Kunhui Zhang, Abolfazl Safikhani, Alex Tank, Ali Shojaie
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The first penalty corresponds to a natural extension of classical TAR model to high-dimensional settings, where the same threshold is enforced for all model parameters. Our second penalty develops a more flexible TAR model, where different thresholds are allowed for different auto-regressive coefficients. We show that both penalized estimation strategies can be utilized in a three-step procedure that consistently learns both the thresholds and the corresponding auto-regressive coefficients. However, our theoretical and empirical investigations show that the direct extension of the TAR model is not appropriate for high-dimensional settings and is better suited for moderate dimensions. 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引用次数: 0
摘要
自回归过程结构简单、易于解释,因此被广泛用于建立时间序列数据模型。然而,许多真实的时间序列数据集都表现出非线性模式,需要非线性建模。阈值自回归(TAR)过程提供了一系列非线性自回归时间序列模型,其中的过程动态是阈值变量的特定阶跃函数。虽然低维 TAR 模型的估计和推理已经得到研究,但高维 TAR 模型受到的关注较少。在本文中,我们为估计高维 TAR 模型开发了一个新框架,并提出了两种不同的稀疏性诱导惩罚。第一种惩罚相当于将经典 TAR 模型自然扩展到高维环境,在这种情况下,所有模型参数都有相同的阈值。我们的第二种惩罚方法开发了一种更灵活的 TAR 模型,允许对不同的自回归系数采用不同的阈值。我们的研究表明,这两种惩罚估计策略都可以在一个三步程序中使用,该程序可以持续学习阈值和相应的自回归系数。然而,我们的理论和实证研究表明,TAR 模型的直接扩展并不适合高维设置,而更适合中等维度。相比之下,TAR 模型更灵活的扩展则能在高维度下实现一致的估计和卓越的实证性能。
Penalized estimation of threshold auto-regressive models with many components and thresholds.
Thanks to their simplicity and interpretable structure, autoregressive processes are widely used to model time series data. However, many real time series data sets exhibit non-linear patterns, requiring nonlinear modeling. The threshold Auto-Regressive (TAR) process provides a family of non-linear auto-regressive time series models in which the process dynamics are specific step functions of a thresholding variable. While estimation and inference for low-dimensional TAR models have been investigated, high-dimensional TAR models have received less attention. In this article, we develop a new framework for estimating high-dimensional TAR models, and propose two different sparsity-inducing penalties. The first penalty corresponds to a natural extension of classical TAR model to high-dimensional settings, where the same threshold is enforced for all model parameters. Our second penalty develops a more flexible TAR model, where different thresholds are allowed for different auto-regressive coefficients. We show that both penalized estimation strategies can be utilized in a three-step procedure that consistently learns both the thresholds and the corresponding auto-regressive coefficients. However, our theoretical and empirical investigations show that the direct extension of the TAR model is not appropriate for high-dimensional settings and is better suited for moderate dimensions. In contrast, the more flexible extension of the TAR model leads to consistent estimation and superior empirical performance in high dimensions.
期刊介绍:
The Electronic Journal of Statistics (EJS) publishes research articles and short notes on theoretical, computational and applied statistics. The journal is open access. Articles are refereed and are held to the same standard as articles in other IMS journals. Articles become publicly available shortly after they are accepted.