{"title":"不确定性条件下的动态系统控制算法。第一部分","authors":"V. I. Shiryaev","doi":"10.17587/mau.25.279-288","DOIUrl":null,"url":null,"abstract":"The paper considers the control of dynamic systems (DS) in situations with a high level of uncertainty caused by disturbances acting on the DS and interference in information channels during operation. Uncertainty results from the action of various external disturbing factors, uncontrolled changes in the object properties, and equipment failures and malfunctions. A peculiar feature of these control problems is that they are single events. In these conditions, the synthesis of positional control of dynamic systems is considered based on the minimax approach — worst-case design. The mathematical model of processes is characterized by disturbances and measurement errors known with a precision up to sets. The DS state vector is known with a precision up to membership in the information set as a result of solving the estimation problem. The proposed approach combines N. N. Krasovsky’s control concepts under information deficiency and A. A. Krasovsky’s concepts of building self-organizing systems. The “principle of a guaranteed result” was chosen to synthesize DS control. A control problem is solved in two stages in incomplete information. At the first stage, the state vector estimation problem is solved. The paper considers several implementations of estimation algorithms. It also proposes a minimax filtration algorithm based on the use of three filters (minimax filter (MMF), Kalman filter (KF), and guaranteeing filter (GF)) which can increase the estimation accuracy and make the proposed minimax filtration algorithm adaptable. The author discusses the implementation of the proposed algorithm and considers examples. 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引用次数: 0
摘要
本文探讨了动态系统(DS)在高度不确定的情况下的控制问题,这种不确定是由作用于动态系统的干扰和运行过程中的信息通道干扰造成的。不确定性源于各种外部干扰因素的作用、对象属性的不可控变化以及设备故障和失灵。这些控制问题的一个特点是它们都是单一事件。在这种情况下,动态系统位置控制的综合考虑基于最小法--最坏情况设计。过程的数学模型以扰动和测量误差为特征,测量误差的精度可达到集。作为解决估计问题的结果,DS 状态矢量的已知精度可达信息集合中的成员。所提出的方法结合了 N. N. Krasovsky 在信息不足情况下的控制概念和 A. A. Krasovsky 建立自组织系统的概念。选择 "保证结果原则 "来综合 DS 控制。在信息不完全的情况下,控制问题分两个阶段解决。在第一阶段,解决状态矢量估计问题。本文考虑了几种估计算法的实现方法。它还提出了一种基于使用三种滤波器(最小滤波器 (MMF)、卡尔曼滤波器 (KF) 和保证滤波器 (GF))的最小滤波算法,该算法可以提高估计精度,并使所提出的最小滤波算法具有适应性。作者讨论了所提算法的实现,并举例说明。论文的第二部分解决了控制问题。
Algorithms for Controlling Dynamic Systems under Uncertainty. Part 1
The paper considers the control of dynamic systems (DS) in situations with a high level of uncertainty caused by disturbances acting on the DS and interference in information channels during operation. Uncertainty results from the action of various external disturbing factors, uncontrolled changes in the object properties, and equipment failures and malfunctions. A peculiar feature of these control problems is that they are single events. In these conditions, the synthesis of positional control of dynamic systems is considered based on the minimax approach — worst-case design. The mathematical model of processes is characterized by disturbances and measurement errors known with a precision up to sets. The DS state vector is known with a precision up to membership in the information set as a result of solving the estimation problem. The proposed approach combines N. N. Krasovsky’s control concepts under information deficiency and A. A. Krasovsky’s concepts of building self-organizing systems. The “principle of a guaranteed result” was chosen to synthesize DS control. A control problem is solved in two stages in incomplete information. At the first stage, the state vector estimation problem is solved. The paper considers several implementations of estimation algorithms. It also proposes a minimax filtration algorithm based on the use of three filters (minimax filter (MMF), Kalman filter (KF), and guaranteeing filter (GF)) which can increase the estimation accuracy and make the proposed minimax filtration algorithm adaptable. The author discusses the implementation of the proposed algorithm and considers examples. The second part of the paper solves the control problem.