Model study of automatic and automated control of hysteretic object
Title | Model study of automatic and automated control of hysteretic object |
Publication Type | Conference Paper |
Year of Publication | 2017 |
Authors | Zhmud, V., Dimitrov, L., Taichenachev, A. |
Conference Name | 2017 International Siberian Conference on Control and Communications (SIBCON) |
Date Published | June 2017 |
Publisher | IEEE |
ISBN Number | 978-1-5090-1081-3 |
Keywords | artificial additional fluctuation, automated hysteretic object control, Automated Response Actions, Automatic control, automatic hysteretic object control, automobiles, closed loop systems, composability, control loop, control signal, control system synthesis, control systems, Engines, fast switching, feedback, feedback signal, human reaction, hysteresis, Numerical models, Oscillators, PI control, pubcrawl, Regulators, Resiliency, sliding mode control, Switches, Uniform resource locators, variable structure systems, Velocity control |
Abstract | This paper presents the results of research and simulation of feature automated control of a hysteretic object and the difference between automated control and automatic control. The main feature of automatic control is in the fact that the control loop contains human being as a regulator with its limited response speed. The human reaction can be described as integrating link. The hysteretic object characteristic is switching from one state to another. This is followed by a transient process from one to another characteristic. For this reason, it is very difficult to keep the object in a desired state. Automatic operation ensures fast switching of the feedback signal that produces such a mode, which in many ways is similar to the sliding mode. In the sliding mode control signal abruptly switches from maximum to minimum and vice versa. The average value provides the necessary action to the object. Theoretical analysis and simulation show that the use of the maximum value of the control signal is not required. It is sufficient that the switching oscillation amplitude is such that the output signal varies with the movement of the object along both branches with hysteretic characteristics in the fastest cycle. The average output value in this case corresponds to the prescribed value of the control task. With automated control, the human response can be approximately modeled by integrating regulator. In this case the amplitude fluctuation could be excessively high and the frequency could be excessively low. The simulation showed that creating an artificial additional fluctuation in the control signal makes possible to provide a reduction in the amplitude and the resulting increase in the frequency of oscillation near to the prescribed value. This should be evaluated as a way to improve the quality of automated control with the helps of human being. The paper presents some practical examples of the examined method. |
URL | https://ieeexplore.ieee.org/document/7998565 |
DOI | 10.1109/SIBCON.2017.7998565 |
Citation Key | zhmud_model_2017 |
- feedback
- Velocity control
- variable structure systems
- Uniform resource locators
- Switches
- sliding mode control
- Resiliency
- Regulators
- pubcrawl
- PI control
- Oscillators
- Numerical models
- hysteresis
- human reaction
- feedback signal
- artificial additional fluctuation
- fast switching
- Engines
- control systems
- control system synthesis
- control signal
- control loop
- composability
- closed loop systems
- automobiles
- automatic hysteretic object control
- Automatic control
- Automated Response Actions
- automated hysteretic object control