Design and Comparison of Strategies for Level Control in a Nonlinear Tank

Design and Comparison of Strategies for Level Control in a Nonlinear Tank

In this work, a study of the water level control of an inverted conical tank system is presented. This type of tank has highly nonlinear mathematical and dynamic characteristics. Four control strategies are designed, applied, and compared, namely classical Proportional–Integral–Derivative (PID), Gai...

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Main Authors: Claudio Urrea, Felipe Páez
Format: Article
Language:English
Published: MDPI AG 2021-04-01
Series:Processes
Subjects:
conical tank
process control
closed-loop control
PID
gain scheduling
internal model control
Online Access:https://www.mdpi.com/2227-9717/9/5/735
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spelling doaj-7c98789d1ddc4f1c85d77f5a19495e692021-04-22T23:00:48ZengMDPI AGProcesses2227-97172021-04-01973573510.3390/pr9050735Design and Comparison of Strategies for Level Control in a Nonlinear TankClaudio Urrea0Felipe Páez1Electrical Engineering Department, Faculty of Engineering, University of Santiago of Chile (USACH), Av. Ecuador 3519, Estación Central, Santiago 9170124, ChileElectrical Engineering Department, Faculty of Engineering, University of Santiago of Chile (USACH), Av. Ecuador 3519, Estación Central, Santiago 9170124, ChileIn this work, a study of the water level control of an inverted conical tank system is presented. This type of tank has highly nonlinear mathematical and dynamic characteristics. Four control strategies are designed, applied, and compared, namely classical Proportional–Integral–Derivative (PID), Gain Scheduling (GS), Internal Model Control (IMC), and Fuzzy Logic (FL). To determine which of the designed control strategies are the most suitable for an inverted conical tank, a comparative study of the behavior of the system is carried out. With this purpose, and considering situations much closer to reality, a variety of scenarios, such as step responses, random input disturbances, and momentary load disturbances, are conducted. Additionally, performance indexes (error- and statistics-based) are calculated to assess the system’s response.https://www.mdpi.com/2227-9717/9/5/735conical tankprocess controlclosed-loop controlPIDgain schedulinginternal model control
collection DOAJ
language English
format Article
sources DOAJ
author Claudio Urrea
Felipe Páez
spellingShingle Claudio Urrea
Felipe Páez
Design and Comparison of Strategies for Level Control in a Nonlinear Tank
Processes
conical tank
process control
closed-loop control
PID
gain scheduling
internal model control
author_facet Claudio Urrea
Felipe Páez
author_sort Claudio Urrea
title Design and Comparison of Strategies for Level Control in a Nonlinear Tank
title_short Design and Comparison of Strategies for Level Control in a Nonlinear Tank
title_full Design and Comparison of Strategies for Level Control in a Nonlinear Tank
title_fullStr Design and Comparison of Strategies for Level Control in a Nonlinear Tank
title_full_unstemmed Design and Comparison of Strategies for Level Control in a Nonlinear Tank
title_sort design and comparison of strategies for level control in a nonlinear tank
publisher MDPI AG
series Processes
issn 2227-9717
publishDate 2021-04-01
description In this work, a study of the water level control of an inverted conical tank system is presented. This type of tank has highly nonlinear mathematical and dynamic characteristics. Four control strategies are designed, applied, and compared, namely classical Proportional–Integral–Derivative (PID), Gain Scheduling (GS), Internal Model Control (IMC), and Fuzzy Logic (FL). To determine which of the designed control strategies are the most suitable for an inverted conical tank, a comparative study of the behavior of the system is carried out. With this purpose, and considering situations much closer to reality, a variety of scenarios, such as step responses, random input disturbances, and momentary load disturbances, are conducted. Additionally, performance indexes (error- and statistics-based) are calculated to assess the system’s response.
topic conical tank
process control
closed-loop control
PID
gain scheduling
internal model control
url https://www.mdpi.com/2227-9717/9/5/735
work_keys_str_mv AT claudiourrea designandcomparisonofstrategiesforlevelcontrolinanonlineartank
AT felipepaez designandcomparisonofstrategiesforlevelcontrolinanonlineartank
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