Inference for nonstationary time series of counts with application to change-point problems

IF 0.8 4区数学 Q3 STATISTICS & PROBABILITY

Annals of the Institute of Statistical Mathematics Pub Date : 2022-01-18 DOI:10.1007/s10463-021-00815-1

William Kengne, Isidore S. Ngongo

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引用次数: 3

Abstract

We consider an integer-valued time series \((Y_t)_{t\in {\mathbb {Z}}}\) where the model after a time \(k^*\) is Poisson autoregressive with the conditional mean that depends on a parameter \(\theta ^*\in \varTheta \subset {\mathbb {R}}^d\). The structure of the process before \(k^*\) is unknown; it could be any other integer-valued process, that is, \((Y_t)_{t\in {\mathbb {Z}}}\) could be nonstationary. It is established that the maximum likelihood estimator of \(\theta ^*\) computed on the nonstationary observations is consistent and asymptotically normal. Subsequently, we carry out the sequential change-point detection in a large class of Poisson autoregressive models, and propose a monitoring scheme for detecting change. The procedure is based on an updated estimator, which is computed without the historical observations. The above results of inference in a nonstationary setting are applied to prove the consistency of the proposed procedure. A simulation study as well as a real data application are provided.

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非平稳计数时间序列的推理及其在变点问题中的应用

我们考虑一个整数值时间序列\（（Y_t）_｛t\ in｛\mathbb｛Z｝｝），其中时间之后的模型\（k^*\）是泊松自回归的，其条件均值取决于参数\（\theta^*\ in \varTheta\subet｛\math bb｛R｝}^d\）。在\（k^*\）之前的过程的结构是未知的；它可以是任何其他的整数值过程，即\（（Y_t）_｛t\in｛\mathbb｛Z｝｝）可以是非平稳的。证明了在非平稳观测上计算的\（θ^*\）的最大似然估计是一致的和渐近正态的。随后，我们在一大类泊松自回归模型中进行了序列变化点检测，并提出了一种检测变化的监测方案。该程序基于更新的估计器，该估计器是在没有历史观测的情况下计算的。以上在非平稳环境下的推理结果被用来证明所提出的过程的一致性。提供了仿真研究和实际数据应用。

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

Annals of the Institute of Statistical Mathematics 数学-统计学与概率论

CiteScore

2.00

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Annals of the Institute of Statistical Mathematics (AISM) aims to provide a forum for open communication among statisticians, and to contribute to the advancement of statistics as a science to enable humans to handle information in order to cope with uncertainties. It publishes high-quality papers that shed new light on the theoretical, computational and/or methodological aspects of statistical science. Emphasis is placed on (a) development of new methodologies motivated by real data, (b) development of unifying theories, and (c) analysis and improvement of existing methodologies and theories.