Abstract
The left-truncated Weibull distribution is used in life-time analysis, it has many applications ranging from financial market analysis and insurance claims to the earthquake inter-arrival times.We present a comprehensive analysis of the left-truncated Weibull distribution when the shape, scale or both parameters are unknown and they are determined from the data using the maximum likelihood estimator. We demonstrate that if both the Weibull parameters are unknown then there are sets of sample configurations, with measure greater than zero, for which the maximum likelihood equations do not possess non trivial solutions. The modified critical values of the goodness-of-fit test from the Kolmogorov-Smirnov test statistic when the parameters are unknown are obtained from a quantile analysis. We find that the critical values depend on sample size and truncation level, but not on the actual Weibull parameters. Confirming this behavior, we present a complementary analysis using the Brownian bridge approach as an asymptotic limit of the Kolmogorov-Smirnov statistics and find that both approaches are in good agreement. A power testing is performed for our Kolmogorov-Smirnov goodness-of-fit test and the issues related to the left-truncated data are discussed. We conclude the paper by showing the importance of left-truncated Weibulldistribution hypothesis testing on the duration times of failed marriages in the US, worldwide terrorist attacks, waiting times between stock market orders, and time intervals of radioactive decay.
Highlights
IntroductionIntroduction and preliminariesThe Weibull distribution with scale and shape parameters, α > 0 and β > 0 respectively, is widely used in areas such as statistics, engineering, finance, insurance and biology (e.g. Weibull (1951), Balakrishnan and Cohen (1991), Rinne (2009)), mainly in the context of life-time analysis (survival analysis in medical studies and reliability analysis in engineer-Left-Truncated Weibull Distribution ing)
Introduction and preliminariesThe Weibull distribution with scale and shape parameters, α > 0 and β > 0 respectively, is widely used in areas such as statistics, engineering, finance, insurance and biology (e.g. Weibull (1951), Balakrishnan and Cohen (1991), Rinne (2009)), mainly in the context of life-time analysis
For all cases the asymptotic critical value analysis from the Brownian Bridge confirms the same η dependence as we found in the quantile analysis
Summary
Introduction and preliminariesThe Weibull distribution with scale and shape parameters, α > 0 and β > 0 respectively, is widely used in areas such as statistics, engineering, finance, insurance and biology (e.g. Weibull (1951), Balakrishnan and Cohen (1991), Rinne (2009)), mainly in the context of life-time analysis (survival analysis in medical studies and reliability analysis in engineer-Left-Truncated Weibull Distribution ing). An independent identically distributed (i.i.d.) left-truncated data set τ = (τ1, · · · , τn) of sample size n has the property that τL < τi, i = 1, ..., n for a given non-negative parameter τL, the truncation point (Kendall and Stuart (1979), pp. The left-truncated cumulative Weibull distribution function (cdf) is given by Wingo (1989). Putting τL = 0 in Equation (1) and Equation (2), cdf and pdf of the complete Weibull distribution will be recovered, respectively. The literature on data analysis tends to focus either on complete or censored data, with much less attention paid to truncated data, truncation formally defined as in Kendall and Stuart (1979), In this paper we concentrate on left-truncated (as defined in the above paragraph) data only
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