Spherical autoregressive models, with application to distributional and compositional time series

IF 9.9 3区 经济学 Q1 ECONOMICS Journal of Econometrics Pub Date : 2024-02-01 DOI:10.1016/j.jeconom.2022.12.008
Changbo Zhu , Hans-Georg Müller
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Abstract

We introduce a new class of autoregressive models for spherical time series. The dimension of the spheres on which the observations of the time series are situated may be finite-dimensional or infinite-dimensional, where in the latter case we consider the Hilbert sphere. Spherical time series arise in various settings. We focus here on distributional and compositional time series. Applying a square root transformation to the densities of the observations of a distributional time series maps the distributional observations to the Hilbert sphere, equipped with the Fisher–Rao metric. Likewise, applying a square root transformation to the components of the observations of a compositional time series maps the compositional observations to a finite-dimensional sphere, equipped with the geodesic metric on spheres. The challenge in modeling such time series lies in the intrinsic non-linearity of spheres and Hilbert spheres, where conventional arithmetic operations such as addition or scalar multiplication are no longer available. To address this difficulty, we consider rotation operators to map observations on the sphere. Specifically, we introduce a class of skew-symmetric operators such that the associated exponential operators are rotation operators that for each given pair of points on the sphere map the first point of the pair to the second point of the pair. We exploit the fact that the space of skew-symmetric operators is Hilbertian to develop autoregressive modeling of geometric differences that correspond to rotations of spherical and distributional time series. Differences expressed in terms of rotations can be taken between the Fréchet mean and the observations or between consecutive observations of the time series. We derive theoretical properties of the ensuing autoregressive models and showcase these approaches with several motivating data. These include a time series of yearly observations of bivariate distributions of the minimum/maximum temperatures for a period of 120 days during each summer for the years 1990-2018 at Los Angeles (LAX) and John F. Kennedy (JFK) international airports. A second data application concerns a compositional time series with annual observations of compositions of energy sources for power generation in the U.S..

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球面自回归模型,应用于分布和组成时间序列
我们为球形时间序列引入了一类新的自回归模型。时间序列观测值所在的球面维度可以是有限维或无限维,在后一种情况下,我们考虑希尔伯特球面。球形时间序列出现在各种场合。在此,我们重点讨论分布式和组成式时间序列。对分布式时间序列的观测值密度进行平方根变换,可将分布式观测值映射到希尔伯特球面上,并配备费雪-拉奥度量。同样,对组成型时间序列观测值的分量进行平方根变换,可将组成型观测值映射到一个有限维的球面上,球面上配有测地公设。对这类时间序列建模的挑战在于球体和希尔伯特球的内在非线性,在这种情况下,加法或标量乘法等传统算术运算不再可用。为了解决这一难题,我们考虑用旋转算子来映射球面上的观测数据。具体来说,我们引入了一类偏斜对称算子,相关的指数算子是旋转算子,对于球面上的每一对给定点,都能将这对点中的第一点映射到这对点中的第二点。我们利用斜对称算子空间是希尔伯特空间这一事实,建立了几何差异的自回归模型,这些差异对应于球面和分布时间序列的旋转。用旋转表示的差异可以是弗雷谢特均值与观测值之间的差异,也可以是时间序列连续观测值之间的差异。我们推导出随之而来的自回归模型的理论属性,并用几个激励数据展示了这些方法。这些数据包括 1990-2018 年洛杉矶国际机场(LAX)和肯尼迪国际机场(JFK)每年夏季 120 天内最低/最高温度双变量分布的年度观测时间序列。第二个数据应用涉及美国发电能源构成的年度观测构成时间序列。
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来源期刊
Journal of Econometrics
Journal of Econometrics 社会科学-数学跨学科应用
CiteScore
8.60
自引率
1.60%
发文量
220
审稿时长
3-8 weeks
期刊介绍: The Journal of Econometrics serves as an outlet for important, high quality, new research in both theoretical and applied econometrics. The scope of the Journal includes papers dealing with identification, estimation, testing, decision, and prediction issues encountered in economic research. Classical Bayesian statistics, and machine learning methods, are decidedly within the range of the Journal''s interests. The Annals of Econometrics is a supplement to the Journal of Econometrics.
期刊最新文献
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