Abstract
In this study, we propose to apply the transmuted log-logistic (TLL) model which is a generalization of log-logistic model, in a Bayesian context. The log-logistic model has been used it is simple and has a unimodal hazard rate, important characteristic in survival analysis. Also, the TLL model was formulated by using the quadratic transmutation map, that is a simple way of derivating new distributions, and it adds a new parameter λ , which one introduces a skewness in the new distribution and preserves the moments of the baseline model. The Bayesian model was formulated by using the half-Cauchy prior which is an alternative prior to a inverse Gamma distribution. In order to fit the model, a real data set, which consist of the time up to first calving of polled Tabapua race, was used. Finally, after the model was fitted, an influential analysis was made and excluding only 0.1 % of observations (influential points), the reestimated model can fit the data better.
Highlights
The genetic prepotency of cows is an important issue since the development of livestock is directly related to the growth of the food production
Due to good characteristics of the TTL model along with its simplicity and the hazard properties, this paper present an application of the model in a Bayesian context
Considering the hyerarchical transmuted log-logistic (TLL) fitting, the Tmax is equals to 546.77 days (18.23 months) and its 95% confidence interval is given by IC[Tmax, 95%] = (460.04; 652.86) days
Summary
The genetic prepotency of cows is an important issue since the development of livestock is directly related to the growth of the food production. Due to the economic results of this particular race, this study is twofold: present the TLL model and fit the times up to the first calving of the cows pointing characteristics of this race. Due to good characteristics of the TTL model along with its simplicity (the main functions are analytically expressed) and the hazard properties (it has a larger range of choices for the shape of the hazard function most commonly observed in the survival analysis field), this paper present an application of the model in a Bayesian context.
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