相位型零截断泊松-林德利分布及其在继发性癌症模型中的应用

Afrika Statistika Pub Date : 2022-01-01 DOI:10.16929/as/20212.3145.199

Cynthia Mwende Mwau, P. Weke, Bundi Davis Ntwiga, J. Ottieno

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引用次数: 0

摘要

慢性疾病保险在肯尼亚逐渐普及，导致保险公司推出慢性疾病保险产品，其中包括癌症保险政策。然而，与其他慢性疾病不同，癌症可以从起源器官转移到另一个器官，这将导致治疗费用增加。这不能用普通分布建模，因此它已成为许多研究人员感兴趣的领域。零截断相位类型分布用于解决普通分布的这一缺点，因为它可以在建模索赔计数数据时协同这些转换。他们进一步改进了索赔计数数据的建模，因为他们只考虑排除零的索赔计数的正值。这是真实索赔计数数据的本质，因为零索赔频率不能吸引任何索赔严重性金额。在这篇论文中，肯尼亚继发性癌症的总索赔损失估计使用零截断泊松林德利分布。导出了零截断的单参数泊松林德利分布和零截断的双参数泊松林德利分布。构造了它们的复合概率生成函数。利用连续Chapman Kolmogorov方程估计继发性癌症状态的过渡状态，并将其作为索赔数分布的矩阵参数。帕累托分布、广义帕累托分布、威布尔分布、OPPL分布和TPPL分布是本研究在索赔数建模中考虑的分布。研究表明，对于PH-ZTOPPL分布模型，PH-ZTTPPL-广义Pareto模型是模拟肯尼亚继发性癌症病例总损失的最佳模型，而对于PH-ZTTPPL分布模型，PH-ZTTPPL-广义Pareto模型是最佳模型。比较了两种最佳模型，证明ph - zttppl -广义Pareto模型是最佳模型。将该模型与前人研究的PH-TPPL广义Pareto模型进行比较，证明PH-TPPL广义Pareto模型是一个更好的模型，这意味着在估计总损失时应该考虑零索赔计数数据

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Phase Type Zero Truncated Poisson Lindley Distributions and their application in modeling Secondary Cancer Cases

Insurance of chronic illness is slowly gaining ground in Kenya which has lead to insurance firms introducing insurance products of chronic illness among them being cancer insurance policies. However, unlike other chronic illnesses, cancer can move from the organ of origin to another which will consequently lead to increased cost of treatment. This can not be modeled using ordinary distributions hence it has become an area of interest for many researchers. Zero-truncated phase type distributions are used to solve this drawback of ordinary distributions as it can in-cooperate these transitions while modeling claim count data. They further improve modeling of claim count data as they only consider positive values of claim count excluding zeros. This is the nature of real claim count data as zero claim frequency can not attract any claim severity amount. In this paper aggregate claim losses of secondary cancers in Kenya are estimated using Zero-truncated Poisson Lindley distributions. Zero-truncated one parameter as well as Zero-truncated two parameter Poisson Lindley distributions are derived. Their compound probability generating functions are also constructed. The transitions states of secondary cancer states are estimated using continuous Chapman Kolmogorov equation and used as the matrix parameters for the claim count distributions. Pareto, Generalized Pareto, Weibull, OPPL and TPPL distributions are the distributions considered in this research in modeling claim numbers. This study concludes that aggregate losses of secondary cancer cases using Kenyan data are best modeled by PH-ZTOPPL Generalized Pareto model for PH-ZTOPPL distribution models while for PH-ZTTPPL distribution models the best model was PH-ZTTPPL-Generalized Pareto model. The two best models were compared and PH-ZTTPPL-Generalized Pareto model was proven to be the best model. Comparing this model with PH-TPPL Generalized Pareto model from earlier research PH-TPPL Generalized Pareto model proved to be a better model implying that zero claim count data should be considered in estimation of aggregate losses

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Afrika Statistika

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