Bayesian inference in nonparametric dynamic state-space models

Q Mathematics

Statistical Methodology Pub Date : 2014-11-01 DOI:10.1016/j.stamet.2014.02.004

Anurag Ghosh , Soumalya Mukhopadhyay , Sandipan Roy , Sourabh Bhattacharya

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引用次数: 17

Abstract

We introduce state-space models where the functionals of the observational and evolutionary equations are unknown, and treated as random functions evolving with time. Thus, our model is nonparametric and generalizes the traditional parametric state-space models. This random function approach also frees us from the restrictive assumption that the functional forms, although time-dependent, are of fixed forms. The traditional approach of assuming known, parametric functional forms is questionable, particularly in state-space models, since the validation of the assumptions require data on both the observed time series and the latent states; however, data on the latter are not available in state-space models.

We specify Gaussian processes as priors of the random functions and exploit the “look-up table approach” of Bhattacharya (2007) to efficiently handle the dynamic structure of the model. We consider both univariate and multivariate situations, using the Markov chain Monte Carlo (MCMC) approach for studying the posterior distributions of interest. We illustrate our methods with simulated data sets, in both univariate and multivariate situations. Moreover, using our Gaussian process approach we analyze a real data set, which has also been analyzed by Shumway & Stoffer (1982) and Carlin, Polson & Stoffer (1992) using the linearity assumption. Interestingly, our analyses indicate that towards the end of the time series, the linearity assumption is perhaps questionable.

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非参数动态状态空间模型中的贝叶斯推理

我们引入状态空间模型，其中观测方程和进化方程的函数是未知的，并将其视为随时间进化的随机函数。因此，我们的模型是非参数的，并推广了传统的参数状态空间模型。这种随机函数方法也使我们摆脱了函数形式虽然依赖于时间，但却是固定形式的限制性假设。假设已知参数函数形式的传统方法是有问题的，特别是在状态空间模型中，因为假设的验证需要观察到的时间序列和潜在状态的数据;然而，后者的数据在状态空间模型中是不可用的。我们指定高斯过程作为随机函数的先验，并利用Bhattacharya(2007)的“查找表方法”来有效地处理模型的动态结构。我们考虑了单变量和多变量情况，使用马尔可夫链蒙特卡罗(MCMC)方法来研究感兴趣的后验分布。我们在单变量和多变量情况下用模拟数据集说明我们的方法。此外，使用我们的高斯过程方法，我们分析了一个真实的数据集，该数据集也被Shumway &Stoffer(1982)和Carlin, Polson &;Stoffer(1992)使用线性假设。有趣的是，我们的分析表明，在时间序列的末尾，线性假设可能是有问题的。

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

Statistical Methodology STATISTICS & PROBABILITY-

CiteScore

0.59

自引率

0.00%

发文量

期刊介绍： Statistical Methodology aims to publish articles of high quality reflecting the varied facets of contemporary statistical theory as well as of significant applications. In addition to helping to stimulate research, the journal intends to bring about interactions among statisticians and scientists in other disciplines broadly interested in statistical methodology. The journal focuses on traditional areas such as statistical inference, multivariate analysis, design of experiments, sampling theory, regression analysis, re-sampling methods, time series, nonparametric statistics, etc., and also gives special emphasis to established as well as emerging applied areas.