Sage Journals: Discover world-class research

Abstract

Estimating parameters accurately in the presence of uncertain and imprecise data is a key challenge in statistical analysis, particularly for complex models involving two populations. Fuzzy data provides a structured way to handle such uncertainties by effectively representing real-world ambiguity. While extensive research has been conducted on parameter estimation for single-population models using fuzzy data, extending these methods to dual populations remains a difficult task. This study addresses the issue by developing estimation techniques for two Weibull distributions that share a common scale parameter $σ$ but have different shape parameters $k_{1}$ and $k_{2}$ , under fuzzy data conditions. We apply the expectation-maximization (EM) algorithm for Maximum Likelihood estimation and utilize a Bayesian approach with TK approximation for parameter estimation. To further refine Bayesian estimates, Gibbs sampling is employed to derive posterior distributions. Through Monte Carlo simulations on both simulated and real-world datasets, we evaluate the accuracy and robustness of our estimators, demonstrating their effectiveness in handling imprecise data. Additionally, asymptotic and HPD confidence intervals are also obtained. This research highlights the importance of reliable statistical methods for dual-population Weibull models, contributing to improved analytical precision across various domains.

Keywords

Gibbs sampling EM algorithm TK approximation Fuzzy data Weibull distribution

Get full access to this article

View all access options for this article.

References

Ashok

Nagamani

(2024). Estimating common parameters of different continuous distributions. Proceedings on Engineering, 6(3), 1273–1286.

Ashok

Nagamani

(2025a). Adaptive estimation: Fuzzy data-driven gamma distribution via Bayesian and maximum likelihood approaches. AIMS Mathematics, 10(1), 438–459.

Ashok

Nagamani

(2025b). Enhancing Lindley distribution parameter estimation with hybrid Bayesian average model for fuzzy data. Reliability: Theory & Applications, 20(1 (82)), 528–542.

Balakrishnan

Kateri

(2008). On the maximum likelihood estimation of parameters of Weibull distribution based on complete and censored data. Statistics & Probability Letters, 78(17), 2971–2975.

Basharat

Mustafa

Mahmood

Jun

Y. B.

(2019). Inference for the linear combination of two independent exponential random variables based on fuzzy data. Hacettepe Journal of Mathematics and Statistics, 48(6), 1859–1869.

Coppi

Gil

M. A.

Kiers

H. A.

(2006). The fuzzy approach to statistical analysis. Computational Statistics & Data Analysis, 51(1), 1–14.

Denoeux

(2011). Maximum likelihood estimation from fuzzy data using the em algorithm. Fuzzy Sets and Systems, 183(1), 72–91.

Huang

H.-Z.

Zuo

M. J.

Sun

Z.-Q.

(2006). Bayesian reliability analysis for fuzzy lifetime data. Fuzzy Sets and Systems, 157(12), 1674–1686.

Khoolenjani

N. B.

Shahsanaie

(2016). Estimating the parameter of exponential distribution under type-II censoring from fuzzy data. Journal of Statistical Theory and Applications, 15(2), 181–195.

10.

Lai

Murthy

Xie

(2011). Weibull distributions. Wiley Interdisciplinary Reviews: Computational Statistics, 3(3), 282–287.

11.

Pak

Parham

G. A.

Saraj

(2013a). Inference for the Weibull distribution based on fuzzy data. Revista Colombiana de Estadistica, 36(2), 337–356.

12.

Pak

Parham

G. A.

Saraj

(2013b). On estimation of rayleigh scale parameter under doubly type-II censoring from imprecise data. Journal of Data Science, 11(2), 305–322.

13.

Stone

Van Heeswijk

(1977). Parameter estimation for the Weibull distribution. IEEE Transactions on Electrical Insulation, EI-12(4), 253–261.

14.

Tan

(2009). A new approach to MLE of Weibull distribution with interval data. Reliability Engineering & System Safety, 94(2), 394–403.

15.

Tierney

Kadane

J. B.

(1986). Accurate approximations for posterior moments and marginal densities. Journal of the American Statistical Association, 81(393), 82–86.

16.

Yang

M.-S.

C.-F.

(1994). On parameter estimation for normal mixtures based on fuzzy clustering algorithms. Fuzzy Sets and Systems, 68(1), 13–28.

17.

Yang

Lin

D. K.

(2007). Improved maximum-likelihood estimation for the common shape parameter of several Weibull populations. Applied Stochastic Models in Business and Industry, 23(5), 373–383.

Robust Parameter Estimation for Dual-population Weibull Models under Fuzzy Data Conditions

Abstract

Keywords

Get full access to this article

References