Control and Identification Toolbox (CIT): An Android application for teaching automatic control and system identification

Concha, Antonio; David, Luviano-Cruz; Calderón, G.; Gadi, Suresh Kumar

doi:10.1002/cae.22145

Cited by 7 publications

(7 citation statements)

References 18 publications

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“…The main characteristics of the mCIT app are similar to those of the CIT app reported by Concha et al [9]. For example, the mCIT app includes the class files utilized in the CIT app.…”

Section: Features Of the Mcit Appmentioning

confidence: 58%

“…rev, respectively. For this experiment, the motor velocity v was estimated from the position measurement q by means of the high-pass filter represented in (9), which has a cut-off frequency of α = 20 1 rad/s. This filter was selected as the velocity estimation method in the simulation settings, whereas its parameter α 1 is set in the mCIT app as shown at the bottom of Figure 5.…”

Section: Frequency Responsementioning

confidence: 99%

“…The mCIT app executes the identification and control algorithms on the mobile device and allows users to interact with the experimental platform. Its GUI is based on the Control and Identification Toolbox (CIT) application described in Concha et al [9]. The main motivation behind the mCIT app design is to take advantage of the fact that most university students have mobile devices, and they have a positive attitude toward mobile learning [8,12].…”

Section: Introductionmentioning

confidence: 99%

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mCIT app for teaching and learning the estimation and automatic control of DC motors

Sánchez,

Thenozhi,

Lara

et al. 2023

Comp Applic In Engineering

Self Cite

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Topics of automatic control, parameter identification, and state estimation of a direct current (DC) motor are widely included in undergraduate and graduate engineering programs. Traditionally, theoretical classes are accompanied by simulation or experimental laboratory sessions. The simulation techniques usually do not consider essential dynamic behaviors exhibited by physical systems, such as friction and saturation. Meanwhile, the DC servomechanism, computing device, and associated software used for the experiments are usually expensive. These situations may be avoided through mobile learning by using a low‐cost and portable platform controlled by a mobile device. This article proposes a free Android application called Control and Identification Toolbox for motors (mCIT) and a low‐cost portable platform designed to perform real‐time experiments on DC servomechanisms. The portable platform comprises a mobile device with the mCIT app, a DC servomechanism, and an Arduino‐based data acquisition system. The mobile device, which can be a smartphone, performs the computational and user interface tasks. The effectiveness of the mCIT app and platform are evaluated in online, hybrid, and face‐to‐face courses. The results indicate that the proposed mobile technique improves the teaching and learning experience of automatic control and system estimation topics.

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“…The main characteristics of the mCIT app are similar to those of the CIT app reported by Concha et al [9]. For example, the mCIT app includes the class files utilized in the CIT app.…”

Section: Features Of the Mcit Appmentioning

confidence: 58%

Section: Frequency Responsementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

mCIT app for teaching and learning the estimation and automatic control of DC motors

Sánchez,

Thenozhi,

Lara

et al. 2023

Comp Applic In Engineering

Self Cite

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show abstract

“…Python is even less used than MATLAB by scientists, but Python users are increasing every day; in Reference 15 it was shown how the use of open source tools like Jupiter notebook improves teachers and students productivity in engineering courses, providing flexibility and support for collaborative work and examples were presented for an Informatics Engineering courses; in Reference 16 it was shown that Jupyter/IPython notebooks is one of open source collaborative tools that provides an environment to develop and promote the access to remote and virtual labs and it was presented a IPython‐based approach to interact with a remote rain gauge to obtain data about the rainfall in a given location; in Reference 17 it was remarked that practical experiments are extremely important to engineering education and sciences and it was proposed a fully open source remote laboratory that can be used in all engineering education and applied sciences. That work was programmed in Python for a SCADA platform, Android app in Reference 18 it was presented a Control and Identification Toolbox (CTI) that performed in an Android platform with the purpose of teaching and learning the system response, automatic control and parameter identification of dynamic systems and Smartphone apps 19 …”

Section: Introductionmentioning

confidence: 99%

Python app for drawing Bode diagram asymptotes of transfer function for minimum and non‐minimal phase systems

Meza

2022

Engineering Reports

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The purpose of this article is to introduce an app to draw the asymptotes of Bode diagram module and phase from each constituent elementary factors of any transfer function for minimum and non-minimal phase systems without transport delay. The Bode diagram is the most used tool in the frequency response method. Python and several Python modules were used to program the app to perform the operations as well as the Qt5 design was used to create a simple graphical user interface for the app and all this in the Linux operating system and the app's source code can also be run in Windows operating system with no adjustments or modifications. The app purpose is to assist students in learning the frequency response concepts and drawing of Bode diagram using asymptotes of magnitude and phase. For students the non-minimum phase system Bode diagram is more difficult to draw than a minimum phase system due to the presence of zeros and/or poles on right half side of s-plane. This application should be used by students as a help and not simply to solve problems and for teachers the application can be used to improve their classes by showing the step by step of drawing the Bode diagram with the figures obtained by the application. The app's executable file is available on release link in https://github.com/Magno-Meza-UFABC/Magno-Meza-UFABC/releases/tag/v.1.0

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“…González‐Vargas et al proposed a low‐cost servomechanism control platform for educational purposes, based on a Real‐Time Application Interface for Linux (RTAI) [8]. Concha et al [4] presented an Android toolbox for teaching automatic control, including the calculation of system responses, and the parameter identification of dynamic systems. Although MATLAB/Simulink are used in many laboratories, field programmable gate arrays (FPGAs) are also used.…”

Section: Introductionmentioning

confidence: 99%

Universal fixed‐point digital controller for control theory studies

Sanchez

Castro

Benedicto

et al. 2021

Comp Applic In Engineering

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The laboratories of control theory are often limited to simulations and a few or none experimental tests. As in other technical subjects, practical experiments really help to understand the theory but need much time and the experimental platforms are usually expensive. This paper describes a platform that implements a universal third‐order discrete controller based on field programmable gate array (FPGA). The controller is implemented using fixed‐point arithmetic, with 17‐bit coefficients, but students can reduce the number of bits to find the resolution problems that may arise. This low‐cost platform, based on a Xilinx Spartan FPGA, allows students to try controllers just by configuring the coefficients of the controller through a computer application and a USB port. It drastically reduces the implementation time, allowing more time for design and testing. Therefore, students can try many controllers in the same laboratory session so that they can check experimentally their behavior in real prototypes and see the differences between simulations and physical systems. This platform has been applied in a real course over two academic years. The student opinion survey shows that the survey respondents consider the platform useful for more deeply understanding the subject, with an average score of 4.47/5.00 on a Likert scale (with a margin of error of 15.56% with a 95% confidence level). Besides this, the platform records the usage statistics showing that there is a relationship between the application usage and the marks in both the theory and laboratory parts.

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Control and Identification Toolbox (CIT): An Android application for teaching automatic control and system identification

Cited by 7 publications

References 18 publications

mCIT app for teaching and learning the estimation and automatic control of DC motors

mCIT app for teaching and learning the estimation and automatic control of DC motors

Python app for drawing Bode diagram asymptotes of transfer function for minimum and non‐minimal phase systems

Universal fixed‐point digital controller for control theory studies

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