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http://dx.doi.org/10.5351/CSAM.2016.23.5.385

Estimation of P(X > Y) when X and Y are dependent random variables using different bivariate sampling schemes  

Samawi, Hani M. (Department of Biostatistics, Jiann-Ping Hsu College of Public Health, Georgia Southern University)
Helu, Amal (Carnegie Mellon University)
Rochani, Haresh D. (Department of Biostatistics, Jiann-Ping Hsu College of Public Health, Georgia Southern University)
Yin, Jingjing (Department of Biostatistics, Jiann-Ping Hsu College of Public Health, Georgia Southern University)
Linder, Daniel (Department of Biostatistics, Jiann-Ping Hsu College of Public Health, Georgia Southern University)
Publication Information
Communications for Statistical Applications and Methods / v.23, no.5, 2016 , pp. 385-397 More about this Journal
Abstract
The stress-strength models have been intensively investigated in the literature in regards of estimating the reliability ${\theta}$ = P(X > Y) using parametric and nonparametric approaches under different sampling schemes when X and Y are independent random variables. In this paper, we consider the problem of estimating ${\theta}$ when (X, Y) are dependent random variables with a bivariate underlying distribution. The empirical and kernel estimates of ${\theta}$ = P(X > Y), based on bivariate ranked set sampling (BVRSS) are considered, when (X, Y) are paired dependent continuous random variables. The estimators obtained are compared to their counterpart, bivariate simple random sampling (BVSRS), via the bias and mean square error (MSE). We demonstrate that the suggested estimators based on BVRSS are more efficient than those based on BVSRS. A simulation study is conducted to gain insight into the performance of the proposed estimators. A real data example is provided to illustrate the process.
Keywords
bivariate simple random sampling; bivariate ranked set sampling; empirical and kernel estimation; reliability; bias; mean square error;
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  • Reference
1 Zhou W (2008). Statistical inference for P(X < Y), Statistics in Medicine, 27, 257-279.   DOI
2 Wand MP and Jones MC (1995). Kernel Smoothing, Chapman and Hall, London.
3 Yan S, Li J, Li S, Zhang B, Du S, Gordon-Larsen P, Adair L, and Popkin B (2012). The expand- ing burden of cardiometabolic risk in China: the China Health and Nutrition Survey, Obesity Reviews, 13, 810-821.   DOI
4 Awad AM, Azzam MM, and Hamdan MA (1981). Some inference results on Pr(Y < X) in the bivariate exponential model, Communications in Statistics-Theory and Methods, 10, 2515-2525.   DOI
5 Baklizi A and Abu-Dayyeh W (2003). Shrinkage estimation of P(Y < X) in the exponential case, Communications in Statistics-Simulation and Computation, 32, 31-42.   DOI
6 Baklizi A and Eidous O (2006). Nonparametric estimation of P(X < Y) using kernel methods, Metron, 64, 47-60.
7 Barbiero A (2012). Interval estimators for reliability: the bivariate normal case, Journal of Applied Statistics, 39, 501-512.   DOI
8 Al-Hussaini EK, Mousa MA, and Sultan KS (1997). Parametric and nonparametric simulation of P(Y < X) for finite mixtures of lognormal components, Communications in Statistics-Theory and Methods, 26, 1269-1289.   DOI
9 Al-Saleh MF and Zheng G (2002). Estimation of bivariate characteristics using ranked set sampling, Australia and New Zealand Journal of Statistics, 44, 221-232.   DOI
10 Domma F and Giordano S (2012). A stress-strength model with dependent variables to measure household financial fragility, Statistical Methods & Applications, 21, 375-389.   DOI
11 Domma F and Giordano S (2013). A copula based approach to account for dependence in stressstrength models, Statistical Papers, 54, 807-826.   DOI
12 Diaz-Frances E and Montoya JA (2013). The simplicity of likelihood based inferences for P(X < Y) and for the ratio of means in the exponential model, Statistical Papers, 54, 499-522.   DOI
13 Enis P and Geisser S (1971). Estimation of the probability that Y < X, Journal of the American Statistical Association, 66, 162-168.
14 Gupta RC, Ghitany ME, and Al-Mutairi DK (2013). Estimation of reliability from a bivariate log normal data, Journal of Statistical Computation and Simulation, 83, 1068-1081.   DOI
15 Johnson ME (1987). Multivariate Statistical Simulation, John Wiley & Sons, New York.
16 Johnson NL (1975). Letter to the editor, Technometrics, 17, 393.   DOI
17 Kaur A, Patil GP, Sinha AK, and Taillie C (1995). Ranked set sampling: an annotated bibliography, Environmental and Ecological Statistics, 2, 25-54.   DOI
18 Kotz S, Lumelskii S, and Pensky M (2003). The Stress-Strength Model and Its Generalizations: Theory and Applications, World Scientific Publishing, Singapore.
19 Li D, Sinha BK, and Chuiv NN (1999). On estimation of P(X > c) based on a ranked set sample. In UJ Dixit and MR Satam (Eds), Statistical Inference and Design of Experiments (pp. 47-54), Alpha Science International, Oxford, UK.
20 McIntyre GA (1952). A method for unbiased selective sampling, using ranked set, Australian Journal of Agricultural Research, 3, 385-390.   DOI
21 GP, Sinha AK, and Taillie C (1993). Relative precision of ranked set sampling: a comparison with the regression estimator, Environmetrics, 4, 399-412.   DOI
22 Montoya JA and Rubio FJ (2014). Nonparametric inference for P(X < Y) with paired variables, Journal of Data Science, 12, 359-375.
23 Norris RC, Patil GP, and Sinha AK (1995). Estimation of multiple characteristics by ranked set sampling methods, Coenoses, 10, 95-111.
24 Parzen E (1962). On estimation of a probability density function and mode, Annals of Mathematical Statistics, 33, 1065-1076.   DOI
25 GP, Sinha AK, and Taillie C (1994). Ranked set sampling for multiple characteristics, International Journal of Ecology and Environmental Sciences, 20, 94-109.
26 Patil GP, Sinha AK, and Taillie C (1999). Ranked set sampling: a bibliography, Environmental and Ecological Statistics, 6, 91-98.   DOI
27 Rubio FJ and Steel MFJ (2013). Bayesian inference for P(X < Y) using asymmetric dependent distributions, Bayesian Analysis, 8, 43-62.   DOI
28 Samawi HM, Ahmed MS, and Abu-Dayyeh W(1996). Estimating the population mean using extreme ranked set sampling, Biometrical Journal, 38, 577-586.   DOI
29 Samawi HM and Al-Sagheer OA (2001). On the estimation of the distribution function using extreme and median ranked set sampling, Biometrical Journal, 43, 357-373.   DOI
30 Samawi HM and Muttlak HA (1996). Estimation of ratio using ranked set sampling, Biometrical Journal, 38, 753-764.   DOI
31 Samawi HM and Muttlak HA (2001). On ratio estimation using median ranked set sampling, Journal of Applied Statistical Science, 10, 89-98.
32 Ventura L and Racugno W (2011). Recent advances on Bayesian inference for P(X < Y), Bayesian Analysis, 6, 411-428.
33 Sengupta S and Mukhuti S (2008). Unbiased estimation of P(X > Y) for exponential populations using order statistics with application in ranked set sampling, Communications in Statistics-Theory and Methods, 37, 898-916.   DOI
34 Silverman BW (1986). Density Estimation for Statistics and Data Analysis, 26, CRC Press, New York.
35 Tong H (1974). A note on the estimation of Pr(Y < X) in the exponential case, Technometrics, 16, 625.
36 Walldius G and Jungner I (2006). The apoB/apoA-I ratio: a strong, new risk factor for cardiovascular disease and a target for lipid-lowering therapy: a review of the evidence, Journal of Internal Medicine, 259, 493-519.   DOI
37 Walldius G, Jungner I, Aastveit AH, Holme I, Furberg CD, and Sniderman AD (2004). The apoB/apoA-I ratio is better than the cholesterol ratios to estimate the balance between plasma proatherogenic and antiatherogenic lipoproteins and to predict coronary risk, Clinical Chemical Laboratory Medicine, 42, 1355-1363.
38 Muttlak HA, Abu-Dayyeh WA, Saleh MF, and Al-Sawi E (2010). Estimating P(Y < X) using ranked set sampling in case of the exponential distribution, Communications in Statistics-Theory and Methods, 39, 1855-1868.   DOI
39 Nadarajah S (2005). Reliability for some bivariate beta distributions, Mathematical Problems in Engineering, 2005, 101-111.   DOI