Efficient parameter estimation for multivariate accelerated failure time model via the quadratic inference functions method

IF 0.9 4区数学 Q4 PHYSICS, MATHEMATICAL

Random Matrices-Theory and Applications Pub Date : 2019-10-23 DOI:10.1142/S2010326319500138

L. Fu, Zhuoran Yang, Mingtao Zhao, Yan Zhou

引用次数: 0

Abstract

A popular approach, generalized estimating equations (GEE), has been applied to the multivariate accelerated failure time (AFT) model of the clustered and censored data. However, this method needs to estimate the correlation parameters and calculate the inverse of the correlation matrix. Meanwhile, the efficiency of the parameter estimators is low when the correlation structure is misspecified and/or the marginal distribution is heavy-tailed. This paper proposes using the quadratic inference functions (QIF) with a mixture correlation structure to estimate the coefficients in the multivariate AFT model, which can avoid estimating the correlation parameters and computing the inverse matrix of the correlation matrix. Moreover, the estimator derived from the QIF is consistent and asymptotically normal. Simulation studies indicate that the proposed method outperforms the method based on GEE when the marginal distribution has a heavy tail. Finally, the proposed method is used to analyze a real dataset for illustration.

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基于二次推理函数的多变量加速失效时间模型的有效参数估计

一种流行的方法，广义估计方程(GEE)，已被应用于聚类和截尾数据的多元加速失效时间(AFT)模型。但是，该方法需要估计相关参数并计算相关矩阵的逆。同时，当相关结构不明确或边缘分布重尾时，参数估计器的效率较低。本文提出了一种混合相关结构的二次推理函数(QIF)来估计多元AFT模型的系数，避免了估计相关参数和计算相关矩阵的逆矩阵。此外，由QIF导出的估计量是一致的和渐近正态的。仿真研究表明，在边缘分布有重尾的情况下，该方法的性能优于基于GEE的方法。最后，用该方法对一个真实数据集进行了分析。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Random Matrices-Theory and Applications Decision Sciences-Statistics, Probability and Uncertainty

CiteScore

1.90

自引率

11.10%

发文量

期刊介绍： Random Matrix Theory (RMT) has a long and rich history and has, especially in recent years, shown to have important applications in many diverse areas of mathematics, science, and engineering. The scope of RMT and its applications include the areas of classical analysis, probability theory, statistical analysis of big data, as well as connections to graph theory, number theory, representation theory, and many areas of mathematical physics. Applications of Random Matrix Theory continue to present themselves and new applications are welcome in this journal. Some examples are orthogonal polynomial theory, free probability, integrable systems, growth models, wireless communications, signal processing, numerical computing, complex networks, economics, statistical mechanics, and quantum theory. Special issues devoted to single topic of current interest will also be considered and published in this journal.