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2002 | Buch

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Dynamics of Controlled Mechanical Systems with Delayed Feedback

verfasst von: Professor Haiyan Hu, Professor Zaihua Wang

Verlag: Springer Berlin Heidelberg

Enthalten in: Professional Book Archive

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Recent years have witnessed a rapid development of active control of various mechanical systems. With increasingly strict requirements for control speed and system performance, the unavoidable time delays in both controllers and actuators have become a serious problem. For instance, all digital controllers, analogue anti aliasing and reconstruction filters exhibit a certain time delay during operation, and the hydraulic actuators and human being interaction usually show even more significant time delays. These time delays, albeit very short in most cases, often deteriorate the control performance or even cause the instability of the system, be cause the actuators may feed energy at the moment when the system does not need it. Thus, the effect of time delays on the system performance has drawn much at tention in the design of robots, active vehicle suspensions, active tendons for tall buildings, as well as the controlled vibro-impact systems. On the other hand, the properly designed delay control may improve the performance of dynamic sys tems. For instance, the delayed state feedback has found its applications to the design of dynamic absorbers, the linearization of nonlinear systems, the control of chaotic oscillators, etc. Most controlled mechanical systems with time delays can be modeled as the dynamic systems described by a set of ordinary differential equations with time delays.

Inhaltsverzeichnis

Frontmatter

1. Modeling of Delayed Dynamic Systems

Abstract

Time delays may come from the retardation of either a controller or an actuator in controlled mechanical systems. In many cases, it is possible to establish the mathematical model for controlled mechanical systems with time delays from the principles of mechanics and the theory of control. However, this is not always the case. For a great number of practical systems, it is necessary to establish the model on the basis of experimental data. For instance, it would be impossible to establish the model for the retardation of human being if no experiments were made.

Haiyan Hu, Zaihua Wang

2. Fundamentals of Delay Differential Equations

Abstract

This chapter serves as a brief review of some theoretical results of delay differential equations in the form

$$\dot x(t) = f(t,x(t),x(t - {\tau _1}),x(t - {\tau _2}), \cdots ,x(t - {\tau _1})),x \in {R^n},$$

(2.0.1)

where $0 < {\tau _1}{\tau _2} \cdots {\tau _l}$ represent the time delays. The time delays are assumed to be constants hereinafter for simplicity, though it may be more reasonable, from the viewpoint of practice, to regard them as the functions in time t.

Haiyan Hu, Zaihua Wang

3. Stability Analysis of Linear Delay Systems

Abstract

From the viewpoint of mathematicians, the stability problem of a linear delay dynamic system has been solved because a number of sufficient and necessary conditions have been available for the stability analysis when the time delays are given. See, for example, (Stépán 1989), (Qin et al. 1989) and (Hassard 1997). As presented in Section 2.2, however, these conditions do not show any explicit relationship among the system parameters that the engineers are interested in. When those conditions are used, the stability test usually involves very tedious computation such as solving transcendental equations or computing the spectrum of operators.

Haiyan Hu, Zaihua Wang

4. Robust Stability of Linear Delay Systems

Abstract

Difference always exists between a real dynamic system and its mathematical model because of the simplification in modeling, the measurement errors of system parameters, and so on. It is very natural, hence, to study the dynamic systems governed by differential equations involving a number of uncertain parameters. In practice, a dynamic system should be robust stable. The problem of robust stability of linear dynamic systems can be roughly stated as follows. Given a family Ω of linear dynamic systems and a set D on the complex plane, how to construct a computationally tractable technique to determine whether the characteristic roots of every system in Ω fall into D. This problem is usually referred to as the D-stability of Ω. For the stability analysis of a continuous-time dynamic system, D should be the open left half-plane of the complex plane, whereas D should be an open unite circular disk on the complex plane for the stability analysis of a discrete-time dynamic system. As a special, but very important case of D-stability, a system is said to be interval stable if it is asymptotically stable under all parameter combinations when some uncertain parameters vary on their pre-specified intervals respectively.

Haiyan Hu, Zaihua Wang

5. Effects of a Short Time Delay on System Dynamics

Abstract

In many controlled mechanical systems, the unavoidable time delays are much shorter than the shortest period of system vibration. If this is the case, the controllers are usually designed according to well-developed control strategies, say optimal control, neglecting the time delays in the controllers and actuators. After the design, one may wonder whether the controlled system is still asymptotically stable if any short time delays appear in the feedback, whether the system stability is robust with respect to the small variation of feedback gains, and so forth. These questions have been answered in part in previous chapters when the system is of single degree of freedom. Nevertheless, tremendous computational efforts have to be made when the system dimension increases. To reduce the computational cost, hence, approximate approaches are preferable in practice.

Haiyan Hu, Zaihua Wang

6. Dimensional Reduction of Nonlinear Delay Systems

Abstract

Time delays usually give rise to great difficulty in the dynamic analysis of controlled mechanical systems. The difficulty increases so dramatically with an increase of system dimensions that the analytical results for the dynamics of delay systems of high dimensions are considerably few. So, it is highly demanded to develop some techniques for the reduction of system dimensions.

Haiyan Hu, Zaihua Wang

7. Periodic Motions of Nonlinear Delay Systems

Abstract

The study on nonlinear delayed dynamic systems is a tough problem. Only a few theoretical results have been available for those that can model engineering systems. Among the available results, the existence and determination of periodic motions of nonlinear delayed dynamic systems have drawn great attention.

Haiyan Hu, Zaihua Wang

8. Delayed Control of Dynamic Systems

Abstract

In previous chapters, attention is mainly paid to the effect of unavoidable feedback time delays on the dynamics of systems. As mentioned time to time, the time delays can be utilized to improve the control performance of dynamic systems. In this case, the time delay plays a favorable and important role in control. This chapter will present a number of control strategies of delayed feedback from the viewpoints of both vibration reduction and system stabilization.

Haiyan Hu, Zaihua Wang

Backmatter

Titel: Dynamics of Controlled Mechanical Systems with Delayed Feedback
verfasst von: Professor Haiyan Hu
Professor Zaihua Wang
Verlag: Springer Berlin Heidelberg
Electronic ISBN: 978-3-662-05030-9
Print ISBN: 978-3-642-07839-2
DOI: https://doi.org/10.1007/978-3-662-05030-9

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Inhaltsverzeichnis

Frontmatter

1. Modeling of Delayed Dynamic Systems

2. Fundamentals of Delay Differential Equations

3. Stability Analysis of Linear Delay Systems

4. Robust Stability of Linear Delay Systems

5. Effects of a Short Time Delay on System Dynamics

6. Dimensional Reduction of Nonlinear Delay Systems

7. Periodic Motions of Nonlinear Delay Systems

8. Delayed Control of Dynamic Systems

Backmatter