Abstract
With the rapid growth of sensor networks and the enormous, fast-growing volumes of data collected from these sensors, there is a question relating to the way it will be used, and not only collected and analyzed. The data from these sensors are traditionally used for controlling and influencing the states and processes. Standard controllers are available and successfully implemented. However, with the data-driven era we are facing nowadays, there is an opportunity to use controllers, which can include much information, elusive for common controllers. Our goal is to propose a design of an intelligent controller–a conventional controller, but with a non-conventional method of designing its parameters using approaches of artificial intelligence combining fuzzy and genetics methods. Intelligent adaptation of parameters of the control system is performed using data from the sensors measured in the controlled process. All parts designed are based on non-conventional methods and are verified by simulations. The identification of the system’s parameters is based on parameter optimization by means of its difference equation using genetic algorithms. The continuous monitoring of the quality control process and the design of the controller parameters are conducted using a fuzzy expert system of the Mamdani type, or the Takagi–Sugeno type. The concept of the intelligent control system is open and easily expandable.
Highlights
Sensor-based measuring systems are used in the information systems and in the control ones
The schema was built on the primary negative feedback loop controlling with two sensors placed for measuring the input u(t) and output y(t) of the controlled system
The effectiveness of the identification procedure for the system of the third order is going to be described in Section 3, but we suggest that the second order is sufficient because ES2 is designed for the system of the second order
Summary
Sensor-based measuring systems are used in the information systems and in the control ones. Quality control of real complex processes requires continuous monitoring of the changing internal and external conditions, followed by continuous adaptation of the controller parameters. We are facing a situation that the sensors provide us with even more information that we are able to use. We can work with a really massive amount of data–big data is trying to find hidden context in data, and the step is to use the information contained in the data. The world of processes controlling should change. It must reflect the situation of the enormous amount of data obtained from the processes as well as being able to work with it. The main idea of the work is to present a non-conventional method of solving classic control problems–how to set the controller parameters and when and how to reset them
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