Bayesian parameter inference for partially observed stochastic volterra equations

IF 1.6 2区数学 Q2 COMPUTER SCIENCE, THEORY & METHODS

Statistics and Computing Pub Date : 2024-02-14 DOI:10.1007/s11222-024-10389-6

Ajay Jasra, Hamza Ruzayqat, Amin Wu

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Abstract

In this article we consider Bayesian parameter inference for a type of partially observed stochastic Volterra equation (SVE). SVEs are found in many areas such as physics and mathematical finance. In the latter field they can be used to represent long memory in unobserved volatility processes. In many cases of practical interest, SVEs must be time-discretized and then parameter inference is based upon the posterior associated to this time-discretized process. Based upon recent studies on time-discretization of SVEs (e.g. Richard et al. in Stoch Proc Appl 141:109–138, 2021) we use Euler–Maruyama methods for the afore-mentioned discretization. We then show how multilevel Markov chain Monte Carlo (MCMC) methods (Jasra et al. in SIAM J Sci Comp 40:A887–A902, 2018) can be applied in this context. In the examples we study, we give a proof that shows that the cost to achieve a mean square error (MSE) of \(\mathcal {O}(\epsilon ^2)\), \(\epsilon >0\), is \(\mathcal {O}(\epsilon ^{-\tfrac{4}{2H+1}})\), where H is the Hurst parameter. If one uses a single level MCMC method then the cost is \(\mathcal {O}(\epsilon ^{-\tfrac{2(2H+3)}{2H+1}})\) to achieve the same MSE. We illustrate these results in the context of state-space and stochastic volatility models, with the latter applied to real data.

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部分观测随机伏特拉方程的贝叶斯参数推断

在本文中，我们考虑对一种部分观测随机伏特拉方程（SVE）进行贝叶斯参数推断。SVE 存在于物理学和数学金融学等许多领域。在数学金融领域，它们可以用来表示未观测波动过程中的长记忆。在许多实际案例中，SVE 必须进行时间离散化，然后根据与时间离散化过程相关的后验结果进行参数推断。根据最近对 SVE 时间离散化的研究（如 Richard 等人在 Stoch Proc Appl 141:109-138, 2021 年），我们使用 Euler-Maruyama 方法进行上述离散化。然后，我们展示了多级马尔科夫链蒙特卡罗 (MCMC) 方法（Jasra 等人，载于 SIAM J Sci Comp 40:A887-A902, 2018）如何应用于这种情况。在我们研究的例子中，我们给出了一个证明，表明实现均方误差（MSE）为 \(\mathcal {O}(\epsilon ^2)\), \(\epsilon >0\)的代价是 \(\mathcal {O}(\epsilon ^{-\tfrac{4}{2H+1}}), 其中 H 是赫斯特参数。如果使用单级 MCMC 方法，则达到相同 MSE 的成本为 \(\mathcal {O}(\epsilon ^{-\tfrac{2(2H+3)}{2H+1}})\) 。我们结合状态空间模型和随机波动模型来说明这些结果，其中随机波动模型应用于真实数据。

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

Statistics and Computing 数学-计算机：理论方法

CiteScore

3.20

自引率

4.50%

发文量

审稿时长

6-12 weeks

期刊介绍： Statistics and Computing is a bi-monthly refereed journal which publishes papers covering the range of the interface between the statistical and computing sciences. In particular, it addresses the use of statistical concepts in computing science, for example in machine learning, computer vision and data analytics, as well as the use of computers in data modelling, prediction and analysis. Specific topics which are covered include: techniques for evaluating analytically intractable problems such as bootstrap resampling, Markov chain Monte Carlo, sequential Monte Carlo, approximate Bayesian computation, search and optimization methods, stochastic simulation and Monte Carlo, graphics, computer environments, statistical approaches to software errors, information retrieval, machine learning, statistics of databases and database technology, huge data sets and big data analytics, computer algebra, graphical models, image processing, tomography, inverse problems and uncertainty quantification. In addition, the journal contains original research reports, authoritative review papers, discussed papers, and occasional special issues on particular topics or carrying proceedings of relevant conferences. Statistics and Computing also publishes book review and software review sections.