Hurst exponent estimation using neural network

IF 1.4 Q4 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Somenath Mukherjee, Bikash Sadhukhan, Arghya Kusum Das, Abhra Chaudhuri
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引用次数: 2

Abstract

The Hurst exponent is used to identify the autocorrelation structure of a stochastic time series, which allows for detecting persistence in time series data. Traditional signal processing techniques work reasonably well in determining the Hurst exponent of a stochastic time series. However, a notable drawback of these methods is their speed of computation. Neural networks have repeatedly proven their ability to learn very complex input-output mappings, even in high dimensional vector spaces. Therefore, an endeavour has been undertaken to employ neural networks to determine the Hurst exponent of a stochastic time series. Unlike previous attempts to solve such problems using neural networks, the proposed architecture can be recognised as the universal estimator of Hurst exponent for short-range and long-range dependent stochastic time series. Experiments demonstrate that if sufficiently trained, neural network can predict the Hurst exponent of any stochastic data at least fifteen times faster than standard signal processing approaches.
基于神经网络的Hurst指数估计
Hurst指数用于识别随机时间序列的自相关结构,从而可以检测时间序列数据的持久性。传统的信号处理技术在确定随机时间序列的赫斯特指数方面工作得相当好。然而,这些方法的一个显著缺点是它们的计算速度。神经网络已经多次证明了它们学习非常复杂的输入-输出映射的能力,甚至在高维向量空间中也是如此。因此,我们尝试使用神经网络来确定随机时间序列的赫斯特指数。与以往使用神经网络解决此类问题的尝试不同,所提出的体系结构可以被认为是短期和长期依赖随机时间序列的Hurst指数的通用估计量。实验表明,如果经过充分的训练,神经网络预测任意随机数据的Hurst指数的速度至少是标准信号处理方法的15倍。
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来源期刊
International Journal of Computational Science and Engineering
International Journal of Computational Science and Engineering COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-
CiteScore
4.00
自引率
40.00%
发文量
73
期刊介绍: Computational science and engineering is an emerging and promising discipline in shaping future research and development activities in both academia and industry, in fields ranging from engineering, science, finance, and economics, to arts and humanities. New challenges arise in the modelling of complex systems, sophisticated algorithms, advanced scientific and engineering computing and associated (multidisciplinary) problem-solving environments. Because the solution of large and complex problems must cope with tight timing schedules, powerful algorithms and computational techniques, are inevitable. IJCSE addresses the state of the art of all aspects of computational science and engineering with emphasis on computational methods and techniques for science and engineering applications.
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