Abstract
In this paper we discuss the multistage sequential estimation of the variance of the Rayleigh distribution using the three-stage procedure that was presented by Hall (Ann. Stat. 9(6):1229–1238, 1981). Since the Rayleigh distribution variance is a linear function of the distribution scale parameter’s square, it suffices to estimate the Rayleigh distribution’s scale parameter’s square. We tackle two estimation problems: first, the minimum risk point estimation problem under a squared-error loss function plus linear sampling cost, and the second is a fixed-width confidence interval estimation, using a unified optimal stopping rule. Such an estimation cannot be performed using fixed-width classical procedures due to the non-existence of a fixed sample size that simultaneously achieves both estimation problems. We find all the asymptotic results that enhanced finding the three-stage regret as well as the three-stage fixed-width confidence interval for the desired parameter. The procedure attains asymptotic second-order efficiency and asymptotic consistency. A series of Monte Carlo simulations were conducted to study the procedure’s performance as the optimal sample size increases. We found that the simulation results agree with the asymptotic results.
Highlights
Rayleigh distribution was presented by Rayleigh [1] in 1880 and primarily proposed in the context of a problem in acoustics and optics
We noticed that the simulation results agree with our findings while the coverage probability improves as the optimal sample size increases
We have proposed a three-stage sequential procedure for estimating the Rayleigh distribution variance by estimating the Rayleigh distribution scale parameter’s square
Summary
Rayleigh distribution was presented by Rayleigh [1] in 1880 and primarily proposed in the context of a problem in acoustics and optics. Yousef et al [13] discussed the Rayleigh distribution scale parameter’s multistage estimation using Hall’s [14] three-stage procedure They tackled two estimation problems, point and confidence interval estimation, under a unified optimal stopping rule. Tahir [17] proposed a purely sequential procedure to tackle the point estimation problem for the square of the scale parameter of the Rayleigh distribution, using a weighted squared-error loss function plus the cost of sampling. He found a second-order asymptotic expansion for the incurred regret and proved that the asymptotic regret is negative for a range of parameter values.
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