Y-Thompson regulating control using adaptive predictive fuzzy logic for a micro-satellite

2009 5th International Colloquium on Signal Processing & Its Applications Pub Date : 2009-03-06 DOI:10.1109/CSPA.2009.5069180

R. Nagarajan, Paulraj M P, S. Yaacob, Z. M. Zain, W. Soh, Kay Hoh, A. S. Arshad

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引用次数: 2

Abstract

Attitude control system is designed to change the attitude of a satellite, able to meet pointing requirement, eliminating external disturbances, a low-cost controller as well as a high reliability control system which can be applied and embedded to a real time application. An adaptive predictive Mamdani fuzzy logic controller (FLC) is introduced in this paper. A predictive control is needed to estimate required control torque at the next sampling time since the satellite system is having time delays. The adaptive portion is using a model reference and the response of the satellite is compared to minimize the output error by adapting the adaptive gain to the controller torque. Y-Thompson regulating control is adapted to the satellite system as the reference input throughout the simulation. The design schemes of modeling adaptive and predictive FLC are described as follow: Basic FLC, Predictive FLC and Adaptive and Predictive FLC (APFLC). The simulation results show that the attitude motion can be controlled with adaptive and predictive FLC even in the presence of noise, disturbance and nonlinearity.

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基于自适应预测模糊逻辑的微卫星Y-Thompson调节控制

姿态控制系统旨在改变卫星的姿态，满足指向要求，消除外界干扰，具有低成本的控制器和高可靠性的控制系统，可以应用和嵌入到实时应用中。介绍了一种自适应预测Mamdani模糊控制器(FLC)。由于卫星系统存在时间延迟，需要预测控制来估计下一次采样时所需的控制转矩。自适应部分采用模型参考，比较卫星的响应，通过使自适应增益与控制器转矩相适应，使输出误差最小。在整个仿真过程中，Y-Thompson调节控制作为卫星系统的参考输入。建模自适应和预测FLC的设计方案如下:基本FLC、预测FLC和自适应和预测FLC (APFLC)。仿真结果表明，在存在噪声、干扰和非线性的情况下，采用自适应和预测FLC可以有效地控制姿态运动。

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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2009 5th International Colloquium on Signal Processing & Its Applications

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