Bond-Graph-Based Approach to Teach PID and Sliding Mode Control in Mechatronics

The main contribution of this article is creating synergy between subjects; this means that students use the same graphical tool in several subjects. So far, the bond graph has not been used in control theory, but it is the “native language” of mechatronics engineers, so we would like to introduce i...

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Bibliographic Details
Published in:Machines (Basel) 2023-10, Vol.11 (10), p.959
Main Authors: Guo, Zenan, Korondi, Péter, Szemes, Péter Tamás
Format: Article
Language:English
Subjects:
block diagram
bond graph
Bonds
College students
Control engineering
Control theory
Controllers
Differential equations
Education
Engineering
Engineers
Graphical representations
Interdisciplinary subjects
LabVIEW programming
Magnetic fields
Mathematical analysis
Mechatronics
Methods
modeling and simulation
Ordinary differential equations
PID
Power
Proportional integral derivative
Robust control
Simulation
Sliding mode control
SMC
Students
Teaching
Teaching methods
Undergraduate study
Citations: Items that this one cites
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Summary:The main contribution of this article is creating synergy between subjects; this means that students use the same graphical tool in several subjects. So far, the bond graph has not been used in control theory, but it is the “native language” of mechatronics engineers, so we would like to introduce it into the teaching of control theory. The bond graph method is proposed as a novel teaching method to teach mechatronics subjects in the paper. The bond graph is a graphical alternative to ordinary differential equations from a mathematical standpoint. Traditionally, control theory employs ordinary differential equations, as they are familiar to control theorists. However, mathematically, both approaches are equivalent but require a slightly different approach in their application. This article highlights the mathematical similarities between the two approaches while emphasizing the distinctions in graphical representation. Another contribution is that the PID and sliding mode controller are represented using the bond graph method. In the meantime, through the use of practical examples, we effectively illustrate how the same problem can be solved using either approach. In the training materials, the PID controller and an adaptive robust sliding mode controller (ARSMC) with the bond graph are utilized as examples to demonstrate synergy in mechatronics. Finally, we present proof that mechatronic engineers achieve superior outcomes when utilizing the bond graph approach, based on test results from undergraduate students.
ISSN:2075-1702
2075-1702
DOI:10.3390/machines11100959