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Optimization for Software Implementation of Fractional Calculus Numerical Methods in an Embedded System

机译：嵌入式系统中分数微积分数值方法的优化

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摘要

In this article, some practical software optimization methods for implementations of fractional order backward difference, sum, and differintegral operator based on Grünwald–Letnikov definition are presented. These numerical algorithms are of great interest in the context of the evaluation of fractional-order differential equations in embedded systems, due to their more convenient form compared to Caputo and Riemann–Liouville definitions or Laplace transforms, based on the discrete convolution operation. A well-known difficulty relates to the non-locality of the operator, implying continually increasing numbers of processed samples, which may reach the limits of available memory or lead to exceeding the desired computation time. In the study presented here, several promising software optimization techniques were analyzed and tested in the evaluation of the variable fractional-order backward difference and derivative on two different Arm® Cortex®-M architectures. Reductions in computation times of up to 75% and 87% were achieved compared to the initial implementation, depending on the type of Arm® core.

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期刊名称 Entropy
作者
Mariusz Matusiak;
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作者单位

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年(卷),期 2020(22),5
年度 2020
页码 566
总页数 14
原文格式 PDF
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关键词
fractional-order differential equations; Grünwald–Letnikov differintegral; fractional-order backward difference/sum; Arm;

机译：分数级微分方程;Grünwald-letnikov不同的恒星;分数阶落后差分/总和;手臂;

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专利

1. A fractional calculus approach to the dynamic optimization of biological reactive systems. Part II: Numerical solution of fractional optimal control problems [J] . Rasiel Toledo-Hernandez, Vicente Rico-Ramirez, Ramiro Rico-Martinez, Chemical Engineering Science . 2014,第Null期

机译：用于生物反应系统动态优化的分数演算方法。第二部分：分数最优控制问题的数值解
2. In this paper, we implement the fractional complex transform method to convert the nonlinear fractional Klein-Gordon equation (FKGE) to an ordinary differential equation. We use the variational iteration method (VIM) to solve the resulting ODE. The fractional derivatives are presented in terms of the Caputo sense. Some numerical examples are presented to validate the proposed techniques. Finally, a comparison with the numerical solution using Runge-Kutta of order four is given. [J] . M. M. Khader, M. Adel Nonlinear engineering: Modeling and application . 2016,第3期

机译：在本文中，我们采用分数阶复杂变换方法将非线性分数阶Klein-Gordon方程（FKGE）转换为常微分方程。我们使用变分迭代方法（VIM）来解决所得的ODE。分数导数以Caputo形式表示。提出了一些数值例子来验证所提出的技术。最后，与使用四阶Runge-Kutta的数值解进行了比较。
3. Fractional Integro-Differential Calculus and Its Control-theoretical Applications. II. Fractional Dynamic Systems: Modeling and Hardware Implementation [J] . A. G. Butkovskii, S. S. Postnov, E. A. Postnova Automation and Remote Control . 2013,第5期

机译：分数积分微分计算及其控制理论应用。二。分数动态系统：建模和硬件实现
4. Fast Numerical Implementation for Variable Order Fractional Calculus Operator Based on Polynomial Fitting Method in Time Domain [C] . Jiacai Huang, Kai Hu, Xinxin Shi, Chinese Control Conference . 2018

机译：基于时域多项式拟合方法的变阶分数阶微积分算子快速数值实现
5. Energy-aware hardware and software optimizations for embedded systems. [D] . Kim, Hyun Suk. 2003

机译：嵌入式系统的能源感知硬件和软件优化。
6. Parallel Implementation of Modeling of Fractional-Order State-Space Systems Using the Fixed-Step Euler Method [O] . Rafał Stanisławski, Kamil Kozioł 2019

机译：使用固定步骤欧拉方法的分数级状态空间系统建模的平行实现
7. Optimization for Software Implementation of Fractional Calculus Numerical Methods in an Embedded System [O] . Mariusz Matusiak 2020

机译：嵌入式系统中分数微积分数值方法的优化

Optimization for Software Implementation of Fractional Calculus Numerical Methods in an Embedded System

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