SciELO - Scientific Electronic Library Online

 
vol.18 número6AI-based smart and intelligent wheelchairProposal for a KDD-based procedure to obtain a set of intelligent systems training applied to the identification of failures in hydroelectric power plants índice de autoresíndice de materiabúsqueda de artículos
Home Pagelista alfabética de revistas  

Servicios Personalizados

Revista

Articulo

Indicadores

Links relacionados

  • No hay artículos similaresSimilares en SciELO

Compartir


Journal of applied research and technology

versión On-line ISSN 2448-6736versión impresa ISSN 1665-6423

J. appl. res. technol vol.18 no.6 Ciudad de México dic. 2020  Epub 30-Jul-2021

https://doi.org/10.22201/icat.24486736e.2020.18.6.1354 

Articles

Estimation of R for geometric distribution under lower record values

M. O. Mohameda  * 

aFaculty of science, Zagazig University, Cairo-Egypt


Abstract:

In this paper, the estimation of the stress-strength model R = P(Y < X), based on lower record values is derived when both X and Y are independent and identical random variables with geometric distribution. Estimating R with maximum likelihood estimator and Bayes estimator with non-informative prior information based on mean square errors and LINIX loss functions for geometric distribution are obtained. The confidence intervals of R are constructed by using exact, bootstrap and Bayesian methods. Finally, different methods have been used for illustrative purpose by using simulation. The main results are obtained and introduced through a set of tables and figures with discussions.

Keywords: Geometric distribution; stress-strength model; maximum likelihood estimator; Bayes estimator; means square errors loss functions; LINIX loss functions

1. Introduction

The stress-strength model is one of the applied model in reliability, which has important practices in many fields especially in engineering applications. The statisticians deal with this model as X is strength and Y is a stress and the system working if, and only if, at any time the applied stress is lower than its strength. This model can be expressed as reliability function R = P(Y < X), where X and Y are independent and identical random variables. To estimate the reliability values in this model, we should first estimate the parameters of stress Y and strength X by using different methods of estimations, Hassan, Muhammed, and Saad (2015), Nkemnole and Samiyu (2017).

In geometric distribution, the probability of success is assumed to be the same for each trial. In such a sequence of trials, the geometric distribution is useful to model the number of failures before the first success. The distribution gives the probability that there are zero failures before the first success, one failure before the first success, two failures before the first success, and so on, Pitman (1993), Walck (2007).

The record values can be classified into lower and upper values, where the observer Xi is called lower value if it is smaller than all pervious subjects to experience. In other side, if Xj is exceed all the subjects to experience, it will call upper record.

Record values have been discussed in the statistical literature by many authors who explained how rerecord values are important in many fields. Chandler (1952) explained how the record values, record times and the inter record times based on the record values are obtained and used to form a model of extremes sequence of independent and identical distributed random variables. The record values and its kinds have introduced in Nagaraja (1988), Ahsanullah (1995, 2004).

Many authors have been focused on the stress-strength model R and they tried to apply it in different cases of studies. Birnbaum (1956), Kundu and Gupta (2005, 2006), Razaei, Tahmasbi, and Mahmoodi (2010), Hussian, (2013) studied the estimation of R for different distributions. The recorded values and more studies about R with different distributions and different methods of estimation found in Baklizi (2008, 2014), Essam (2012), Tarvirdizade, and Kazemzadeh Garehchobogh (2014).

This paper is organized as follows. In Section 2, maximum likelihood estimates and exact confidence interval of R are studied. Also, the asymptotic bootstrap confidence interval of R is established. In Section 3, the Bayes estimates of R against both squared error and LINEX loss functions are studied. Also, Bayes confidence interval is obtained. In Section 4, steps of simulation study are proposed. Results and discussion are shown in Section 5. Finally, conclusions appear in Section 6.

2. Likelihood inferences

In this section, maximum likelihood estimator (MLE) and confidence interval of R are derived. Also, the asymptotic bootstrap confidence interval of R is obtained.

2.1. Maximum likelihood estimator of R

According to Mohamed (2015), let Y be stress for the model of stress-strength is subjected to X as strength of the model. Assume X ~ P(X, P1) and Y ~ P(Y, P2) have geometric distribution with x ∈ {1, 2, 3, …} nd 0 < p1 < 1.

px=(1-p1)x-1 p1 (1)

F(x)=1 -(1-p1)x (2)

where p(.) And F(.)are the probability and cumulative density function.

Then the reliability function

R= P2p1+ p2- p1 p2 (3)

Let r = (r0, … …, rn) be the first independent set of lower record of data with size (n +1) from strength with geometric distribution with parameter p1 and s = (s0, …, …, sm) have the same features but with size (m +1) from stress with geometric distribution with parameter p2.

The likelihood function for both r and s are given by Arnold, Balakrishnan and Nagaraja (1998):

 L1p1|r  =prni=0n-1p(ri)F(ri) ,   0<rn<rn-1<<r0< (4)

and

L2p2|s  =prmj=0m-1p(sj)F(sj) ,   0<sm<sm-1<<s0< (5)

The likelihood function of the observed record values r and s are:

L1p1|r_  =(1- p1)rn-1p1n+1i=0n-1(1-p1)ri-1(1-(1- p1))ri (6)

and

L2(p2|s_) =(1- P2)Sn-1P2m+1 j=0m-1(1-p1)sj-1 (1-(1- p1))sj (7)

Therefore, the joint log-likelihood function of r and s denoted by l is:

l= (rn-1) log 1-p1+n+1 log p1+ sm-1log (1-p2)+m+1log  p2+log i=0n-1(1- p1)ri-1  j=0m-1(1- p2)sj-1  (8)

The maximum likelihood estimators of p1 and p2 are p^1 and p^2 according to the observed lower record values are obtaining by solving the equations as follow:

lp1= [-rn-1- i=0nri-1]  (1-p̂̂1 )+ n+1 p̂̂1=0 (9)

and

lp2= [-sm-1- j=0msj-1] (1-p̂̂2 )+ m+1 p̂̂2=0 (10)

From (9) and (10), P^1 and P^2 are obtained as follow:

 p^^1= n+1 rn-1+ n+1+i=0nri-1 , p̂̂2= m+1 sm-1+ m+1+j=0msj-1  (11)

Hence, the maximum likelihood estimator of R, denoted by R^ML, is given by substitution p^1 and p^2 in Eq. 3 as follows:

ȒML=  p̂̂2 p̂̂1+ p̂̂2-  p̂̂1 p̂̂2  (12)

2.2. Exact confidence interval of R

In this subsection, exact confidence interval of R based on the asymptotic properties and the general conditions of the MLE of p^1 and p^2 is obtained (Lehmann, 1999). The asymptotic distribution of the MLE immediately comes from the Fisher information matrix of p 1 and p 2. That is,

As n,m  and nmk, where 0 <k<1;then np^1-p1,mp^2-p2N20,δp,

where

δp=I-1p=I11I12I21I22-1

and the matrix I(P) is the Fisher information matrix of the parameter vector P = (p1, p).

The (ij)th element is defined as the second partial derivatives:

Iij=2l(P)P1P2, i,j=1,2

From the asymptotic properties of the MLEs of P1, P2, one can easily get.

nR^-R=n( p^^2 p^^1+ p^^2-  p^^1 p^^2 -P2p1+ p2- p1 p2)DN2(0,σ2) (13)

where

σ2=E(n p^^2 p^^1+ p^^2-  p^^1 p^^2 -nP2p1+ p2- p1 p2)2 (14)

The maximum likelihood (1 − α) 100% confidence interval of R is given by:

R^±Z1-α2σ^ (15)

where σ^ is the asymptotic standard deviation of R.

2.3. Asymptotic bootstrap confidence interval

In this subsection, the asymptotic bootstrap confidence interval of R is derived. Kotz and Pensky (2003) proposed the bootstrap method as an alternative way to construct a confidence interval.

The algorithm of the (1 − α) 100% confidence interval for R by using bootstrap method is illustrated below:

1- Use the estimators p^1 and p^2 in inverse of distribution of p1 and p2 to estimate the bootstrap sample X*1, … …, X*n and Y*1, … …, Y*n, then compute the estimated value of R by MLE which is shown in Eq. 12.

2- Calculate the bootstrap MSE by:

MSE^B=1Nk=1N(R-j-R-) (16)

3- The asymptotic (1 − α) 100% confidence interval is obtained by:

(R--Zα2MSE^B,R-+Zα2MSE^B) (17)

3. Bayesian inferences

In this section, the Bayes estimator of R is calculated by the mean squared error and LINEX loss functions. Also, Bayes confidence interval for R is obtained.

3.1. Bayes estimator of R based on mean square errors loss function

To get the Bayes estimator of p^1 and p^2 based on the mean square errors, we used the non-informative prior information for choosing the prior distributions. The steps to find the Bayesian estimator of p^1 and p^2, respectively, Mohamed (2015).

The non-informative priors of p1 and p2 by using Fisher information matrix for P1 and P2 are calculated as follows

IP1=-E2lP1P12,IP2=-E2lP2P22

The prior distributions by non-informative of p1 and p2 are

π(p1)   1p1,π(p2)   1p2 (18)

The posterior distributions of p1 and p2, denoted by π* (p1) and π* (p2), are obtained by combining Eq. 6, Eq. 7 and Eq. 18 as follows

π*p1=  (1- p1)rn-1p1ni=0n-1(1-p1)ri-1(1-(1- p1))ri 01(1- p1)rn-1p1ni=0n-1(1-p1)ri-1(1-(1- p1))ridp1, (19)

π*p2=  (1- P2)Sn-1P2m j=0m-1(1-p1)sj-1 (1-(1- p1))sj01(1- P2)Sn-1P2m j=0m-1(1-p1)sj-1 (1-(1- p1))sjdp2. (20)

The Bayes estimates of p1 and p2,under mean squared error loss function, denoted by p^1MS and p^2MS, are calculated as follows

P^1MS=01P1π*p1dp1=01(1- p1)rn-1p1n+1i=0n-1(1-p1)ri-1(1-(1- p1))ri 01(1- p1)rn-1p1ni=0n-1(1-p1)ri-1(1-(1- p1))ridp1dp1, (21)

and

P^2MS=01p2π*p2dp2=01(1- P2)Sn-1P2m+1 j=0m-1(1-p1)sj-1 (1-(1- p1))sj01(1- P2)Sn-1P2m j=0m-1(1-p1)sj-1 (1-(1- p1))sjdp2dp2. (22)

The mean square errors loss function of R based on the lower records data for X and Y denoted as R^MS, can be obtained by substituting Eq. 21 and Eq. 22 in Eq. 3.

R^MS= P^1MSP^1MS+ P^2MS- P^1MSP^2MS

3.2. Bayes estimator of R based on LINEX loss function

In this subsection, the Bayes estimator of R under LINEX loss function, denoted by R^LL is obtained. R^LL is calculated as follows

R^LL=-1alnEe-aR=1nln0101e-aRπ*p1π*p2dp1dp2

According to Lindley (1980) and after some calculations, the approximate Bayes estimator of R is

R^LL=-1alne-aR^ML+12R11σ11+R22σ22+L111R1σ112+L222R2σ222 (23)

where

a>0, σ11=P12n, σ22=P22m, R11= 21-P22P1+P2-P1P22,R22= 2P11-P1P1+P2-P1P22,L111=3lP13 and L222=3lP23

3.3. Bayes confidence interval of R

In this subsection, Bayes confidence interval for R is obtained. To derive the distribution of stress-strength R function based on Bayesian inferences, the posterior distributions of p1 and p2 must be found. the conjugate prior density functions of p1 and p2 is proportional with beta distribution as follows

π(p1) ~B(α1,β1)  ,π(p2) ~B(α2,β2) (24)

After some calculations, the posterior distributions of p1 is

π*p1= 1B(a1,b1)  p1a1-1  (1-p1)b1-1 (25)

where

a1=rn+n+α1,b1=rn+(k1+1)i=0n-1ri+n-1 ,k1=0,1,2,

And the posterior distribution for p2 is

π*p2= 1B(a2,b2)  p2a2-1  (1-p2)b2-1 (26)

where

a2=sm+m+α2,b2=sm+(k2+1)j=0m-1sj+m-1 ,k2=0,1,2,

The Bayesian (1 − α) 100% confidence interval of R for p1 and p2, are

PL1  p1U1|data=1-α,L2  p2U2|data=1-α (27)

Using Eq. 25, 26 and 27, the Bayesian confidence intervals (L1, U1) and (L2, U2) for p1 and p2 can be derived by solving the followings equations

0L11B(a1,b1)  p1a1-1  (1-p1)b1-1dp1=α2 , (28)

U101B(a1,b1)  p1a1-1  (1-p1)b1-1dp1=α2 (29)

0L21Ba2,b2  p2a2-1  (1-p2)b2-1dp2=α2,   (30)

and

U201Ba2,b2  p2a2-1  (1-p2)b2-1dp2=α2 (31)

Therefore, Bayes confidence interval for R is constructed by substitute Eq. 28, 29, 30 and 31 in Eq. 3.

4. Simulation study

In this section a simulation study is studied to compare the performance of MLE and Bayes estimates (under squared error and LINEX loss functions). The exact values of R are 0.714 and 0.95. The estimates of R through MLE and Bayes methods under lower record values are calculated for different sample sizes. Three different methods for confidence intervals are computed. The simulation study is performance according to the following steps:

  • 1. Generate 10000 samples from uniform (0,1), then find the 300 random sample according to geometric distribution through the transformation technique.

  • 2. From each vector the first (n + 1) of lower record values r0, … …, rn for the values of strength random variables X be selected,

  • 3. Repeat the previous two steps to generate 5000 random samples of size 300 from geometric distribution and select from each vector the first (m + 1) of lower record values s0, … …, sm for the values of stress random variable Y.

  • 4. The MLE of p1, p2 are obtained from Eq. 11, then the MLE of R is obtained by substitute p1 and p2 in Eq. 12. The maximum likelihood confidence intervals of p1 and p2 are calculated with confidence level at α = 0.5 by using Eq. 15. The bootstrap confidence intervals are obtained from Eq. 17. Bayesian confidence intervals are obtained from Eq. 3, 28 and 29.

  • 5. Compute Bayes estimator of R under mean squared error and LINEX loss functions.

5. Results and discussion

Simulation results are tabulated in Tables (1:6). We can observe the following results:

  • 1. The coverage percentage of MLE is better than that of the Bayesian estimator at R =0.714 and 0.985 according to Tables (1, 2).

  • 2. The coverage percentage of Bayes LINEX loss function is better than that of Bayes under MSE at R =0.714 and 0.985 according to Tables (3, 4).

  • 3. The average length of the exact confidence intervals is shorter than the bootstrap and Bayes methods according to Tables (5, 6).

  • 4. When n and m increase, the coverage percentages decrease for different estimators at different values of p1, p2 according to Tables (1, 6).

Table 1 Simulation results for maximum likelihood estimator and Bayes estimators under mean square errors at p = 0.1, p2 = 0.2 and R = 0.714 

n m MLE BAYES
R^ML MSE Converge R^MS MSE Converge
2 2 0.67 0.06 0.938 0.445 0.073 0.623
3 2 0.642 0.052 0.899 0.544 0.053 0.762
3 0.658 0.025 0.922 0.599 0.101 0.839
4 2 0.636 0.0047 0.891 0.345 0.342 0.483
3 0.602 0.013 0.843 0.268 0.435 0.375
5 3 0.637 0.0061 0.892 0.222 0.222 0.311
4 0.6 0.03 0.84 0.677 0.814 0.948
6 4 0.607 0.012 0.85 0.558 0.353 0.782
5 0.6674 0.02 0.935 0.454 0.111 0.636

Table 2 Simulation results for maximum likelihood estimator and Bayes estimators under mean square errors at p1 = 0.01, p2 = 0.16 and R = 0.95. 

n m MLE BAYES
R^ML MSE Converge R^MS MSE Converge
2 2 0.87 0.0145 0.916 0.179 0.818 0.188
3 2 0.829 0.0103 0.873 0.171 0.005 0.18
3 0.867 0.0147 0.913 0.934 0.548 0.983
4 2 0.835 0.099 0.879 0.747 0.546 0.786
3 0.894 0.0127 0.941 0.341 0.852 0.359
5 3 0.831 0.0102 0.875 0.946 0.681 0.996
4 0.884 0.0134 0.931 0.074 0.004 0.078
6 4 0.901 0.0116 0.948 0.861 0.707 0.906
5 0.871 0.0143 0.917 0.334 0.012 0.352

Table 3 Simulation results for Bayes estimators under mean square errors and LINEX loss function at p1 = 0.1, p2 = 0.2 and R = 0.714. 

n m BAYES with MSE BAYES with LINEX loss function
R^MS MSE Converge R^LL MSE Converge
2 2 0.445 0.073 0.623 0.697 0.569 0.976
3 2 0.544 0.053 0.762 0.566 0.288 0.793
3 0.599 0.101 0.639 0.493 0.42 0.69
4 2 0.345 0.342 0.453 0.333 0.525 0.466
3 0.268 0.435 0.375 0.465 0.453 0.651
5 3 0.677 0.814 0.648 0.54 0.791 0.756
4 0.222 0.222 0.311 0.208 0.289 0.391
6 4 0.558 0.353 0.782 0.21 0.246 0.294
5 0.454 0.111 0.636 0.697 0.249 0.976

Table 4 Simulation results for Bayes estimators under mean square errors and LINEX loss function at p1 = 0.01, p2 = 0.16 and R = 0.95. 

n m BAYES with MSE BAYES with LINEX loss function
R^MS MSE Converge R^LL MSE Converge
2 2 0.179 0.818 0.188 0.772 0.229 0.813
3 2 0.171 0.005 0.18 0.442 0.319 0.465
3 0.934 0.548 0.563 0.54 0.044 0.568
4 2 0.747 0.546 0.786 0.811 0.256 0.854
3 0.341 0.852 0.359 0.805 0.365 0.847
5 3 0.946 0.681 0.996 0.579 0.855 0.609
4 0.074 0.004 0.078 0.27 0.068 0.284
6 4 0.861 0.707 0.606 0.727 0.423 0.765
5 0.334 0.012 0.352 0.601 0.031 0.633

Table 5 Simulation results for exact, bootstrap and Bayes confidence interval at p1 = 0.01, p2 = 0.16 and R = 0.714. 

n m 95% CI of the length of Exact CI 95% CI of the length of Bootstrap CI 95% CI of the length of Bayes CI
2 2 1.765*10^-5 0.224 1.660*10^-4
3 2 2.823*10^-5 0.479 2.623*10^-4
3 4.741*10^-5 0.201 4.657*10^-3
4 2 1.043*10^-3 0.431 1.232*10^-5
3 4.899*10^-6 0.692 3.099*10^-5
5 3 2.839*10^-5 0.235 3.222*10^-4
4 2.419*10^-6 0.459 2.543*10^-6
6 4 2.86*10^-7 1.397 2.543*10^-6
5 7.696*10^-7 0.425 6.777*10^-7
6 3.775*10^-7 0.302 4.723*10^-7

Table 6 Simulation results for exact, bootstrap and Bayes confidence interval at p1 = 0.01, p = 0.16 and R = 0.95. 

n m 95% CI of the length of Exact CI 95% CI of the length of Bootstrap CI 95% CI of the length of Bayes CI
2 2 3.025*10^-4 0.119 2.111*10^-3
3 2 6.603*10^-5 0.149 5.344*10^-4
3 5.720*10^-7 0.137 7.502*10^-6
4 2 1.31*10^-6 0.147 2.222*10^-6
3 5.637*10^-6 0.277 8.324*10^-6
5 3 4.127*10^-8 0.116 5.1322*10^-7
4 1.291*10^-7 0.159 3.2657*10^-7
6 4 6.213*10^-8 0.186 5.121*10^-6
5 1.917*10^-8 0.216 3.777*10^-8
6 2.415*10^-8 0.115 1.400*10^-8

6. Conclusion

In this paper, the MLE and Bayesian estimators are derived for R when the stress and strength variables are independently geometric distributions based on lower record values. The exact, bootstrap and Bayesian confidence intervals are investigated.

Generally, the coverage percentage of MLE is better than coverage percentage of the Bayes estimator.

Regarding, the number of records n and m for stress- strength modelvaribles.it is observed that the coverage percentage is increase as n and m increase and vice versa.

The estimate values of MLE is better than coverage percentage of the Bayes estimator at R = 0.714 and 0.95.

The average confidence interval lengths of the exact method are shorter than the corresponding average confidence interval lengths of the bootstrap and Bayes method.

The MSEs of the Bayesian estimator under MSE loss function are less than the LINEX loss function.

References

Ahsanullah, M. (1995). Record Statistics, Nova Science Publishers, New York. [ Links ]

Arnold, B. C., Balakrishnan, N., & Nagaraja, H. N. (1998). Records (Vol. 768). John Wiley & Sons. [ Links ]

Ahsanullah, M. (2004). Record values- theory and applications. University Press of America. Lanham, Maryland USA. [ Links ]

Birnbaum, Z. W. (1956). On a use of the Mann-Whitney statistic. In Proceedings of the Third Berkeley Symposium on Mathematical Statistics and Probability , Volume 1: Contributions to the Theory of Statistics. The Regents of the University of California. [ Links ]

Baklizi, A. (2008). Estimation of Pr (X < Y) using record values in the one and two parameter exponential distributions. Communications in Statistics-Theory and Methods, 37(5), 692-698. https://doi.org/10.1080/03610920701501921 [ Links ]

Baklizi, A. (2014). Bayesian inference for Pr (Y< X) in the exponential distribution based on records. Applied Mathematical Modelling, 38(5-6), 1698-1709. https://doi.org/10.1016/j.apm.2013.09.003 [ Links ]

Chandler, K. N. (1952). The distribution and frequency of record values. Journal of the Royal Statistical Society: Series B (Methodological), 14(2), 220-228. https://doi.org/10.1111/j.2517-6161.1952.tb00115.x [ Links ]

Essam, A. A. (2012). Bayesian and non-Bayesian estimation of from type I generalized logistic distribution based on lower record values. Aust J Basic Appl Sci, 6(3), 616-621. [ Links ]

Hussian, M. A. (2013). Estimation of P (Y< X) for the class of Kumaraswamy-G distributions. Austral. Journal of Basic and Applied Sciences, Sci, 7(11), 158-169. [ Links ]

Hassan, A. S., Muhammed, H. Z., & Saad, M. S. (2015). Estimation of stress-strength reliability for exponentiated inverted Weibull distribution based on lower record values. Journal of Advances in Mathematics and Computer Science, 11(2), 1-14. https://doi.org/10.9734/BJMCS/2015/19829 [ Links ]

Kotz, S., & Pensky, M. (2003). The stress-strength model and its generalizations: theory and applications. World Scientific. https://doi.org/10.1142/5015 [ Links ]

Kundu, D., & Gupta, R. D. (2005). Estimation of P [Y< X] for generalized exponential distribution. Metrika, 61(3), 291-308. https://doi.org/10.1007/s001840400345 [ Links ]

Kundu, D., & Gupta, R. D. (2006). Estimation of P [Y< X] for Weibull distributions. IEEE Trans. Reliability, 55(2), 270-280. [ Links ]

Lindley, D. V. (1980). Approximate bayesian methods. Trabajos de estadística y de investigación operativa, 31(1), 223-245. [ Links ]

Lehmann, E. L. (1999). Elements of Large-Sample Theory. Springer: New York. MR1663158. [ Links ]

Mohamed, M. O. Inference for Reliability and Stress-Strength for Geometric Distribution. SYLWAN, 159(2), 281-289. [ Links ]

Nagaraja, H. N. (1988). Record values and related statistic-a review. Communication in Statistics - Theory and Methods, 17(7), 2223-2238. https://doi.org/10.1080/03610928808829743 [ Links ]

Nkemnole, E. B., & Samiyu, M. A. (2017). Inference on Stress-Strength Reliability for Log-Normal Distribution based on Lower Record Values. AMSE JOURNALS-AMSE IIETA, 22(1), 77-97. [ Links ]

Pitman, J. (1993). Probability Springer texts in statistics, New York: Springer. [ Links ]

Rezaei, S., Tahmasbi, R., & Mahmoodi, M. (2010). Estimation of P [Y< X] for generalized Pareto distribution. Journal of Statistical Planning and Inference, 140(2), 480-494. https://doi.org/10.1016/j.jspi.2009.07.024 [ Links ]

Tarvirdizade, B., & Kazemzadeh Garehchobogh, H. (2014). Interval estimation of stress-strength reliability based on lower record values from inverse Rayleigh distribution. Journal of Quality and Reliability Engineering, 2014. http://doi.org/10.1155/2014/192072 [ Links ]

Walck, C. (2007). Hand-book on statistical distributions for experimentalists. University of Stockholm , 10. Internal Report SUF-PFY/96-01 [ Links ]

Peer Review under the responsibility of Universidad Nacional Autónoma de México.

Received: April 14, 2020; Accepted: June 23, 2020

*Corresponding author. E-mail address: mo11577.mm@gmail.com (M. O. Mohamed).

Creative Commons License This is an open-access article distributed under the terms of the Creative Commons Attribution License