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\widehat{\vartheta_{l}}\geq t_{2}
|
l_{2}(\eta,\widehat{\eta})\propto e^{c(\widehat{\eta}-\eta)}-c(\widehat{\eta}-%
\eta)-1,\quad c\neq 0.
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E(\widehat{\vartheta}_{MLE})=\left(1-v^{n}\right)^{-1}{\left[\sum_{\mathcal{D}%
=1}^{\gamma-1}\sum_{k=0}^{\mathcal{D}}A_{k,\mathcal{D}}\left(\vartheta+T_{k,%
\mathcal{D}}\right)+\vartheta\right.}\\
\left.+\gamma\left(\begin{array}[]{l}n\\
\gamma\end{array}\right)\sum_{k=1}^{\gamma}\frac{(-1)^{k}v^{n-\gamma+k}}{n-%
\gamma+k}\left(\begin{array}[]{l}\gamma-1\\
k-1\end{array}\right)\left(\vartheta+T_{k,\gamma}\right)\right],
|
\vartheta_{U}
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P_{a}=\frac{p_{a}}{1-p_{c}}
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L(x,\vartheta)=\frac{1}{\vartheta^{\gamma}}exp\left\{-\frac{1}{\vartheta}\sum%
\limits_{i=1}^{\mathcal{D}}x_{i,n}-\frac{(n-\gamma)}{\vartheta}\mathcal{T}^{*}%
\right\},
|
L(\vartheta,x)=-\gamma\operatorname{log}\vartheta-\frac{1}{\vartheta}\sum%
\limits_{i=1}^{\mathcal{D}}x_{i,n}-\frac{(n-\gamma)}{\vartheta}\mathcal{T}^{*},
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\widehat{\vartheta_{s}}<t_{1}.
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\widehat{g}_{s}=E(g\mid Data)=\frac{\int_{\vartheta}g(\vartheta)L(x,\vartheta)%
\rho(\vartheta)d\vartheta}{\int_{\vartheta}L(x,\vartheta)\rho(\vartheta)d%
\vartheta}.
|
h(\vartheta\mid Data)=\frac{\left(\mathcal{D}\ \hat{\vartheta}_{MLE}+a\right)^%
{(\mathcal{D}+b)}}{\Gamma(\mathcal{D}+b)}\vartheta^{-\left(\mathcal{D}+b+1%
\right)}\operatorname{exp}\left\{\left(\mathcal{D}\ \hat{\vartheta}_{MLE}+a%
\right)/\vartheta\right\}
|
\mathcal{D}\geq 1
|
\hat{\vartheta}_{MLE}
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\mathcal{T}^{*}=\operatorname{Min}\{\mathcal{T},X_{\gamma,n}\}
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\frac{1}{1-p_{c}}\ E\left(\widehat{\vartheta_{l}}\right)
|
\displaystyle\underset{\left(n,t_{1},t_{2}\right)}{\operatorname{Min}}\left(%
\frac{C\ E\left(\widehat{\vartheta_{l}}\right)}{1-p_{c}}\right)\text{at}\ %
\vartheta_{A}
|
t_{2}=2157
|
\vartheta_{A}
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P_{1}(n,t_{1},t_{2})
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\displaystyle\left(P_{a}\mid\vartheta=\vartheta_{U}\right)\leq\beta,
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n,t_{1},
|
\displaystyle\underset{\left(n,t_{1},t_{2}\right)}{\operatorname{Min}}\left(%
\frac{C\ E\left(\widehat{\vartheta_{l}}\right)}{1-P\left[\frac{t_{1}-E\left(%
\widehat{\vartheta_{l}}\right)}{\sqrt{V\left(\widehat{\vartheta_{l}}\right)}}%
\leq Z<\frac{t_{2}-E\left(\widehat{\vartheta_{l}}\right)}{\sqrt{V\left(%
\widehat{\vartheta_{l}}\right)}}\right]}\right)\text{at}\ \vartheta_{A}
|
P_{r}=\frac{p_{r}}{1-p_{c}}
|
\displaystyle\left(\frac{P\left[Z\geq\frac{t_{2}-E\left(\widehat{\vartheta_{l}%
}\right)}{\sqrt{V\left(\widehat{\vartheta_{l}}\right)}}\right]}{1-P\left[\frac%
{t_{1}-E\left(\widehat{\vartheta_{l}}\right)}{\sqrt{V\left(\widehat{\vartheta_%
{l}}\right)}}\leq Z<\frac{t_{2}-E\left(\widehat{\vartheta_{l}}\right)}{\sqrt{V%
\left(\widehat{\vartheta_{l}}\right)}}\right]}\mid\vartheta=\vartheta_{U}%
\right)\leq\beta,
|
\mathcal{T}=50
|
\widehat{\vartheta_{l}}=\widehat{\vartheta}_{MLE}-\frac{1}{c}\operatorname{ln}%
\left[1+\frac{c}{2\mathcal{D}}\left(c\widehat{\vartheta}_{MLE}^{2}-2a+2%
\widehat{\vartheta}_{MLE}(b-1)\right)\right].
|
\displaystyle=\left(1-\frac{2cE\left(\widehat{\vartheta}_{MLE}\right)+2b-2}{2%
\mathcal{D}+c\left(cE\left(\widehat{\vartheta}_{MLE}\right)^{2}-2a+2E\left(%
\widehat{\vartheta}_{MLE}\right)(b-1)\right)}\right)^{2}\ \sigma^{2}\left({%
\widehat{\vartheta}_{MLE}}\right).
|
p_{a}=P\left(\widehat{\vartheta_{s}}\geq t_{2}\right)=P\left[Z\geq\frac{t_{2}-%
E\left(\widehat{\vartheta_{s}}\right)}{\sqrt{V\left(\widehat{\vartheta_{s}}%
\right)}}\right],
|
p_{c}=P\left(t_{1}\leq\widehat{\vartheta_{s}}<t_{2}\right)=P\left[\frac{t_{1}-%
E\left(\widehat{\vartheta_{s}}\right)}{\sqrt{V\left(\widehat{\vartheta_{s}}%
\right)}}\leq Z<\frac{t_{2}-E\left(\widehat{\vartheta_{s}}\right)}{\sqrt{V%
\left(\widehat{\vartheta_{s}}\right)}}\right].
|
g=g(\vartheta)
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P_{1}\left(n,t_{1},t_{2}\right)
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\displaystyle\left(\frac{P\left[Z\geq\frac{t_{2}-E\left(\widehat{\vartheta_{s}%
}\right)}{\sqrt{V\left(\widehat{\vartheta_{s}}\right)}}\right]}{1-P\left[\frac%
{t_{1}-E\left(\widehat{\vartheta_{s}}\right)}{\sqrt{V\left(\widehat{\vartheta_%
{s}}\right)}}\leq Z<\frac{t_{2}-E\left(\widehat{\vartheta_{s}}\right)}{\sqrt{V%
\left(\widehat{\vartheta_{s}}\right)}}\right]}\mid\vartheta=\vartheta_{U}%
\right)\leq\beta,
|
\text{ETC}=\frac{C\ E\left(\widehat{\vartheta_{l}}\right)}{1-p_{c}},
|
\displaystyle\underset{\left(n,t_{1},t_{2}\right)}{\operatorname{Min}}\left(%
\frac{C\ E\left(\widehat{\vartheta_{s}}\right)}{1-p_{c}}\right)\text{at}\ %
\vartheta_{A}
|
\widehat{\vartheta_{l}}>t_{2}
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\mathcal{T}^{*}=\operatorname{Min}\{\mathcal{T},X_{\gamma}\}
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\widehat{\vartheta_{s}}
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\displaystyle\text{Data type I}:
|
\displaystyle=E\left(\widehat{\vartheta}_{MLE}\right)-\frac{1}{c}\operatorname%
{ln}\left[1+\frac{c}{2\mathcal{D}}\left(cE\left(\widehat{\vartheta}_{MLE}%
\right)^{2}-2a+2E\left(\widehat{\vartheta}_{MLE}\right)(b-1)\right)\right],
|
t_{1}\leq\widehat{\vartheta_{l}}<t_{2}
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P_{2}(n,t_{1},t_{2})
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\mathcal{T}=2000
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E\left(\widehat{\vartheta_{s}}\right)=U_{1}\left(E\left(\widehat{\vartheta}_{%
MLE}\right)\right)=\frac{\mathcal{D}\ E\left(\hat{\vartheta}_{MLE}\right)+a}{%
\mathcal{D}+b-1},
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\displaystyle P_{2}(n,t_{1},t_{2}):\qquad
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\frac{\left(\mathcal{D}\ \hat{\vartheta}_{MLE}+a\right)}{\vartheta}
|
\displaystyle=\left(\frac{\mathcal{D}}{\mathcal{D}+b-1}\right)^{2}\sigma^{2}%
\left({\widehat{\vartheta}_{MLE}}\right).
|
t_{2}=2065
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X_{11}=1594
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\displaystyle\left\{X_{1,n}<X_{2,n}<\cdots<X_{\gamma,n}\right\}\quad\text{if}%
\quad\mathcal{T}^{*}=X_{\gamma},
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n,t_{1},t_{2}
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f(x,\vartheta)=\frac{1}{\vartheta}exp\left\{-\frac{-x}{\vartheta}\right\}%
\qquad x\geq 0,\vartheta>0
|
\widehat{\vartheta_{s}}=U_{1}\left(\widehat{\vartheta}_{MLE}\right)
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\widehat{\vartheta_{l}}<t_{1}.
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\vartheta_{A}=500
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c=-0.5
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\displaystyle P\left(\text{Lot is rejected}\mid\vartheta=\vartheta_{A}\right)
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\mathcal{T}^{*}=X_{\gamma}
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\displaystyle\leq\alpha,
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E\left(\widehat{\vartheta}_{MLE}^{2}\right)=\left(1-v^{n}\right)^{-1}\left[%
\sum_{\mathcal{D}=1}^{\gamma-1}\sum_{k=0}^{\mathcal{D}}A_{k,\mathcal{D}}\left%
\{\frac{\vartheta^{2}}{\mathcal{D}}(1+\mathcal{D})+2T_{k,\mathcal{D}}\vartheta%
+\left(T_{k,\mathcal{D}}\right)^{2}\right\}\right.\\
+\frac{\vartheta^{2}}{\gamma}(1+\gamma)+\gamma\left(\begin{array}[]{l}n\\
\gamma\end{array}\right)\left.\cdot\sum_{k=1}^{\gamma}\frac{(-1)^{k}v^{n-%
\gamma+k}}{n-\gamma+k}\left(\begin{array}[]{l}\gamma-1\\
k-1\end{array}\right)\left\{\frac{\vartheta^{2}}{\gamma}(1+\gamma)+2T_{k,%
\gamma}\vartheta+\left(T_{k,\gamma}\right)^{2}\right\}\right].
|
\widehat{\vartheta_{s}}\geq t_{2}
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E\left(\widehat{\vartheta_{s}}\right)=\frac{\mathcal{D}\ E\left(\hat{\vartheta%
}_{MLE}\right)+a}{\mathcal{D}+b-1},
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\displaystyle V\left(\widehat{\vartheta_{l}}\right)
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0<\alpha,\beta<1
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\widehat{\vartheta_{l}}=2883.2339
|
\chi^{2}_{2\left(b+a\right)}/2
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\widehat{\vartheta_{s}}=\frac{\mathcal{D}\ \hat{\vartheta}_{MLE}+a}{\mathcal{D%
}+b-1}.
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\displaystyle=U_{2}\left(E\left(\widehat{\vartheta}_{MLE}\right)\right)
|
\vartheta_{A}=200
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\widehat{\vartheta}_{MLE}
|
\begin{aligned} &11,35,49,170,329,381,708,958,1062,1167,1594,1925,1990,2223,23%
27,2400,2451,2471,2551,2565,2568,\\
&2694,2702,2761,2831,3034,3059,3112,3214,3478,3504,4329,6367,6976,7846,13403.%
\end{aligned}
|
\displaystyle\left(\frac{P\left[Z<\frac{t_{1}-E\left(\widehat{\vartheta_{l}}%
\right)}{\sqrt{V\left(\widehat{\vartheta_{l}}\right)}}\right]}{1-P\left[\frac{%
t_{1}-E\left(\widehat{\vartheta_{l}}\right)}{\sqrt{V\left(\widehat{\vartheta_{%
l}}\right)}}\leq Z<\frac{t_{2}-E\left(\widehat{\vartheta_{l}}\right)}{\sqrt{V%
\left(\widehat{\vartheta_{l}}\right)}}\right]}\mid\vartheta=\vartheta_{A}%
\right)\leq\alpha,
|
\displaystyle V\left(\widehat{\vartheta_{s}}\right)
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\widehat{g}_{l}=-\frac{1}{c}\ln E\left(e^{-cg}\mid Data\right),
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\rho(\vartheta)=\frac{a^{b}}{\Gamma(b)}\vartheta^{-(b+1)}e^{-a/\vartheta},%
\quad\vartheta>0,\ a>0,\ \text{and}\ b>0.
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\displaystyle\leq\beta,
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\widehat{\vartheta_{s}}=2577.9286
|
\gamma=11
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\displaystyle\left(\frac{p_{a}}{1-p_{c}}\mid\vartheta=\vartheta_{U}\right)\leq\beta,
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\frac{1}{1-p_{c}}
|
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