非稳态未知过程的参数推断。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Kieran S Owens, Ben D Fulcher
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引用次数: 0

摘要

从二氧化碳浓度变化影响下的气候模式,到由上升神经调节驱动的大脑动态,世界各地都存在非稳态系统。因此,我们需要分析非平稳过程的方法,然而,大多数用于解决科学和工业领域重要问题的时间序列分析方法都做了简化的平稳性假设。非平稳系统分析中的一个重要问题是我们称之为非平稳未知过程参数推断(PINUP)的问题类别。鉴于观测到的时间序列,这涉及推断驱动时间序列非平稳性的参数,而无需了解或推断底层系统的数学模型。在此,我们回顾并统一了 PINUP 算法的各种文献。我们对问题进行了表述,并将各种算法分为以下几类:(1) 降维;(2) 统计时间序列特征;(3) 预测误差;(4) 相空间划分;(5) 递推图;(6) 贝叶斯推理。这种综合方法可以让研究人员找出文献中的空白,并对不同的方法进行系统的比较。我们还证明,现有方法所测试的最常见系统--尤其是非稳态洛伦兹过程和逻辑图--使用简单的统计特征(如窗口均值和方差)就能取得出人意料的好成绩,这破坏了将这些系统上的好成绩作为算法性能证据的做法。然后,我们确定了更具挑战性的问题,许多现有方法在这些问题上表现不佳,而这些问题可用来推动该领域方法论的进步。我们的研究结果统一了对分析非平稳系统的不同科学贡献,并为 PINUP 问题和更广泛的非平稳现象研究提出了新的进展方向。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Parameter inference from a non-stationary unknown process.

Non-stationary systems are found throughout the world, from climate patterns under the influence of variation in carbon dioxide concentration to brain dynamics driven by ascending neuromodulation. Accordingly, there is a need for methods to analyze non-stationary processes, and yet, most time-series analysis methods that are used in practice on important problems across science and industry make the simplifying assumption of stationarity. One important problem in the analysis of non-stationary systems is the problem class that we refer to as parameter inference from a non-stationary unknown process (PINUP). Given an observed time series, this involves inferring the parameters that drive non-stationarity of the time series, without requiring knowledge or inference of a mathematical model of the underlying system. Here, we review and unify a diverse literature of algorithms for PINUP. We formulate the problem and categorize the various algorithmic contributions into those based on (1) dimension reduction, (2) statistical time-series features, (3) prediction error, (4) phase-space partitioning, (5) recurrence plots, and (6) Bayesian inference. This synthesis will allow researchers to identify gaps in the literature and will enable systematic comparisons of different methods. We also demonstrate that the most common systems that existing methods are tested on-notably, the non-stationary Lorenz process and logistic map-are surprisingly easy to perform well on using simple statistical features like windowed mean and variance, undermining the practice of using good performance on these systems as evidence of algorithmic performance. We then identify more challenging problems that many existing methods perform poorly on and which can be used to drive methodological advances in the field. Our results unify disjoint scientific contributions to analyzing the non-stationary systems and suggest new directions for progress on the PINUP problem and the broader study of non-stationary phenomena.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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