{HM}}$ and ${\textstyle {\tilde {d}}_{opt~},}$ and then the estimated mean squared error (EMSE) calculated as calculated the relative mean square (RMSE) as

when ${\textstyle RMSE}$ is greater than one, it indicates that the estimator ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}^{\ast }}$ superior to the estimator ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ . For the stochastic linear restriction ${\textstyle {\mathit {\boldsymbol {r}}}=}$ ${\mathit {\boldsymbol {R\beta }}}+\Phi ,$ the matrix ${\textstyle {\mathit {\boldsymbol {R}}}}$ is ${\textstyle m\times p}$ and generated from the normal distribution ${\textstyle N(0,1)}$ and the matrix ${\textstyle \Phi }$ is generated from the normal distribution ${\textstyle N(0,{\mathit {\boldsymbol {V}}})}$ where ${\textstyle {\mathit {\boldsymbol {V}}}}$ is taken as ${\textstyle =}$ $\mathrm {diag} \,\left({\sigma }^{2}{\mathit {\boldsymbol {I}}}_{m}\right)$ ) with ${\textstyle m=}$ $2$ . In Table 1, we obtain the values of EMSE and RMSE for ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}},{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d),{\tilde {\mathit {\boldsymbol {\beta }}}}_{r}}$ and ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)}$ . We have the following results for Table 1:

(i) In the whole table, the EMSE values of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)}$ is less than ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ . Also, the EMSE values of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)}$ is less than ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{r}}$ . In general, the EMSE values of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)}$ is less than all estimators.

(ii) As ${\textstyle {\rho }^{2}}$ and ${\textstyle {\sigma }^{2}}$ increase, the EMSE values of the estimators increase.

(iii) As ${\textstyle {\rho }^{2}}$ increases, difference between the EMSE values of the two parameter estimators and the EMSE values of the best linear unbiased estimators increase. This implies an increase in the improvement of the two-parameter estimators.

Table 1. Estimated

and SMSE values with

and

$p=0.75$	$\left({\sigma }^{2},{\sigma }_{1}^{2}\right)=(0.5,0.5)$		$\left({\sigma }^{2},{\sigma }_{1}^{2}\right)=(1,1)$
ni	3	7	3	7
$\mathrm {EMSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}})$	0.0001526	7.3974e-05	0.0003053	0.0001479
$\mathrm {EMSE} \,\left({\tilde {{\mathit {\boldsymbol {\beta }}}_{\mathit {\boldsymbol {r}}}}}_{\,}\right)$	0.0001461	7.1668e-05	0.0002923	0.0001433
$\mathrm {EMSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d))$	0.0001032	6.9166e-05	0.0001912	0.0001332
$\mathrm {EMSE} \,\left({\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)\right)$	9.9335e-05	6.7089e-05	0.0001845	0.0001293
$\mathrm {RMSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}}:{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d))$	1.4795	1.0695	1.5965	1.1104
$\mathrm {RMSE} \,\left({\tilde {\mathit {\boldsymbol {\beta }}}}_{r}:{\tilde {\mathit {\boldsymbol {\beta }}}}_{c}(k,d)\right)$	1.4716	1.0682	1.5845	1.1083
$\mathrm {RMSE} \,\left({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d):{\tilde {\mathit {\boldsymbol {\beta }}}}_{\mathit {\boldsymbol {c}}}(k,d)\right)$	1.0389	1.0309	1.0363	1.0301
$p=0.85$	$\left({\sigma }^{2},{\sigma }_{1}^{2}\right)=(0.5,0.5)$		$\left({\sigma }^{2},{\sigma }_{1}^{2}\right)=(1,1)$
ni	3	7	3	7
$\mathrm {EMSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}})$	0.0002198	0.0003460	0.0004396	0.0002387
$\mathrm {EMSE} \,\left({\tilde {{\mathit {\boldsymbol {\beta }}}_{\mathit {\boldsymbol {r}}}}}_{\,}\right)$	0.0002076	0.0001134	0.0004153	0.0002269
$\mathrm {EMSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d))$	0.0001332	0.0001045	0.0002562	0.0002111
$\mathrm {EMSE} \,\left({\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)\right)$	0.0001277	0.0002460	0.0002459	0.0002014
$\mathrm {RMSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}}:{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d))$	1.6495	1.1414	1.7156	1.1308
$\mathrm {RMSE} \,\left({\tilde {\mathit {\boldsymbol {\beta }}}}_{r}:{\tilde {\mathit {\boldsymbol {\beta }}}}_{c}(k,d)\right)$	1.6263	1.1373	1.6889	1.1266
$\mathrm {RMSE} \,\left({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d):{\tilde {\mathit {\boldsymbol {\beta }}}}_{\mathit {\boldsymbol {c}}}(k,d)\right)$	1.0430	1.1219	1.0418	1.0481
$p=0.95$	$\left({\sigma }^{2},{\sigma }_{1}^{2}\right)=(0.5,0.5)$		$\left({\sigma }^{2},{\sigma }_{1}^{2}\right)=(1,1)$
ni	3	7	3	7
$\mathrm {EMSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}})$	0.0005729	0.0003460	0.0011459	0.0006920
$\mathrm {EMSE} \,\left({\tilde {{\mathit {\boldsymbol {\beta }}}_{\mathit {\boldsymbol {r}}}}}_{\,}\right)$	0.0005033	0.0003044	0.0010066	0.0006088
$\mathrm {EMSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d))$	0.0002762	0.0002760	0.0005201	0.0005272
$\mathrm {EMSE} \,\left({\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)\right)$	0.0002578	0.0002460	0.0004927	0.0004716
$\mathrm {RMSE} \,({\tilde {\mathit {\boldsymbol {\beta }}}}:{\tilde {\mathit {\boldsymbol {\beta }}}}(k,d))$	2.0743	1.2533	2.2030	1.3125
$\mathrm {RMSE} \,\left({\tilde {\mathit {\boldsymbol {\beta }}}}_{r}:{\tilde {\mathit {\boldsymbol {\beta }}}}_{c}(k,d)\right)$	1.9524	1.2369	2.0429	1.2908
$\mathrm {RMSE} \,\left({\tilde {\mathit {\boldsymbol {\beta }}}}(k,d):{\tilde {\mathit {\boldsymbol {\beta }}}}_{\mathit {\boldsymbol {c}}}(k,d)\right)$	1.0713	1.1219	1.0556	1.1178

7. Real data analysis

We consider a data set, which is known as the Egyptian pottery data to show the behavior of the new Restricted and Unrestricted Two-Parameter Estimators. This data set arises from an extensive archaeological survey of pottery production and distribution in the ancient Egyptian city of Al-Amarna. The data consist of measurements of chemical contents (mineral elements) made on many samples of pottery using two different techniques, NAA and ICP (see Smith et al. [30] for description of techniques). The set of pottery was collected from different locations around the city. We fit the data set by linear mixed model as ${\textstyle {\mathit {\boldsymbol {y}}}=}$ ${\mathit {\boldsymbol {X\beta }}}+{\mathit {\boldsymbol {Zu}}}+{\mathit {\boldsymbol {\epsilon }}},$ where ${\textstyle {\mathit {\boldsymbol {y}}}}$ is ${\textstyle 159\times 1}$ vector of response variables, ${\textstyle {\mathit {\boldsymbol {X}}}}$ and ${\textstyle {\mathit {\boldsymbol {Z}}}}$ which are regression matrix with dimensions ${\textstyle 159\times 6}$ and ${\textstyle 159\times 25}$ respectively. First, we are estimated the variance components by consider ${\textstyle {\sigma }_{1}^{2}=}$ $0.5$ and ${\textstyle {\sigma }^{2}=0.5.}$ Then, by calculating the eigenvalues of ${\textstyle {\mathit {\boldsymbol {X}}}{\mathit {\boldsymbol {H}}}^{-1}{\mathit {\boldsymbol {X}}},}$ the condition number 8322860 is obtained, which indicate severe multicollinearity. We considered the stochastic linear restrictions as ${\textstyle {\mathit {\boldsymbol {r}}}=}$ ${\mathit {\boldsymbol {R\beta }}}+\Phi ,\Phi \sim N\left(0,{\sigma }^{2}{\mathit {\boldsymbol {I}}}_{3}\right)$ and selected 3 available data in the previous sections to the Egyptian pottery data. ${\textstyle {\tilde {k}}_{HM}}$ and ${\textstyle {\tilde {d}}_{opt}}$ are obtained using the iterative method introduced at the end of section 5,0.348 and 0.373 respectively. In Table 2, the estimated ${\textstyle MSE}$ values of the estimators are obtained by replacing in the corresponding theoretical MSE equations. We can see the estimated MSE values of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)}$ is less than ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ . Also, the estimated MSE values of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{c}(k,d)}$ is less than ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{r}}$ . In general, the estimated MSE values of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)}$ is less than all estimators. So, we conclude that the stochastic restricted two parameter estimator performs better than the other estimators. Note that in the results obtained for this data, all eigenvalues of ${\textstyle {\Delta }_{1}}$ and ${\textstyle {\Delta }_{2}}$ are positive and the condition of Theorem 4.1 and Theorem 4.2 are true. In Figure 1, a plot of the estimated MSE values of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ and ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)}$ against ${\textstyle k}$ in the interval [0,2] with fixed ${\textstyle {\tilde {d}}_{opt~}=}$ $0.373$ is drawn. Because ${\textstyle {\tilde {\beta }}}$ is not dependent on ${\textstyle k}$ , its estimated ${\textstyle MSE}$ value is the same for all ${\textstyle k}$ values. It is obvious that estimated ${\textstyle MSE}$ values of ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)}$ is always less than ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ . Altogether, it is obvious that the two parameter estimators can perform better than the ${\textstyle {\tilde {\mathit {\boldsymbol {\beta }}}}}$ in MSEM criterion under conditions.

Table 2. Estimated MSE values of the proposed estimators

	${\tilde {\mathit {\boldsymbol {\beta }}}}{\,}{\,}{\,}$	${\tilde {\mathit {\boldsymbol {\beta }}}}_{r}$	${\tilde {\mathit {\boldsymbol {\beta }}}}(k,d)$	${\tilde {\mathit {\boldsymbol {\beta }}}}_{r}(k,d)$
EMSE	1.216069	1.201379	0.1544953	0.1541745

Figure 1. The estimated mean square error values of the estimators versus

with

8. Conclusion

In this article, we proposed the two parameter estimator and the stochastic restricted two parameter estimator to overcome the effects of the multicollinearity problem in linear mixed models. We also obtained estimates of variance parameters and then using the mean squared error matrix sense made comparisons between the proposed estimators and some other estimators. Finally, we proposed methods for estimating biasing parameters and provided a simulation study and a data example to illustrate performance of new estimators.

Disclosure statement

No potential conflict of interest was reported by the authors..

Funding

The research was supported by the Slamic Azad University.

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Latest revision as of 15:51, 14 December 2021

Abstract

1. Introduction

2. The proposed estimators

3. Estimation of variance parameters

4. Comparison of estimators

4.1 Comparison the Estimator β̃(k,d) with β̃

5. Selection of parameters k and d

6. A simulation study

7. Real data analysis

8. Conclusion

Disclosure statement

Funding

References

Document information

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Keywords

claim authorship

@@ Line 4: / Line 4: @@
 ==Performance of Stochastic Restricted and Unrestricted Two-Parameter Estimators in linear Mixed Models==
-'''Nahid Ganjealivand<sup>*1</sup>, Fatemeh Ghapani<sup>2</sup>,'''<big>''' '''</big>'''Ali Zaherzadeh<sup>3</sup>, Farshin Hormozinejad<sup>1</sup>'''
+'''AsupNahid Ganjealivand<sup>1</sup>, Fatemeh Ghapani<sup>*2</sup>,'''<big>''' '''</big>'''AsupZaherzadeh<sup>3</sup>, Farshin Hormozinejad<sup>1</sup>'''
 <sup>1</sup> Department of Statistics, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran
-ganjealivandsci[mailto:@ @]gmail.com
 <sup>2</sup> Department of Mathematics and Statistics, Shoushtar Branch, Islamic Azad University, Shoushtar, Iran
-∗Corresponding author. Email address:f.ghapani[mailto:sci@gmail.com sci@gmail.com], [mailto:f-ghapani@phdstu.ac.ir f-ghapani@phdstu.ac.ir]
+∗Corresponding author. Email address:f.ghapani[mailto:f.ghapani@iau-shoushtar.ac.ir], [mailto:f-ghapani@phdstu.ac.ir f-ghapani@phdstu.ac.ir]
 <sup>3</sup>Jundi-Shapur University of Technology,Dezful,Iran
@@ Line 20: / Line 31: @@
 In this article, two parameter estimation using penalized likelihood method in the linear mixed model is proposed. In addition, by considering the stochastic linear restriction for the vector of fixed effects parameters we are introduced the stochastic restricted two parameter estimation. Methods are proposed for estimating variance parameters when unknown. Also, the superiority conditions of the two parameter estimator over the best linear unbiased estimator, and the stochastic restricted two parameter estimator over the stochastic restricted best linear unbiased estimator are obtained under the mean square error matrix sense. Methods are proposed for estimating of the biasing parameters. Finally, a simulation study and a numerical example are given to evaluate the proposed estimators.
-'''Keywords''': Linear mixed model, two parameter estimation, stochastic restricted two parameter estimation, matrix mean square error.
+'''Keywords''': Linear mixed model, two parameter estimation, stochastic restricted two parameter estimation, matrix mean square error
 <!--'''Mathematics Subject''' '''Classification'''  62J05. 62J12.-->
 ==1. Introduction==
@@ Line 49: / Line 60: @@
-where <math display="inline">\zeta</math>  and <math display="inline">\xi</math>  are <math display="inline">{r}_{1}\times 1</math> and <math display="inline">{r}_{2}\times 1</math> vectors of variance parameters corresponding to <math display="inline">u</math> and <math display="inline">\epsilon</math>, respectively. Henderson et al [6-7] introduced the set of equations called mixed model equations, and obtained <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math> and <math display="inline">\tilde{\mathit{\boldsymbol{u}}}</math> as
+where <math display="inline">\zeta</math>  and <math display="inline">\xi</math>  are <math display="inline">{r}_{1}\times 1</math> and <math display="inline">{r}_{2}\times 1</math> vectors of variance parameters corresponding to <math display="inline">u</math> and <math display="inline">\epsilon</math>, respectively. Henderson et al. [6-7] introduced the set of equations called mixed model equations, and obtained <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math> and <math display="inline">\tilde{\mathit{\boldsymbol{u}}}</math> as
 {| class="formulaSCP" style="width: 100%; text-align: center;"
 |-
@@ Line 61: / Line 72: @@
 where <math display="inline">\mathrm{Var}\,(\mathit{\boldsymbol{y}})={\sigma }^{2}\mathit{\boldsymbol{H}}</math> and <math display="inline">\mathit{\boldsymbol{H}}=</math><math>\mathit{\boldsymbol{ZG}}{\mathit{\boldsymbol{Z}}}^{'}+\mathit{\boldsymbol{W}}</math>. They <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math> and <math display="inline">\tilde{\mathit{\boldsymbol{u}}}</math> are called the best linear unbiased estimator (BLUE) and the best linear unbiased predictor (BLUP), respectively. One of the most common estimators in linear regression is the ordinary least squares (OLS) estimator, which in the case of multicollinearity may lead to estimates with adverse effects such as high variance [8]. To reduce the effects of multicollinearity. Liu et al. [9-10] proposed the ridge estimator and the Liu estimator respectively, which are the well-known alternatives of the OLS estimator. Yang and Chang [11] obtained the two parameter estimator <math display="inline">\overset{\mbox{ˆ}}{\mathit{\boldsymbol{\beta }}}(k,d),</math> “Using the mixed estimation technique introduced by Theil et al. [12-13]. They considered the prior information about <math display="inline">\mathit{\boldsymbol{\beta }}</math> in the form of restriction as <math display="inline">(d-</math><math>k)\overset{\mbox{ˆ}}{\mathit{\boldsymbol{\beta }}}(k)=\mathit{\boldsymbol{\beta }}+</math><math>{\mathit{\boldsymbol{\epsilon }}}_{0},</math> where <math display="inline">k,d</math> and <math display="inline">\overset{\mbox{ˆ}}{\mathit{\boldsymbol{\beta }}}(k)</math> are respectively the ridge, Liu parameters and the ridge estimator”.
-In <math display="inline">LMM</math>, authors such as Gilmour, Jiang and Searl in [14-16], considered a state where the matrix <math display="inline">{X}^{'}{H}^{-1}X</math> is singular. Liu and Hu [10] and Eliot et al. [17] inquired the ridge prediction in LMM. Liu and Hu [10] are obtained <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k)</math> and <math display="inline">\tilde{\mathit{\boldsymbol{u}}}(k)</math> as
+In <math display="inline">LMM</math>, authors such as Gilmour et al. [14], Jiming and Lahiri [15] and Patel and Patel [16], considered a state where the matrix <math display="inline">{X}^{'}{H}^{-1}X</math> is singular. Liu and Hu [10] and Eliot et al. [17] inquired the ridge prediction in LMM. Liu and Hu [10] are obtained <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k)</math> and <math display="inline">\tilde{\mathit{\boldsymbol{u}}}(k)</math> as
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 72: / Line 83: @@
 |}
-where <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k)</math> and <math display="inline">\tilde{\mathit{\boldsymbol{u}}}(k)</math> are the ridge estimator of <math display="inline">\mathit{\boldsymbol{\beta }}</math> and the ridge predictor of <math display="inline">\mathit{\boldsymbol{u}},</math> respectively. Qzkale and Can [18] gave “an example from kidney failure data” to evaluate ridge estimator in linear mixed model. Kuran and Ozkale [19] obtained the mixed and stochastic restricted ridge predictors by using Gilmour approach. They introduced “stochastic linear restriction as <math display="inline">r=</math><math>R\beta +\Phi</math> where <math display="inline">r</math> is an <math display="inline">m\times 1</math> vector, <math display="inline">\mathit{\boldsymbol{R}}</math> is an <math display="inline">m\times p</math> known matrix of rank <math display="inline">m\leq p</math> and <math display="inline">\Phi</math>  is an <math display="inline">m\times 1</math> random vector that is assumed to be distributed with <math display="inline">E(\Phi )=</math><math>0</math> and <math display="inline">\mathrm{Var}\,(\Phi )={\sigma }^{2}\mathit{\boldsymbol{V}}(\mathit{\boldsymbol{v}}),</math> where <math display="inline">v</math> is <math display="inline">v\times 1</math> vector of variance parameters corresponding to <math display="inline">\Phi .</math> Also <math display="inline">\Phi</math>  and <math display="inline">\epsilon</math>  are independent”
+where <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k)</math> and <math display="inline">\tilde{\mathit{\boldsymbol{u}}}(k)</math> are the ridge estimator of <math display="inline">\mathit{\boldsymbol{\beta }}</math> and the ridge predictor of <math display="inline">\mathit{\boldsymbol{u}},</math> respectively. Özkale and Can [18] gave “an example from kidney failure data” to evaluate ridge estimator in linear mixed model. Kuran and Özkale [19] obtained the mixed and stochastic restricted ridge predictors by using Gilmour approach. They introduced “stochastic linear restriction as <math display="inline">r=</math><math>R\beta +\Phi</math> where <math display="inline">r</math> is an <math display="inline">m\times 1</math> vector, <math display="inline">\mathit{\boldsymbol{R}}</math> is an <math display="inline">m\times p</math> known matrix of rank <math display="inline">m\leq p</math> and <math display="inline">\Phi</math>  is an <math display="inline">m\times 1</math> random vector that is assumed to be distributed with <math display="inline">E(\Phi )=</math><math>0</math> and <math display="inline">\mathrm{Var}\,(\Phi )={\sigma }^{2}\mathit{\boldsymbol{V}}(\mathit{\boldsymbol{v}}),</math> where <math display="inline">v</math> is <math display="inline">v\times 1</math> vector of variance parameters corresponding to <math display="inline">\Phi .</math> Also <math display="inline">\Phi</math>  and <math display="inline">\epsilon</math>  are independent”
 Then derived the stochastic restricted estimator of <math display="inline">\beta</math>  and the stochastic restricted predictor of <math display="inline">\mathit{\boldsymbol{u}}</math> respectively, as
@@ Line 141: / Line 152: @@
 |<math>\begin{array}{lll}
 {I}_{\ast }={\sigma }^{2}{I}_{p}, & \quad {y}_{\ast }=\left[ \begin{matrix}y\\(d-k)\tilde{\beta }(k)\end{matrix}\right] ,& \quad {X}_{\ast }=\left[ \begin{matrix}X\\{I}_{p}\end{matrix}\right] ,\\
-{Z}_{\star }=\left[ \begin{matrix}Z\\0\end{matrix}\right]  ,& \quad {\epsilon }_{\ast }=\left[ \begin{matrix}\epsilon \\{\epsilon }_{0}\end{matrix}\right], &\quad {W}_{\star }=\left[ \begin{matrix}W&0\\0&{I}_{\star }\end{matrix}\right]\end{array}</math>.
+{Z}_{\star }=\left[ \begin{matrix}Z\\0\end{matrix}\right]  ,& \quad {\epsilon }_{\ast }=\left[ \begin{matrix}\epsilon \\{\epsilon }_{0}\end{matrix}\right], &\quad {W}_{\star }=\left[ \begin{matrix}W&0\\0&{I}_{\star }\end{matrix}\right]\end{array}</math>
 |}
 |}
@@ Line 198: / Line 209: @@
 |}
-By solving the Eq. (5),\tilde{u}(k,d) is
+By solving the Eq. (5),<math>\tilde{u}(k,d)</math> is
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 211: / Line 222: @@
 |}
-Using <math display="inline">\tilde{u}(k,d)</math> into the Eq. (4) we get
+Using <math display="inline">\tilde{u}(k,d)</math> into Eq. (4) we get
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 249: / Line 260: @@
 |}
-Due to <math display="inline">\left( {Z}^{'}{W}^{-1}Z+\right. </math><math>\left. {G}^{-1}\right) G{Z}^{'}={Z}^{'}{W}^{-1}ZG{Z}^{'}+{Z}^{'}={Z}^{'}{W}^{-1}\left( ZG{Z}^{'}+\right. </math><math>\left. W\right) ={Z}^{'}{W}^{-1}H,</math> we get
+Due to <math display="inline">\left( {Z}^{'}{W}^{-1}Z+ {G}^{-1}\right) G{Z}^{'}={Z}^{'}{W}^{-1}ZG{Z}^{'}+{Z}^{'}={Z}^{'}{W}^{-1}\left( ZG{Z}^{'}+ W\right) ={Z}^{'}{W}^{-1}H,</math> we get
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 261: / Line 272: @@
 |}
-Using Eq. (10), <math display="inline">\tilde{u}(k,d)</math> equals to <math display="inline">\tilde{u}(k,d)=</math><math>GZ{H}^{-1}(y-X\tilde{\beta }(k,d))</math>.
+Using Eq. (10), <math display="inline">\tilde{u}(k,d)</math> equals to <math display="inline">\tilde{u}(k,d)=GZ{H}^{-1}(y-X\tilde{\beta }(k,d))</math>.
-In section, we obtain the stochastic restricted two parameter estimation. For this, the stochastic Linear restrictions <math display="inline">r=</math><math>R\beta +\Phi</math>  can be unified to model (1) and the restriction <math display="inline">(d-</math><math>k)\tilde{\beta },(k)=\beta +{\epsilon }_{0}</math> to give
+In section, we obtain the stochastic restricted two parameter estimation. For this, the stochastic Linear restrictions <math display="inline">r=R\beta +\Phi</math>  can be unified to model (1) and the restriction <math display="inline">(d-k)\tilde{\beta },(k)=\beta +{\epsilon }_{0}</math> to give
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 270: / Line 281: @@
 {| style="text-align: center; margin:auto;"
 |-
-| <math display="inline">{\mathit{\boldsymbol{y}}}_{{r}^{\star }}={\mathit{\boldsymbol{X}}}_{{r}^{\star }}\mathit{\boldsymbol{\beta }}+</math><math>{\mathit{\boldsymbol{Z}}}_{r}\mathit{\boldsymbol{u}}+{\mathit{\boldsymbol{\epsilon }}}_{\ast ,}</math>
+| <math display="inline">{\mathit{\boldsymbol{y}}}_{{r}^{\star }}={\mathit{\boldsymbol{X}}}_{{r}^{\star }}\mathit{\boldsymbol{\beta }}+{\mathit{\boldsymbol{Z}}}_{r}\mathit{\boldsymbol{u}}+{\mathit{\boldsymbol{\epsilon }}}_{\ast ,}</math>
 |}
 | style="width: 5px;text-align: right;white-space: nowrap;" | (11)
 |}
-where <math display="inline">{y}_{{r}^{\ast }}=\left[ \begin{matrix}y\\(d-k){\tilde{\beta }}_{r}(k)\\r\end{matrix}\right] ,{X}_{{r}^{\ast }}=</math><math>\left[ \begin{matrix}X\\{I}_{p}\\R\end{matrix}\right] ,{Z}_{{r}^{\ast }}=\left[ \begin{matrix}Z\\0\\0\end{matrix}\right] ,{\epsilon }_{{r}^{\ast }}=</math><math>\left[ \begin{matrix}\epsilon \\{\epsilon }_{0}\\\Phi \end{matrix}\right]</math>  and <math display="inline">{W}_{{r}^{\star }}=</math><math>\left[ \begin{matrix}W&0&0\\0&{I}_{\ast }&0\\0&0&V\end{matrix}\right] .</math> Then, the conditional distribution of <math display="inline">{y}_{\ast }</math> given <math display="inline">\mathit{\boldsymbol{u}}</math> is <math display="inline">{\mathit{\boldsymbol{y}}}_{{r}^{\ast }}\mid \mathit{\boldsymbol{u}}\sim \mathit{\boldsymbol{N}}\left( {\mathit{\boldsymbol{X}}}_{{r}^{\ast }}\mathit{\boldsymbol{\beta }}+\right. </math><math>\left. {\mathit{\boldsymbol{Z}}}_{{r}^{\ast }}\mathit{\boldsymbol{u}},{\mathit{\boldsymbol{W}}}_{{r}^{\ast }}\right)</math>  and the logarithm joint density of <math display="inline">{y}_{r}</math> and <math display="inline">u</math> given by
+where
+{| class="formulaSCP" style="width: 100%; text-align: center;"
+|-
+|
+{| style="text-align: center; margin:auto;"
+|-
+|<math>{y}_{{r}^{\ast }}=\left[ \begin{matrix}y\\(d-k){\tilde{\beta }}_{r}(k)\\r\end{matrix}\right] ,\quad {X}_{{r}^{\ast }}=\left[ \begin{matrix}X\\{I}_{p}\\R\end{matrix}\right] ,\quad {Z}_{{r}^{\ast }}=\left[ \begin{matrix}Z\\0\\0\end{matrix}\right] ,\quad{\epsilon }_{{r}^{\ast }}=\left[ \begin{matrix}\epsilon \\{\epsilon }_{0}\\\Phi \end{matrix}\right],  \quad{W}_{{r}^{\star }}=\left[ \begin{matrix}W&0&0\\0&{I}_{\ast }&0\\0&0&V\end{matrix}\right]</math>
+|}
+|}
+Then, the conditional distribution of <math display="inline">{y}_{\ast }</math> given <math display="inline">\mathit{\boldsymbol{u}}</math> is <math display="inline">{\mathit{\boldsymbol{y}}}_{{r}^{\ast }}\mid \mathit{\boldsymbol{u}}\sim \mathit{\boldsymbol{N}}\left( {\mathit{\boldsymbol{X}}}_{{r}^{\ast }}\mathit{\boldsymbol{\beta }}+ {\mathit{\boldsymbol{Z}}}_{{r}^{\ast }}\mathit{\boldsymbol{u}},{\mathit{\boldsymbol{W}}}_{{r}^{\ast }}\right)</math>  and the logarithm joint density of <math display="inline">{y}_{r}</math> and <math display="inline">u</math> given by
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 284: / Line 306: @@
-Substituting <math display="inline">{y}_{r},{X}_{{r}^{\ast }}{Z}_{{r}^{\ast }}</math> and <math display="inline">{W}_{{r}^{+}}</math> to <math display="inline">{\left( {y}_{{r}^{\ast }}-{X}_{{r}^{\ast }}\beta -{Z}_{{r}^{\ast }}u\right) }^{'}{W}_{{\gamma }^{\ast }}^{-1}\left( {y}_{{r}^{\ast }}-\right. </math><math>\left. {X}_{{r}^{\ast }}\beta -{Z}_{{r}^{\ast }}u\right) ,</math> the penalized log-likelihood function is obtained as follows:
+Substituting <math display="inline">{y}_{r},{X}_{{r}^{\ast }}{Z}_{{r}^{\ast }}</math> and <math display="inline">{W}_{{r}^{+}}</math> to <math display="inline">{\left( {y}_{{r}^{\ast }}-{X}_{{r}^{\ast }}\beta -{Z}_{{r}^{\ast }}u\right) }^{'}{W}_{{\gamma }^{\ast }}^{-1}\left( {y}_{{r}^{\ast }}- {X}_{{r}^{\ast }}\beta -{Z}_{{r}^{\ast }}u\right)</math>, the penalized log-likelihood function is obtained as follows:
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 345: / Line 367: @@
 ==3. Estimation of variance parameters==
-In linear mixed models, the variance parameter within <math display="inline">G</math> and <math display="inline">W</math> are often unknown that several methods have been proposed by Searle <math display="inline">[16,20-</math><math>22]</math> to estimate them. In this section, we estimate the variance parameters using the ML method. The marginal distribution of <math display="inline">{y}_{\ast }</math> is <math display="inline">N\left( \mathit{\boldsymbol{X}}\cdot \mathit{\boldsymbol{\beta }},{\sigma }^{2}{\mathit{\boldsymbol{H}}}_{\ast }\right) ,</math> therefore we can write the marginal log-likelihood function of <math display="inline">\mathit{\boldsymbol{y}}</math>
+In linear mixed models, the variance parameter within <math display="inline">G</math> and <math display="inline">W</math> are often unknown that several methods have been proposed by [16,20-22]
+to estimate them. In this section, we estimate the variance parameters using the ML method. The marginal distribution of <math display="inline">{y}_{\ast }</math> is <math display="inline">N\left( \mathit{\boldsymbol{X}}\cdot \mathit{\boldsymbol{\beta }},{\sigma }^{2}{\mathit{\boldsymbol{H}}}_{\ast }\right)</math>, therefore we can write the marginal log-likelihood function of <math display="inline">\mathit{\boldsymbol{y}}</math>
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@@ Line 352: / Line 375: @@
 {| style="text-align: center; margin:auto;width: 100%;"
 |-
-| style="text-align: center;" | <math>{l}_{ML}\left( \mathit{\boldsymbol{\beta }},\mathit{\boldsymbol{\phi }},{\mathit{\boldsymbol{y}}}_{\ast }\right) =</math><math>\frac{-1}{2{\sigma }^{2}}\left\{ {\left( {\mathit{\boldsymbol{y}}}_{\ast }-{\mathit{\boldsymbol{X}}}_{\ast }\mathit{\boldsymbol{\beta }}\right) }^{'}{\mathit{\boldsymbol{H}}}_{\ast }^{-1}\left( {\mathit{\boldsymbol{y}}}_{\ast }-\right. \right. </math><math>\left. \left. {\mathit{\boldsymbol{X}}}_{\ast }\mathit{\boldsymbol{\beta }}\right) \right\} -</math><math>\frac{n+p}{2}\mathrm{ln}\,\left( 2\pi {\mathit{\boldsymbol{\sigma }}}^{2}\right) -</math><math>\frac{1}{2}\mathrm{ln}\,\left| {\mathit{\boldsymbol{H}}}_{\ast }\right| </math>
+| style="text-align: center;" | <math>{l}_{ML}\left( \mathit{\boldsymbol{\beta }},\mathit{\boldsymbol{\phi }},{\mathit{\boldsymbol{y}}}_{\ast }\right) =</math><math>\displaystyle\frac{-1}{2{\sigma }^{2}}\left\{ {\left( {\mathit{\boldsymbol{y}}}_{\ast }-{\mathit{\boldsymbol{X}}}_{\ast }\mathit{\boldsymbol{\beta }}\right) }^{'}{\mathit{\boldsymbol{H}}}_{\ast }^{-1}\left( {\mathit{\boldsymbol{y}}}_{\ast }-\right. \right. </math><math>\left. \left. {\mathit{\boldsymbol{X}}}_{\ast }\mathit{\boldsymbol{\beta }}\right) \right\} -</math><math>\frac{n+p}{2}\mathrm{ln}\,\left( 2\pi {\mathit{\boldsymbol{\sigma }}}^{2}\right) -</math><math> \displaystyle\frac{1}{2}\mathrm{ln}\,\left| {\mathit{\boldsymbol{H}}}_{\ast }\right| </math>
 |}
 | style="width: 5px;text-align: right;white-space: nowrap;" |(17)
 |}
-where <math display="inline">\phi ={\left( {\mathit{\boldsymbol{K}}}^{'},{\sigma }^{2}\right) }^{'},\mathit{\boldsymbol{k}}=</math><math>{\left( {\zeta }^{'},{\xi }^{'}\right) }^{'}</math> and are <math display="inline">\left( {r}_{1}+\right. </math><math>\left. {r}_{2}+1\right) \times 1</math> and <math display="inline">\left( {r}_{1}+\right. </math><math>\left. {r}_{2}\right) \times 1</math> vectors of unknown parameters, respectively. Differentiating the Eq. (17) with respect to <math display="inline">\beta ,{\sigma }^{2}</math> and <math display="inline">{\kappa }_{j}=</math><math>1,\ldots ,{r}_{1}+{r}_{2}</math> the partial derivatives is obtained as
+where <math display="inline">\phi ={\left( {\mathit{\boldsymbol{K}}}^{'},{\sigma }^{2}\right) }^{'},\mathit{\boldsymbol{k}}={\left( {\zeta }^{'},{\xi }^{'}\right) }^{'}</math> and  <math display="inline">\left( {r}_{1}+{r}_{2}+1\right) \times 1</math> and <math display="inline">\left( {r}_{1}+ {r}_{2}\right) \times 1</math> are vectors of unknown parameters, respectively. Differentiating the Eq. (17) with respect to <math display="inline">\beta ,{\sigma }^{2}</math> and <math display="inline">{\kappa }_{j}=</math><math>1,\ldots ,{r}_{1}+{r}_{2}</math> the partial derivatives is obtained as
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@@ Line 364: / Line 387: @@
 {| style="text-align: center; margin:auto;width: 100%;"
 |-
-| style="text-align: center;" | <math>\frac{\partial {l}_{ML}\left( \mathit{\boldsymbol{\beta }},\mathit{\boldsymbol{\phi }};{\mathit{\boldsymbol{y}}}_{\ast }\right) }{\partial \mathit{\boldsymbol{\beta }}}=</math><math>\frac{-1}{{\sigma }^{2}}\left( {\mathit{\boldsymbol{X}}}_{\ast }^{'}{\mathit{\boldsymbol{H}}}_{\ast }^{-1}{\mathit{\boldsymbol{X}}}_{\ast }\mathit{\boldsymbol{\beta }}-\right. </math><math>\left. {\mathit{\boldsymbol{X}}}_{\ast }^{'}{\mathit{\boldsymbol{H}}}_{\ast }^{-1}{\mathit{\boldsymbol{y}}}_{\ast }\right) ,</math>
+| style="text-align: center;" | <math>\displaystyle\frac{\partial {l}_{ML}\left( \mathit{\boldsymbol{\beta }},\mathit{\boldsymbol{\phi }};{\mathit{\boldsymbol{y}}}_{\ast }\right) }{\partial \mathit{\boldsymbol{\beta }}}=</math><math>\displaystyle\frac{-1}{{\sigma }^{2}}\left( {\mathit{\boldsymbol{X}}}_{\ast }^{'}{\mathit{\boldsymbol{H}}}_{\ast }^{-1}{\mathit{\boldsymbol{X}}}_{\ast }\mathit{\boldsymbol{\beta }}-\right. </math><math>\left. {\mathit{\boldsymbol{X}}}_{\ast }^{'}{\mathit{\boldsymbol{H}}}_{\ast }^{-1}{\mathit{\boldsymbol{y}}}_{\ast }\right) ,</math>
 |}
 | style="width: 5px;text-align: right;white-space: nowrap;" |(18)
@@ Line 374: / Line 397: @@
 {| style="text-align: center; margin:auto;width: 100%;"
 |-
-| style="text-align: center;" |<math>\frac{\partial {l}_{ML}\left( \mathit{\boldsymbol{\beta }},\mathit{\boldsymbol{\phi }};{\mathit{\boldsymbol{y}}}_{\ast }\right) }{\partial {\sigma }^{2}}=</math><math>\frac{-(n+p)}{2{\sigma }^{2}}+\frac{{\left( {\mathit{\boldsymbol{y}}}_{\ast }-\mathit{\boldsymbol{X}}\cdot \mathit{\boldsymbol{\beta }}\right) }^{'}{\mathit{\boldsymbol{H}}}_{\cdot }^{-1}\left( {\mathit{\boldsymbol{y}}}_{\ast }-\mathit{\boldsymbol{X}}\cdot \mathit{\boldsymbol{\beta }}\right) }{2{\sigma }^{4}},</math>
+| style="text-align: center;" |<math>\displaystyle\frac{\partial {l}_{ML}\left( \mathit{\boldsymbol{\beta }},\mathit{\boldsymbol{\phi }};{\mathit{\boldsymbol{y}}}_{\ast }\right) }{\partial {\sigma }^{2}}=</math><math>\displaystyle\frac{-(n+p)}{2{\sigma }^{2}}+\displaystyle\frac{{\left( {\mathit{\boldsymbol{y}}}_{\ast }-\mathit{\boldsymbol{X}}\cdot \mathit{\boldsymbol{\beta }}\right) }^{'}{\mathit{\boldsymbol{H}}}_{\cdot }^{-1}\left( {\mathit{\boldsymbol{y}}}_{\ast }-\mathit{\boldsymbol{X}}\cdot \mathit{\boldsymbol{\beta }}\right) }{2{\sigma }^{4}},</math>
 |}
 | style="width: 5px;text-align: right;white-space: nowrap;" |(19)
@@ Line 384: / Line 407: @@
 {| style="text-align: center; margin:auto;width: 100%;"
 |-
-| style="text-align: center;" |<math>\frac{\partial {l}_{ML}\left( \mathit{\boldsymbol{\beta }},\mathit{\boldsymbol{\phi }};{\mathit{\boldsymbol{y}}}_{\ast }\right) }{\partial {\kappa }_{i}}=</math><math>\frac{-1}{2}\mathrm{tr}\,\left( {\mathit{\boldsymbol{H}}}_{\ast }^{-1}{\dot{\mathit{\boldsymbol{H}}}}_{{\ast }_{j}}\right) +</math><math>\frac{{\left( {\mathit{\boldsymbol{y}}}_{\ast }-{\mathit{\boldsymbol{X}}}_{\ast }\mathit{\boldsymbol{\beta }}\right) }^{'}{\mathit{\boldsymbol{H}}}_{\ast }^{-1}{\dot{\mathit{\boldsymbol{H}}}}_{\ast }{\mathit{\boldsymbol{H}}}_{\ast }^{-1}\left( {\mathit{\boldsymbol{y}}}_{\ast }-\mathit{\boldsymbol{X}}\cdot \mathit{\boldsymbol{\beta }}\right) }{2{\sigma }^{2}} </math>
+| style="text-align: center;" |<math>\displaystyle\frac{\partial {l}_{ML}\left( \mathit{\boldsymbol{\beta }},\mathit{\boldsymbol{\phi }};{\mathit{\boldsymbol{y}}}_{\ast }\right) }{\partial {\kappa }_{i}}=</math><math>\displaystyle\frac{-1}{2}\mathrm{tr}\,\left( {\mathit{\boldsymbol{H}}}_{\ast }^{-1}{\dot{\mathit{\boldsymbol{H}}}}_{{\ast }_{j}}\right) +</math><math>\displaystyle\frac{{\left( {\mathit{\boldsymbol{y}}}_{\ast }-{\mathit{\boldsymbol{X}}}_{\ast }\mathit{\boldsymbol{\beta }}\right) }^{'}{\mathit{\boldsymbol{H}}}_{\ast }^{-1}{\dot{\mathit{\boldsymbol{H}}}}_{\ast }{\mathit{\boldsymbol{H}}}_{\ast }^{-1}\left( {\mathit{\boldsymbol{y}}}_{\ast }-\mathit{\boldsymbol{X}}\cdot \mathit{\boldsymbol{\beta }}\right) }{2{\sigma }^{2}} </math>
 |}
 | style="width: 5px;text-align: right;white-space: nowrap;" |(20)
@@ Line 416: / Line 439: @@
 {| style="text-align: center; margin:auto;width: 100%;"
 |-
-| style="text-align: center;" |<math>(\mathrm{tr}\,\left( {\tilde{H}}_{\ast }^{-1}{\tilde{H}}_{\ast j}\right) =\frac{{\left( {y}_{\star }-{X}_{\ast }\tilde{\beta }\left( k,d\right) \right) }^{'}{\tilde{H}}_{\ast }^{-1}{\tilde{H}}_{\ast j}{\tilde{H}}_{\ast }^{-1}\left( {y}_{\star }-{X}_{\star }\tilde{\beta }\left( k,d\right) \right) }{{\tilde{\sigma }}^{2}\left( k,d\right) }</math>
+| style="text-align: center;" |<math>(\mathrm{tr}\,\left( {\tilde{H}}_{\ast }^{-1}{\tilde{H}}_{\ast j}\right) =\displaystyle\frac{{\left( {y}_{\star }-{X}_{\ast }\tilde{\beta }\left( k,d\right) \right) }^{'}{\tilde{H}}_{\ast }^{-1}{\tilde{H}}_{\ast j}{\tilde{H}}_{\ast }^{-1}\left( {y}_{\star }-{X}_{\star }\tilde{\beta }\left( k,d\right) \right) }{{\tilde{\sigma }}^{2}\left( k,d\right) }</math>
 |}
 | style="width: 5px;text-align: right;white-space: nowrap;" |(23)
@@ Line 496: / Line 519: @@
-===4.1. Comparison the Estimator  <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}\boldsymbol{(}\mathit{\boldsymbol{k}}\boldsymbol{,}\mathit{\boldsymbol{d}}\boldsymbol{)}</math>''' with ''' <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math>===
+===4.1 Comparison the Estimator ''&beta;&#771;''(''k'',''d'') with  ''&beta;&#771;''===
 The <math display="inline">MSEM</math> of <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math> is <math display="inline">\mathrm{MSEM}\,(\tilde{\mathit{\boldsymbol{\beta }}})=</math><math>{\sigma }^{2}{\mathit{\boldsymbol{A}}}^{-1},</math> where <math display="inline">{\mathit{\boldsymbol{A}}}_{1}=</math><math>\left( \mathit{\boldsymbol{X}}{\mathit{\boldsymbol{H}}}^{-1}\mathit{\boldsymbol{X}}\right) ,</math> and the <math display="inline">MSEM</math> of <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> is
@@ Line 516: / Line 539: @@
 According to Farebrother <math display="inline">(1976),</math> if <math display="inline">{\sigma }^{2}\left( {A}_{1}^{-1}-\right. </math><math>\left. {T}_{1}{A}_{1}{T}_{1}\right) >0,</math> then the necessary and sufficient condition for <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> to be superior to <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math> is <math display="inline">{\mathit{\boldsymbol{\beta }}}^{'}{\left( {\mathit{\boldsymbol{T}}}_{1}{\mathit{\boldsymbol{A}}}_{1}-{\mathit{\boldsymbol{I}}}_{p}\right) }^{'}{\left[ {\sigma }^{2}\left( {\mathit{\boldsymbol{A}}}_{1}^{-1}-{\mathit{\boldsymbol{T}}}_{1}{\mathit{\boldsymbol{A}}}_{1}{\mathit{\boldsymbol{T}}}_{1}\right) \right] }^{-1}\left( {\mathit{\boldsymbol{T}}}_{1}{\mathit{\boldsymbol{A}}}_{1}-\right. </math><math>\left. {\mathit{\boldsymbol{I}}}_{p}\right) \mathit{\boldsymbol{\beta }}<1</math>.
-==5. Selection of parameters  <math display="inline">\mathit{\boldsymbol{k}}</math> and  <math display="inline">\mathit{\boldsymbol{d}}</math>==
+==5. Selection of parameters '''''k''''' and '''''d'''''==
-In the linear regression model, choosing the parameter <math display="inline">k</math> is important so many statisticians were suggested several methods for obtaining this parameter. These methods were proposed by many researchers [23-29] and others. According to Ozkale and Can [18], "we rewrite model (1) in the form of a marginal model in which random effects are not explicitly defined:
+In the linear regression model, choosing the parameter <math display="inline">k</math> is important so many statisticians were suggested several methods for obtaining this parameter. These methods were proposed by many researchers [23-29] and others. According to Ozkale and Can [18], we rewrite model (1) in the form of a marginal model in which random effects are not explicitly defined:
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 547: / Line 570: @@
 |}
-Notice that <math display="inline">\mathrm{MSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}(k,d),\mathit{\boldsymbol{\beta }})=\mathrm{MSE}\,(\tilde{\gamma }(k,d),\gamma )=\mathrm{tr}\,[\mathrm{MSEM}\,(\tilde{\gamma }(k,d),\gamma )].</math> Therefore, getting <math display="inline">\frac{\partial \mathrm{MSE}\,(\tilde{\gamma }(k,d),\gamma )}{\partial k}=</math><math>0,</math> we obtain <math display="inline">k=\frac{{\sigma }^{2}\left( {\lambda }_{i}+d\right) -{\lambda }_{i}{\gamma }_{i}^{2}(1-d)}{{\gamma }_{i}^{2}\left( {\lambda }_{j}+1\right) }.</math> Since the optimal <math display="inline">k</math> depends on unknown <math display="inline">\gamma</math>  and <math display="inline">{\sigma }^{2},</math> then according Hoerl and Kennard [9] we can get the estimate of <math display="inline">k</math> by substituting <math display="inline">\tilde{\gamma }</math> and <math display="inline">{\tilde{\sigma }}^{2}</math> as follows:
+Notice that <math display="inline">\mathrm{MSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}(k,d),\mathit{\boldsymbol{\beta }})=\mathrm{MSE}\,(\tilde{\gamma }(k,d),\gamma )=\mathrm{tr}\,[\mathrm{MSEM}\,(\tilde{\gamma }(k,d),\gamma )].</math> Therefore, getting <math display="inline">\displaystyle\frac{\partial \mathrm{MSE}\,(\tilde{\gamma }(k,d),\gamma )}{\partial k}=</math><math>0,</math> we obtain <math display="inline">k=\displaystyle\frac{{\sigma }^{2}\left( {\lambda }_{i}+d\right) -{\lambda }_{i}{\gamma }_{i}^{2}(1-d)}{{\gamma }_{i}^{2}\left( {\lambda }_{j}+1\right) }.</math> Since the optimal <math display="inline">k</math> depends on unknown <math display="inline">\gamma</math>  and <math display="inline">{\sigma }^{2},</math> then according Hoerl and Kennard [9] we can get the estimate of <math display="inline">k</math> by substituting <math display="inline">\tilde{\gamma }</math> and <math display="inline">{\tilde{\sigma }}^{2}</math> as follows:
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 554: / Line 577: @@
 {| style="text-align: center; margin:auto;"
 |-
-| <math display="inline">\tilde{k}=\frac{{\tilde{\sigma }}^{2}\left( {\lambda }_{i}+d\right) -{\lambda }_{i}{\tilde{\gamma }}_{i}^{2}(1-d)}{{\tilde{\gamma }}_{i}^{2}\left( {\lambda }_{i}+1\right) }</math>
+| <math display="inline">\tilde{k}=\displaystyle\frac{{\tilde{\sigma }}^{2}\left( {\lambda }_{i}+d\right) -{\lambda }_{i}{\tilde{\gamma }}_{i}^{2}(1-d)}{{\tilde{\gamma }}_{i}^{2}\left( {\lambda }_{i}+1\right) }</math>
 |}
 | style="width: 5px;text-align: right;white-space: nowrap;" | (27)
@@ Line 561: / Line 584: @@
 where <math display="inline">\tilde{\gamma }</math> and <math display="inline">{\tilde{\sigma }}^{2}</math> are the unbiased estimators <math display="inline">\mathit{\boldsymbol{\gamma }}</math> and <math display="inline">{\sigma }^{2}</math>. According to the estimator of <math display="inline">k,</math> which Kibria [25] and Hoerl and Kennard [9] proposed, the harmonic mean value of <math display="inline">k</math> in (27) is
-Now, let <math display="inline">k</math> fixed, and we get the optimal value <math display="inline">d</math> by minimizing <math display="inline">\mathrm{MSE}\,(\tilde{\gamma }(k,d),\gamma )</math>. Therefore getting <math display="inline">\frac{\partial \mathrm{MSE}\,(\tilde{\gamma }(k,d),\gamma )}{\partial d}=</math><math>0,</math>
+Now, let <math display="inline">k</math> fixed, and we get the optimal value <math display="inline">d</math> by minimizing <math display="inline">\mathrm{MSE}\,(\tilde{\gamma }(k,d),\gamma )</math>. Therefore getting <math display="inline">\displaystyle\frac{\partial \mathrm{MSE}\,(\tilde{\gamma }(k,d),\gamma )}{\partial d}=</math><math>0,</math>
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 568: / Line 591: @@
 {| style="text-align: center; margin:auto;"
 |-
-| <math display="inline">{\tilde{d}}_{opt}=\frac{\sum _{i=1}^{p}\frac{[\left( \left( k+1\right) {\lambda }_{i}+k\right) {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}-\, {\lambda }_{i}^{2}{\tilde{\sigma }}^{2}\, ]}{[{(\, {\lambda }_{i}+k)}^{2}\ast {({\lambda }_{i}\, +1)}^{2}]}}{\sum _{i=1}^{p}\frac{[\left( {\tilde{\sigma }}^{2}\, +\, \, {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) {\lambda }_{i}]}{[{({\lambda }_{i}+k)}^{2}\ast {({\lambda }_{i}+1)}^{2}]}}</math>
+| <math display="inline">{\tilde{d}}_{opt}=\displaystyle\frac{\sum _{i=1}^{p}\displaystyle\frac{[\left( \left( k+1\right) {\lambda }_{i}+k\right) {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}-\, {\lambda }_{i}^{2}{\tilde{\sigma }}^{2}\, ]}{[{(\, {\lambda }_{i}+k)}^{2}\ast {({\lambda }_{i}\, +1)}^{2}]}}{\sum _{i=1}^{p}\displaystyle\frac{[\left( {\tilde{\sigma }}^{2}\, +\, \, {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) {\lambda }_{i}]}{[{({\lambda }_{i}+k)}^{2}\ast {({\lambda }_{i}+1)}^{2}]}}</math>
 |}
 | style="width: 5px;text-align: right;white-space: nowrap;" | (28)
@@ Line 578: / Line 601: @@
 '''Theorem 5.1'''
-If <math display="inline">\tilde{d}>max\left\{ \frac{1-{\tilde{\sigma }}^{2}{\tilde{\gamma }}_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) }\right\}</math>,
+If <math display="inline">\tilde{d}>max\left\{ \displaystyle\frac{1-{\tilde{\sigma }}^{2}{\tilde{\gamma }}_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) }\right\}</math>,
 for all <math display="inline">i,</math> then <math display="inline">{\tilde{k}}_{HM}</math> are always positive.
 '''Proof.'''
-If <math display="inline">\frac{{\sigma }^{2}\left( {\lambda }_{i}+d\right) -{\lambda }_{i}{\gamma }_{i}^{2}(1-d)}{{\gamma }_{i}^{2}\left( {\lambda }_{i}+1\right) }>0</math>, then the values of <math display="inline">k</math> are positive. Since <math display="inline">{\gamma }_{i}^{2}\left( {\lambda }_{i}+1\right) >0</math> and <math display="inline">{\sigma }^{2}\left( {\lambda }_{i}+\right. </math><math>\left. d\right) -{\lambda }_{i}{\gamma }_{i}^{2}(1-d)</math> must be positive for all <math display="inline">i</math>. Then we get
+If <math display="inline">\displaystyle\frac{{\sigma }^{2}\left( {\lambda }_{i}+d\right) -{\lambda }_{i}{\gamma }_{i}^{2}(1-d)}{{\gamma }_{i}^{2}\left( {\lambda }_{i}+1\right) }>0</math>, then the values of <math display="inline">k</math> are positive. Since <math display="inline">{\gamma }_{i}^{2}\left( {\lambda }_{i}+1\right) >0</math> and <math display="inline">{\sigma }^{2}\left( {\lambda }_{i}+\right. </math><math>\left. d\right) -{\lambda }_{i}{\gamma }_{i}^{2}(1-d)</math> must be positive for all <math display="inline">i</math>. Then we get
-<math display="inline">d>\frac{1-{\sigma }^{2}/{\gamma }_{i}^{2}}{1+{\sigma }^{2}/\left( {\lambda }_{i}{\gamma }_{i}^{2}\right) }</math> and because depends on the unknown parameters <math display="inline">{\gamma }_{i}^{2}</math> and <math display="inline">{\sigma }^{2},</math> so their unbiased estimators are replaced. Therefore <math display="inline">{\tilde{k}}_{HM}</math> is always positive if <math display="inline">\tilde{d}</math> is selected as <math display="inline">\tilde{d}>max\left\{ \frac{1-{\tilde{\sigma }}^{2}{\tilde{\gamma }}_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{j}{\tilde{\gamma }}_{i}^{2}\right) }\right\}</math>.
+<math display="inline">d>\displaystyle\frac{1-{\sigma }^{2}/{\gamma }_{i}^{2}}{1+{\sigma }^{2}/\left( {\lambda }_{i}{\gamma }_{i}^{2}\right) }</math> and because depends on the unknown parameters <math display="inline">{\gamma }_{i}^{2}</math> and <math display="inline">{\sigma }^{2},</math> so their unbiased estimators are replaced. Therefore <math display="inline">{\tilde{k}}_{HM}</math> is always positive if <math display="inline">\tilde{d}</math> is selected as <math display="inline">\tilde{d}>max\left\{ \displaystyle\frac{1-{\tilde{\sigma }}^{2}{\tilde{\gamma }}_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{j}{\tilde{\gamma }}_{i}^{2}\right) }\right\}</math>.
-Note that <math display="inline">\frac{1-{\tilde{\sigma }}^{2}/{\gamma }_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) }</math> is always less than one and since <math display="inline">d</math> must be between zero and one, we consider the inequality <math display="inline">\tilde{d}>max\left\{ \frac{1-{\tilde{\sigma }}^{2}{\tilde{\gamma }}_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) }\right\}</math> as follows
+Note that <math display="inline">\displaystyle\frac{1-{\tilde{\sigma }}^{2}/{\gamma }_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) }</math> is always less than one and since <math display="inline">d</math> must be between zero and one, we consider the inequality <math display="inline">\tilde{d}>max\left\{\displaystyle \frac{1-{\tilde{\sigma }}^{2}{\tilde{\gamma }}_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) }\right\}</math> as follows
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 593: / Line 616: @@
 {| style="text-align: center; margin:auto;"
 |-
-| <math display="inline">max\left\{ \frac{1-{\tilde{\sigma }}^{2}{\tilde{\gamma }}_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) },o\right\} <\tilde{d}<1</math>
+| <math display="inline">max\left\{\displaystyle \frac{1-{\tilde{\sigma }}^{2}{\tilde{\gamma }}_{i}^{2}}{1+{\tilde{\sigma }}^{2}/\left( {\lambda }_{i}{\tilde{\gamma }}_{i}^{2}\right) },o\right\} <\tilde{d}<1</math>
 |}
 | style="width: 5px;text-align: right;white-space: nowrap;" | (29)
@@ Line 615: / Line 638: @@
 |}
+where <math display="inline">{w}_{ijc}</math> independent standard normal are pseudo-random numbers and <math display="inline">{\rho }^{2}</math> is the correlation between any two fixed effects. Three different sets of <math display="inline">{\rho }^{2}</math> were considered as 0.75,0.85 and <math display="inline">0.95.</math> The <math display="inline">\mathit{\boldsymbol{Z}}</math> matrix is produced in a completely randomized design. Observation on responses are then determined by
-Where <math display="inline">{w}_{ijc}</math> independent standard normal are pseudo-random numbers and <math display="inline">{\rho }^{2}</math> is the correlation between any two fixed effects. Three different sets of <math display="inline">{\rho }^{2}</math> were considered as 0.75,0.85 and <math display="inline">0.95.</math> The <math display="inline">\mathit{\boldsymbol{Z}}</math> matrix is produced in a completely randomized design. Observation on responses are then determined by
 {| class="formulaSCP" style="width: 100%; text-align: center;"
@@ Line 629: / Line 651: @@
-We consider two designs that in the first design <math display="inline">{n}_{i}=</math><math>3</math> and in the second design <math display="inline">{n}_{i}=7</math>. Also, the same value <math display="inline">t=</math><math>9,p=4</math> and <math display="inline">q=9</math> are taken in both designs. Following Ozcale and Can (2017) “The <math display="inline">\mathit{\boldsymbol{\beta }}</math> vector was chosen as the eigenvector corresponding to the largest eigenvalue of the <math display="inline">{\boldsymbol{X}}^{'}{\mathit{\boldsymbol{H}}}^{-1}\mathit{\boldsymbol{X}}</math> matrix”. The variances matrix of random effects <math display="inline">{u}_{i}</math> and <math display="inline">{\epsilon }_{ij}</math> are <math display="inline">\mathit{\boldsymbol{G}}=</math><math>{\sigma }_{1}^{2}{\mathit{\boldsymbol{I}}}_{q}</math> and <math display="inline">\mathit{\boldsymbol{W}}=</math><math>{\sigma }^{2}{\mathit{\boldsymbol{I}}}_{a}</math><br/>respectively. They <math display="inline">{u}_{i}</math> are generated from the normal distribution <math display="inline">N(0,G)</math>. We are considered <math display="inline">{\sigma }^{2}=</math><math>0.5,1</math> and <math display="inline">{\sigma }_{1}^{2}=0.5,1</math>.The trial was replicated 1000 times by generating <math display="inline">{u}_{i}</math> and <math display="inline">{\epsilon }_{ij}.</math> For each simulated data set derived <math display="inline">{\tilde{k}}_{HM}</math> and <math display="inline">{\tilde{d}}_{opt~},</math> and then the estimated mean squared error (EMSE) calculated as calculated the relative mean square (RMSE) as
+We consider two designs that in the first design <math display="inline">{n}_{i}=</math><math>3</math> and in the second design <math display="inline">{n}_{i}=7</math>. Also, the same value <math display="inline">t=</math><math>9,p=4</math> and <math display="inline">q=9</math> are taken in both designs. Following Ozcale and Can [18], the <math display="inline">\mathit{\boldsymbol{\beta }}</math> vector was chosen as the eigenvector corresponding to the largest eigenvalue of the <math display="inline">{\boldsymbol{X}}^{'}{\mathit{\boldsymbol{H}}}^{-1}\mathit{\boldsymbol{X}}</math> matrix”. The variances matrix of random effects <math display="inline">{u}_{i}</math> and <math display="inline">{\epsilon }_{ij}</math> are <math display="inline">\mathit{\boldsymbol{G}}=</math><math>{\sigma }_{1}^{2}{\mathit{\boldsymbol{I}}}_{q}</math> and <math display="inline">\mathit{\boldsymbol{W}}=</math><math>{\sigma }^{2}{\mathit{\boldsymbol{I}}}_{a}</math>, respectively. They <math display="inline">{u}_{i}</math> are generated from the normal distribution <math display="inline">N(0,G)</math>. We are considered <math display="inline">{\sigma }^{2}=</math><math>0.5,1</math> and <math display="inline">{\sigma }_{1}^{2}=0.5,1</math>.The trial was replicated 1000 times by generating <math display="inline">{u}_{i}</math> and <math display="inline">{\epsilon }_{ij}.</math> For each simulated data set derived <math display="inline">{\tilde{k}}_{HM}</math> and <math display="inline">{\tilde{d}}_{opt~},</math> and then the estimated mean squared error (EMSE) calculated as calculated the relative mean square (RMSE) as
 {| class="formulaSCP" style="width: 100%; text-align: center;"
 |-
-| <math>\mathrm{RMSE}\,\left( \tilde{\mathit{\boldsymbol{\beta }}}:{\tilde{\mathit{\boldsymbol{\beta }}}}^{\ast }\right) =</math><math>\frac{\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}})}{\mathrm{EMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}^{\ast }\right) }<br/></math>
+| <math>\mathrm{RMSE}\,\left( \tilde{\mathit{\boldsymbol{\beta }}}:{\tilde{\mathit{\boldsymbol{\beta }}}}^{\ast }\right) =</math><math>\displaystyle\frac{\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}})}{\mathrm{EMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}^{\ast }\right) }</math>
 |}
-when <math display="inline">RMSE</math> is greater than one, it indicates that the estimator <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}^{\ast }</math> superior to the estimator <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math>. For the stochastic linear restriction <math display="inline">\mathit{\boldsymbol{r}}=</math><math>\mathit{\boldsymbol{R\beta }}+\Phi ,</math> the matrix <math display="inline">\mathit{\boldsymbol{R}}</math> is <math display="inline">m\times p</math> and generated from the normal distribution <math display="inline">N(0,1)</math> and the matrix <math display="inline">\Phi</math>  is generated from the normal distribution <math display="inline">N(0,\mathit{\boldsymbol{V}})</math> where <math display="inline">\mathit{\boldsymbol{V}}</math> is taken as <math display="inline">=</math><math>\mathrm{diag}\,\left( {\sigma }^{2}{\mathit{\boldsymbol{I}}}_{m}\right.</math>  ) with <math display="inline">m=</math><math>2</math>. In tables 1 , we obtain the values of EMSE and RMSE for <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}},\tilde{\mathit{\boldsymbol{\beta }}}(k,d),{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}</math> and <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d).</math> We have the following results for Table 1:
+when <math display="inline">RMSE</math> is greater than one, it indicates that the estimator <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}^{\ast }</math> superior to the estimator <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math>. For the stochastic linear restriction <math display="inline">\mathit{\boldsymbol{r}}=</math><math>\mathit{\boldsymbol{R\beta }}+\Phi ,</math> the matrix <math display="inline">\mathit{\boldsymbol{R}}</math> is <math display="inline">m\times p</math> and generated from the normal distribution <math display="inline">N(0,1)</math> and the matrix <math display="inline">\Phi</math>  is generated from the normal distribution <math display="inline">N(0,\mathit{\boldsymbol{V}})</math> where <math display="inline">\mathit{\boldsymbol{V}}</math> is taken as <math display="inline">=</math><math>\mathrm{diag}\,\left( {\sigma }^{2}{\mathit{\boldsymbol{I}}}_{m}\right)</math>) with <math display="inline">m=</math><math>2</math>. In [[#tab-1|Table 1]], we obtain the values of EMSE and RMSE for <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}},\tilde{\mathit{\boldsymbol{\beta }}}(k,d),{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}</math> and <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)</math>. We have the following results for [[#tab-1|Table 1]]:
 (i) In the whole table, the EMSE values of <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> is less than <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math>. Also, the EMSE values of <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)</math> is less than <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}</math>. In general, the EMSE values of <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)</math> is less than all estimators.
@@ Line 642: / Line 666: @@
 (iii) As <math display="inline">{\rho }^{2}</math> increases, difference between the EMSE values of the two parameter estimators and the EMSE values of the best linear unbiased estimators increase. This implies an increase in the improvement of the two-parameter estimators.
-Table 1. Estimated <math display="inline">MSE</math> and SMSE values with <math display="inline">{\tilde{k}}_{HM},{\tilde{d}}_{opt~}</math> and <math display="inline">t=</math><math>9</math>
+<div class="center" style="font-size: 75%;">'''Table 1'''. Estimated <math display="inline">MSE</math> and SMSE values with <math display="inline">{\tilde{k}}_{HM},{\tilde{d}}_{opt~}</math> and <math display="inline">t=</math><math>9</math></div>
-{| style="width: 100%;border-collapse: collapse;"
+<div id='tab-1'></div>
-|-
+{| class="wikitable" style="margin: 1em auto 0.1em auto;border-collapse: collapse;font-size:85%;width:auto;"
-|  style="border: 1pt solid black;vertical-align: top;"|p=0.75
+|-style="text-align:center"
-|  colspan='2'  style="border: 1pt solid black;vertical-align: top;"|<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(0.5,0.5)</math>
+! <math>p=0.75</math> !!  colspan='2'  |<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(0.5,0.5)</math> !!   colspan='2'  | <math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(1,1)</math>
-|  colspan='2'  style="border: 1pt solid black;vertical-align: top;"|<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(1,1)</math>
+|-style="text-align:center"
-|-
+|  ni
-|  style="border: 1pt solid black;vertical-align: top;"|ni
+|  3
-|  style="border: 1pt solid black;vertical-align: top;"|3
+|  7
-|  style="border: 1pt solid black;vertical-align: top;"|7
+|  3
-|  style="border: 1pt solid black;vertical-align: top;"|3
+|  7
-|  style="border: 1pt solid black;vertical-align: top;"|7
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}})</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}})</math>
+|  0.0001526
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001526       </span>
+|  7.3974e-05
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">7.3974e-05</span>
+|  0.0003053
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0003053         </span>
+|  0.0001479
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001479</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,\left( {\tilde{{\mathit{\boldsymbol{\beta }}}_{\mathit{\boldsymbol{r}}}}}_{\, }\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,\left( {\tilde{{\mathit{\boldsymbol{\beta }}}_{\mathit{\boldsymbol{r}}}}}_{\, }\right)</math>
+|  0.0001461
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001461       </span>
+|  7.1668e-05
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">7.1668e-05</span>
+|  0.0002923
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002923         </span>
+|  0.0001433
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001433</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
+|  0.0001032
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001032       </span>
+|  6.9166e-05
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">6.9166e-05</span>
+|  0.0001912
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001912          </span>
+|  0.0001332
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001332</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)\right)</math>
+|  9.9335e-05
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">9.9335e-05      </span>
+|  6.7089e-05
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">6.7089e-05</span>
+|  0.0001845
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001845         </span>
+|  0.0001293
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001293</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{RMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}:\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{RMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}:\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
+|  1.4795
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.4795             </span>
+|  1.0695
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0695</span>
+|  1.5965
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.5965                </span>
+|  1.1104
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.1104</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{RMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}:{\tilde{\mathit{\boldsymbol{\beta }}}}_{c}(k,d)\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{RMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}:{\tilde{\mathit{\boldsymbol{\beta }}}}_{c}(k,d)\right)</math>
+|  1.4716
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.4716             </span>
+|  1.0682
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0682</span>
+|  1.5845
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.5845</span>
+|  1.1083
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.1083</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{RMSE}\,\left( \tilde{\mathit{\boldsymbol{\beta }}}(k,d):{\tilde{\mathit{\boldsymbol{\beta }}}}_{\mathit{\boldsymbol{c}}}(k,d)\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{RMSE}\,\left( \tilde{\mathit{\boldsymbol{\beta }}}(k,d):{\tilde{\mathit{\boldsymbol{\beta }}}}_{\mathit{\boldsymbol{c}}}(k,d)\right)</math>
+|  1.0389
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0389             </span>
+|  1.0309
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0309</span>
+|  1.0363
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0363                 </span>
+|  1.0301
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0301</span>
+|-style="text-align:center"
-|-
+|  <math>p=0.85</math>
-|  style="border: 1pt solid black;vertical-align: top;"|p=0.85
+|  colspan='2'  |<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(0.5,0.5)</math>
-|  colspan='2'  style="border: 1pt solid black;vertical-align: top;"|<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(0.5,0.5)</math>
+|  colspan='2'  |<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(1,1)</math>
-|  colspan='2'  style="border: 1pt solid black;vertical-align: top;"|<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(1,1)</math>
+|-style="text-align:center"
-|-
+|  ni
-|  style="border: 1pt solid black;vertical-align: top;"|ni
+|  3
-|  style="border: 1pt solid black;vertical-align: top;"|3
+|  7
-|  style="border: 1pt solid black;vertical-align: top;"|7
+|  3
-|  style="border: 1pt solid black;vertical-align: top;"|3
+|  7
-|  style="border: 1pt solid black;vertical-align: top;"|7
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}})</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}})</math>
+|  0.0002198
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002198</span>
+|  0.0003460
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0003460</span>
+|  0.0004396
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0004396        </span>
+|  0.0002387
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002387</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,\left( {\tilde{{\mathit{\boldsymbol{\beta }}}_{\mathit{\boldsymbol{r}}}}}_{\, }\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,\left( {\tilde{{\mathit{\boldsymbol{\beta }}}_{\mathit{\boldsymbol{r}}}}}_{\, }\right)</math>
+|  0.0002076
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002076         </span>
+|  0.0001134
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001134</span>
+|  0.0004153
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0004153         </span>
+|  0.0002269
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002269</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
+|  0.0001332
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001332         </span>
+|  0.0001045
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001045</span>
+|  0.0002562
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002562         </span>
+|  0.0002111
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002111</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)\right)</math>
+|  0.0001277
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0001277         </span>
+|  0.0002460
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002460</span>
+|  0.0002459
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002459        </span>
+|  0.0002014
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002014</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{RMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}:\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{RMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}:\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
+|  1.6495
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.6495                </span>
+|  1.1414
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.1414</span>
+|  1.7156
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.7156             </span>
+|  1.1308
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.1308</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{RMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}:{\tilde{\mathit{\boldsymbol{\beta }}}}_{c}(k,d)\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{RMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}:{\tilde{\mathit{\boldsymbol{\beta }}}}_{c}(k,d)\right)</math>
+|  1.6263
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.6263                </span>
+|  1.1373
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.1373</span>
+|  1.6889
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.6889             </span>
+|  1.1266
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.1266</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{RMSE}\,\left( \tilde{\mathit{\boldsymbol{\beta }}}(k,d):{\tilde{\mathit{\boldsymbol{\beta }}}}_{\mathit{\boldsymbol{c}}}(k,d)\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{RMSE}\,\left( \tilde{\mathit{\boldsymbol{\beta }}}(k,d):{\tilde{\mathit{\boldsymbol{\beta }}}}_{\mathit{\boldsymbol{c}}}(k,d)\right)</math>
+|  1.0430
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0430                </span>
+|  1.1219
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.1219</span>
+|  1.0418
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0418</span>
+|  1.0481
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0481</span>
+|-style="text-align:center"
-|-
+|  <math>p=0.95</math>
-|  style="border: 1pt solid black;vertical-align: top;"|p=0.95
+|  colspan='2'  |<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(0.5,0.5)</math>
-|  colspan='2'  style="border: 1pt solid black;vertical-align: top;"|<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(0.5,0.5)</math>
+|  colspan='2'  |<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(1,1)</math>
-|  colspan='2'  style="border: 1pt solid black;vertical-align: top;"|<math>\left( {\sigma }^{2},{\sigma }_{1}^{2}\right) =(1,1)</math>
+|-style="text-align:center"
-|-
+|  ni
-|  style="border: 1pt solid black;vertical-align: top;"|ni
+|  3
-|  style="border: 1pt solid black;vertical-align: top;"|3
+|  7
-|  style="border: 1pt solid black;vertical-align: top;"|7
+|  3
-|  style="border: 1pt solid black;vertical-align: top;"|3
+|  7
-|  style="border: 1pt solid black;vertical-align: top;"|7
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}})</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}})</math>
+|  0.0005729
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0005729</span>
+|  0.0003460
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0003460</span>
+|  0.0011459
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0011459          </span>
+|  0.0006920
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0006920</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,\left( {\tilde{{\mathit{\boldsymbol{\beta }}}_{\mathit{\boldsymbol{r}}}}}_{\, }\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,\left( {\tilde{{\mathit{\boldsymbol{\beta }}}_{\mathit{\boldsymbol{r}}}}}_{\, }\right)</math>
+|  0.0005033
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0005033        </span>
+|  0.0003044
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0003044</span>
+|  0.0010066
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0010066          </span>
+|  0.0006088
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0006088</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
+|  0.0002762
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002762        </span>
+|  0.0002760
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002760</span>
+|  0.0005201
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0005201           </span>
+|  0.0005272
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0005272</span>
+|-style="text-align:center"
-|-
+|  <math>\mathrm{EMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{EMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)\right)</math>
+|  0.0002578
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002578        </span>
+|  0.0002460
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0002460</span>
+|  0.0004927
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0004927          </span>
+|  0.0004716
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">0.0004716</span>
+|-style="text-align:center"
+|  <math>\mathrm{RMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}:\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
+|  2.0743
-|-
+|  1.2533
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{RMSE}\,(\tilde{\mathit{\boldsymbol{\beta }}}:\tilde{\mathit{\boldsymbol{\beta }}}(k,d))</math>
+|  2.2030
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">2.0743              </span>
+|  1.3125
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.2533</span>
+|-style="text-align:center"
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">2.2030                </span>
+|  <math>\mathrm{RMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}:{\tilde{\mathit{\boldsymbol{\beta }}}}_{c}(k,d)\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.3125</span>
+|  1.9524
-|-
+|  1.2369
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{RMSE}\,\left( {\tilde{\mathit{\boldsymbol{\beta }}}}_{r}:{\tilde{\mathit{\boldsymbol{\beta }}}}_{c}(k,d)\right)</math>
+|  2.0429
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.9524              </span>
+|  1.2908
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.2369</span>
+|-style="text-align:center"
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">2.0429                </span>
+|  <math>\mathrm{RMSE}\,\left( \tilde{\mathit{\boldsymbol{\beta }}}(k,d):{\tilde{\mathit{\boldsymbol{\beta }}}}_{\mathit{\boldsymbol{c}}}(k,d)\right)</math>
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.2908</span>
+|  1.0713
-|-
+|  1.1219
-|  style="border: 1pt solid black;vertical-align: top;"|<math>\mathrm{RMSE}\,\left( \tilde{\mathit{\boldsymbol{\beta }}}(k,d):{\tilde{\mathit{\boldsymbol{\beta }}}}_{\mathit{\boldsymbol{c}}}(k,d)\right)</math>
+|  1.0556
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0713               </span>
+|  1.1178
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.1219</span>
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.0556                </span>
-|  style="border: 1pt solid black;vertical-align: top;"|<span style="text-align: center; font-size: 75%;">1.1178</span>
 |}
 ==7. Real data analysis==
-We consider a data set, which is known as the Egyptian pottery data to show the behavior of the new Restricted and Unrestricted Two-Parameter Estimators. This data set arises from an extensive archaeological survey of pottery production and distribution in the ancient Egyptian city of Al-Amarna. The data consist of measurements of chemical contents (mineral elements) made on many samples of pottery using two different techniques, NAA and ICP (see Smith et al. [30] for description of techniques). The set of pottery was collected from different locations around the city. We fit the data set by linear mixed model as <math display="inline">\mathit{\boldsymbol{y}}=</math><math>\mathit{\boldsymbol{X\beta }}+\mathit{\boldsymbol{Zu}}+\mathit{\boldsymbol{\epsilon }},</math> where <math display="inline">\mathit{\boldsymbol{y}}</math> is <math display="inline">159\times 1</math> vector of response variables, <math display="inline">\mathit{\boldsymbol{X}}</math> and <math display="inline">\mathit{\boldsymbol{Z}}</math> which are regression matrix with dimensions <math display="inline">159\times 6</math> and <math display="inline">159\times 25</math> respectively. First, we are estimated the variance components by consider <math display="inline">{\sigma }_{1}^{2}=</math><math>0.5</math> and <math display="inline">{\sigma }^{2}=0.5.</math> Then, by calculating the eigenvalues of <math display="inline">\mathit{\boldsymbol{X}}{\mathit{\boldsymbol{H}}}^{-1}\mathit{\boldsymbol{X}},</math> the condition number 8322860 is obtained, which indicate severe multicollinearity. We considered the stochastic linear restrictions as <math display="inline">\mathit{\boldsymbol{r}}=</math><math>\mathit{\boldsymbol{R\beta }}+\Phi ,\Phi \sim N\left( 0,{\sigma }^{2}{\mathit{\boldsymbol{I}}}_{3}\right)</math>  and selected 3 available data in the previous sections to the Egyptian pottery data. <math display="inline">{\tilde{k}}_{HM}</math> and <math display="inline">{\tilde{d}}_{opt}</math> are obtained using the iterative method introduced at the end of section 5,0.348 and 0.373 respectively. In Table 2 the estimated <math display="inline">MSE</math> values of the estimators are obtained by replacing in the corresponding theoretical MSE equations. We can see the estimated MSE values of <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> is less than <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math>. Also, the estimated MSE values of <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{c}(k,d)</math> is less than <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}</math>. In general, the estimated MSE values of <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)</math> is less than all estimators. So, we conclude that the stochastic restricted two parameter estimator performs better than the other estimators. Note that in the results obtained for this data, all eigenvalues of <math display="inline">{\Delta }_{1}</math> and <math display="inline">{\Delta }_{2}</math> are positive and the condition of Theorem 4.1 and Theorem 4.2 are true. In Figure 1 , a plot of the estimated MSE values of <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math> and <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> against <math display="inline">k</math> in the interval [0,2] with fixed <math display="inline">{\tilde{d}}_{opt~}=</math><math>0.373</math> is drawn. Because <math display="inline">\tilde{\beta }</math> is not dependent on <math display="inline">k</math>, its estimated <math display="inline">MSE</math> value is the same for all <math display="inline">k</math> values. It is obvious that estimated <math display="inline">MSE</math> values of <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> is always less than <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math>. Altogether, it is obvious that the two parameter estimators can perform better than the <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math> in MSEM criterion under conditions.
+We consider a data set, which is known as the Egyptian pottery data to show the behavior of the new Restricted and Unrestricted Two-Parameter Estimators. This data set arises from an extensive archaeological survey of pottery production and distribution in the ancient Egyptian city of Al-Amarna. The data consist of measurements of chemical contents (mineral elements) made on many samples of pottery using two different techniques, NAA and ICP (see Smith et al. [30] for description of techniques). The set of pottery was collected from different locations around the city. We fit the data set by linear mixed model as <math display="inline">\mathit{\boldsymbol{y}}=</math><math>\mathit{\boldsymbol{X\beta }}+\mathit{\boldsymbol{Zu}}+\mathit{\boldsymbol{\epsilon }},</math> where <math display="inline">\mathit{\boldsymbol{y}}</math> is <math display="inline">159\times 1</math> vector of response variables, <math display="inline">\mathit{\boldsymbol{X}}</math> and <math display="inline">\mathit{\boldsymbol{Z}}</math> which are regression matrix with dimensions <math display="inline">159\times 6</math> and <math display="inline">159\times 25</math> respectively. First, we are estimated the variance components by consider <math display="inline">{\sigma }_{1}^{2}=</math><math>0.5</math> and <math display="inline">{\sigma }^{2}=0.5.</math> Then, by calculating the eigenvalues of <math display="inline">\mathit{\boldsymbol{X}}{\mathit{\boldsymbol{H}}}^{-1}\mathit{\boldsymbol{X}},</math> the condition number 8322860 is obtained, which indicate severe multicollinearity. We considered the stochastic linear restrictions as <math display="inline">\mathit{\boldsymbol{r}}=</math><math>\mathit{\boldsymbol{R\beta }}+\Phi ,\Phi \sim N\left( 0,{\sigma }^{2}{\mathit{\boldsymbol{I}}}_{3}\right)</math>  and selected 3 available data in the previous sections to the Egyptian pottery data. <math display="inline">{\tilde{k}}_{HM}</math> and <math display="inline">{\tilde{d}}_{opt}</math> are obtained using the iterative method introduced at the end of section 5,0.348 and 0.373 respectively. In [[#tab-2|Table 2]], the estimated <math display="inline">MSE</math> values of the estimators are obtained by replacing in the corresponding theoretical MSE equations. We can see the estimated MSE values of <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> is less than <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math>. Also, the estimated MSE values of <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{c}(k,d)</math> is less than <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}</math>. In general, the estimated MSE values of <math display="inline">{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)</math> is less than all estimators. So, we conclude that the stochastic restricted two parameter estimator performs better than the other estimators. Note that in the results obtained for this data, all eigenvalues of <math display="inline">{\Delta }_{1}</math> and <math display="inline">{\Delta }_{2}</math> are positive and the condition of Theorem 4.1 and Theorem 4.2 are true. In [[#img-1|Figure 1]], a plot of the estimated MSE values of <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math> and <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> against <math display="inline">k</math> in the interval [0,2] with fixed <math display="inline">{\tilde{d}}_{opt~}=</math><math>0.373</math> is drawn. Because <math display="inline">\tilde{\beta }</math> is not dependent on <math display="inline">k</math>, its estimated <math display="inline">MSE</math> value is the same for all <math display="inline">k</math> values. It is obvious that estimated <math display="inline">MSE</math> values of <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> is always less than <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math>. Altogether, it is obvious that the two parameter estimators can perform better than the <math display="inline">\tilde{\mathit{\boldsymbol{\beta }}}</math> in MSEM criterion under conditions.
-<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
+<div class="center" style="font-size: 75%;">'''Table 2'''. Estimated MSE values of the proposed estimators</div>
-Table 2. Estimated MSE values of the proposed estimators.</div>
-{| style="width: 100%;border-collapse: collapse;"
+<div id='tab-2'></div>
-|-
+{| class="wikitable" style="margin: 1em auto 0.1em auto;border-collapse: collapse;font-size:85%;width:auto;"
-|  style="border: 1pt solid black;vertical-align: top;"|
+|-style="text-align:center"
-|  style="border: 1pt solid black;"|<math>\tilde{\mathit{\boldsymbol{\beta }}}{\, }{\, }{\, }</math>
+! !! <math>\tilde{\mathit{\boldsymbol{\beta }}}{\, }{\, }{\, }</math> !! <math>{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}</math> !! <math>\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math> !! <math>{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)</math>
+|-style="text-align:center"
+|  EMSE
-|  style="border: 1pt solid black;"|<math>{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}</math>
+|  1.216069
+|  1.201379
+|  0.1544953
-|  style="border: 1pt solid black;"|<math>\tilde{\mathit{\boldsymbol{\beta }}}(k,d)</math>
+|  0.1541745
+|}
-|  style="border: 1pt solid black;"|<math>{\tilde{\mathit{\boldsymbol{\beta }}}}_{r}(k,d)</math>
+<div id='img-1'></div>
+{| style="text-align: center; border: 1px solid #BBB; margin: 1em auto; width: auto;max-width: auto;"
 |-
-|  style="border: 1pt solid black;"|EMSE
+|style="padding:10px;"|  [[Image:Review_312425094190-image1.png|276px]]
-|  style="border: 1pt solid black;"|1.216069
+|- style="text-align: center; font-size: 75%;"
-|  style="border: 1pt solid black;"|1.201379
+| colspan="1" style="padding:10px;"| '''Figure 1'''. The estimated mean square error values of the estimators versus <math display="inline">k</math> with <math display="inline">{\tilde{d}}_{of~}</math>
-|  style="border: 1pt solid black;"|0.1544953
-|  style="border: 1pt solid black;"|0.1541745
 |}
-<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
-<span style="text-align: center; font-size: 75%;"> [[Image:Review_312425094190-image1.png|276px]] </span></div>
-<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
-Figure <math display="inline">1.</math> The estimated mean square error values of the estimators versus <math display="inline">k</math> with <math display="inline">{\tilde{d}}_{of~}</math></div>
 ==8. Conclusion==
@@ Line 852: / Line 862: @@
 ==Funding==
+The research was supported by the Slamic Azad University.
-The research was supported by the Payame Noor University.
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+</div>