Control Engineering is an interdisciplinary field of engineering that deals with the analysis and design of control systems, which are used to regulate and manipulate the behavior of dynamic systems. With the increasing demand for professionals in this area, many online courses have emerged to provide individuals with the necessary skills and knowledge. In this article, we will review some of the best Control Engineering courses available online, highlighting their key features and benefits.
Here’s a look at the Best Control Engineering Courses and Certifications Online and what they have to offer for you!
10 Best Control Engineering Courses and Certifications Online
- 10 Best Control Engineering Courses and Certifications Online
- 1. Fundamental Question on Industrial Electronics by Harish Kumar Maheshwari (Udemy) (Our Best Pick)
- 2. Control Systems Engineering from Scratch by Sujithkumar MA (Udemy)
- 3. Electrical Control for real Industrial Automatic System by NewWay Academy (Udemy)
- 4. Introduction to Control Systems for Engineers by Michael Reynolds, PhD (Udemy)
- 5. Complete Instrumentation and Control Engineering Course by R.B. Singh (Udemy)
- 6. Getting started with Data Acquisition and LabJack by Dr. Peter Dalmaris (Udemy)
- 7. Your Guide in Modern Control Engineering with MATLab by Mo’ath Yousef AbuTo’amah (Udemy)
- 8. Process Control: Hands-On for Dynamic Mathematical Modelling by JMH Integrated Training (Udemy)
- 9. Control Valve Masterclass : Design and Maintenance by Md Dass (Udemy)
- 10. Bode Plots and Stability of Power Supplies (Buck Converters) by kayhan ince (Udemy)
1. Fundamental Question on Industrial Electronics by Harish Kumar Maheshwari (Udemy) (Our Best Pick)
The Fundamental Question on Industrial Electronics Course, taught by Harish Kumar Maheshwari, offers multiple choice questions on the principles and applications of Industrial Electronics. This course is designed to help students prepare for interviews in the field of Industrial Electronics. Through the Industrial Electronics Quiz, students will gain confidence by learning tips and tricks to solve Industrial Electronics based questions. The quiz includes a series of practice tests to test the student’s knowledge in the field of Industrial Electronics.
The Industrial Electronics MCQ Test provides students with sample questions likely to be asked in real exams and interviews. These MCQ questions are designed to assist with self-study and self-assessment, and help students check their knowledge. By taking the quiz, students can enhance their confidence during real exams and interviews.
The course aims to make it easy for students to cover a range of topics in Industrial Electronics. The course includes Industrial Electronics based questions from different topics, allowing students to increase their confidence by solving these questions. This type of Q&A is crucial for real exams. The course also offers a 30-day money-back guarantee.
The course content includes Practice Tests, which offer a range of Industrial Electronics based questions to help students prepare for exams and interviews. By participating in the Industrial Electronics Test, students can understand various questions and answers, helping them to improve their knowledge and confidence.
The course titled “Control Systems Engineering from Scratch” is offered by Sujithkumar MA. It is designed to provide a comprehensive understanding of the fundamentals and concepts of control systems. The course covers topics such as systems (including types, open loop, and closed loop), SISO/MISO systems, linear and non-linear systems, time-variant and time-invariant systems, causal and non-causal systems, transforms (including Laplace transforms and inverse Laplace transforms), transfer function, fundamentals of electrical circuits, block diagrams, time response analysis, poles and zeroes, steady state error, error constants, stability analysis, and relative stability plots.
Control Systems Engineering is a field of engineering that deals with designing, developing, and implementing solutions that control dynamic systems to produce the desired outcome. The course is particularly useful for those preparing for competitive exams such as GATE and ESE, where control systems are commonly tested. The course covers everything from scratch, making it accessible to learners with no prior knowledge of the subject.
The course is divided into several sections, including an introduction, classification of systems, standard test signals, Laplace transforms, transfer function of electrical systems, block diagrams, time response analysis of first-order systems, poles, zeroes, DC gain, type numbers, time response analysis of second-order systems, steady state error and error constants, methods to determine the stability of a system, tools to determine stability, and relative stability using plots.
Overall, the course aims to provide learners with a comprehensive understanding of control systems engineering, making it a valuable resource for students, professionals, and anyone interested in the field.
NewWay Academy is offering a course titled “Electrical Control for Real Industrial Automatic System” with the goal of taking participants to a higher level of understanding and capability in dealing with complex classic project and automation. This course is the first of its kind on Udemy and other educational platforms, providing practical knowledge that can help advance participants’ careers in industrial automation.
The course curriculum is designed to take participants step-by-step through the process of building a complete control system, including calculating each component and designing power and control circuits. The course instructor emphasizes their availability to offer help and support to participants who may have questions or get stuck during the learning process.
The course is appropriate for anyone interested in understanding control systems, electrical basics, and how sensors work, including electrical engineering students. It is also useful for those who want to be familiar with industrial automation and control or who understand control but cannot design a complete control system. Additionally, the course covers topics such as automatic transfer switch, voltage monitoring relay, overloading, and short-circuit protection.
The course content is divided into several sections, including an introduction, components of classic control, classic control components in practical life, starting for induction motor, EKTS, applications, automatic transfer switch, phase sequence, final project, and basics of electricity. The course instructor encourages participants to take advantage of this opportunity to begin on the right path and gain the knowledge and skills necessary to succeed in industrial automation.
The course titled “Introduction to Control Systems for Engineers” is led by Michael Reynolds, PhD. The course aims to provide an introduction to both classical and modern control systems, with a focus on utilizing MATLAB as a teaching tool.
The course covers a variety of topics, ranging from system response and root-locus, to bode plots, nyquist, state-space, digital control, and optimal control. The instructor provides clear explanations and takes students through the basics of control systems, up to current research in the field.
The course is divided into several sections, including an introduction and background information, basic concepts in control design, control design via root locus (which includes an exam and solution), using the frequency domain to understand response and design control systems, and modern control design with state-space and beyond.
Overall, the course provides a comprehensive overview of control systems, with an emphasis on practical applications and hands-on learning using MATLAB.
The Complete Instrumentation and Control Engineering Course is taught by R.B. Singh and covers the basics of instrumentation and control engineering, including the use of process control instruments and software tools such as temperature, pressure, flow, and level sensors, analyzers, and Piping and Instrumentation Diagram (P&ID) in industrial settings. The course also covers control systems derived from mathematical models of industrial processes and systems.
The purpose of this course is to provide students with an understanding of instrumentation engineering and why it is important. The role of an instrumentation engineer is to Conceptualize, Design, Detail, Maintain and Trouble shoot control system for its industry. The course covers the changed mindset and government compliance efforts to make safety the first priority against profits and production.
The course contains several sections focusing on flow instruments engineering, level instruments engineering, temperature instruments engineering, and pressure instruments engineering. These sections cover the selection, sizing, technical datasheets, specifications, technical bid tabulation, technical query, vendor offer, GAD, inspection, and documentation of various types of instruments used in industrial settings. For example, the flow instruments engineering section covers the selection, sizing, technical datasheets, specifications, technical bid tabulation, technical query, vendor offer, GAD, inspection, and documentation of orifice flow meters, magnetic flow meters, vortex flow meters, and other types of flow meters.
The level instruments engineering section covers the selection, sizing, technical datasheets, specifications, technical bid tabulation, technical query, vendor offer, GAD, inspection, and documentation of level gauges, DP level transmitters, radar level transmitters, ultrasonic level transmitters, and other types of level instruments.
The course, Getting started with Data Acquisition and LabJack, is designed to teach individuals how to utilize the LabJack device for data acquisition and control (DaQ) operations. It is particularly beneficial for those interested in recording and analyzing data from sensors, as well as controlling the environment based on that data.
LabJack is a tool for data acquisition and control that is robust, reliable, and designed to work autonomously in harsh environments for extended periods of time. It has numerous input/output ports that can connect to a wide range of sensors and actuators, and can be used via an intuitive graphical user interface or programmed using mainstream languages. This course teaches the basic concepts of data acquisition and control, how to use a LabJack device without any programming, and how to network and automate DaQ tasks using languages like Lua and Python.
Specifically, the course covers topics such as introduction to data acquisition and control, getting started with LabJack, analog inputs, flexible ports, digital to analog converter ports, DIO extended feature examples, on-board programming with Lua, and using the LabJack API with Python. The course content, required hardware, knowledge prerequisites, and free sample lectures can be found on the course website.
This course, titled “Your Guide in Modern Control Engineering with MATLab,” is led by instructor Mo’ath Yousef AbuTo’amah. It aims to enhance the academic and practical understanding of modern control systems, allowing students to design their controllers for different systems and study modern control theory.
The course content is diverse, providing a balance between scientific methods and practical techniques through exercises. The course is divided into several sections, including introduction, Laplace transformation, transfer function, obtaining block diagrams and state equations, modeling of dynamic systems, root locus plot, frequency-response analysis, stability analysis, Bode plot, lag, lead, and lag-lead compensation by root locus and Bode plot methods, PID controller, Ziegler-Nichols rules for tuning PID controller, and examples.
Students who complete this course will have a comprehensive understanding of modern control engineering with MATLab.
The course titled “Process Control: Hands-On for Dynamic Mathematical Modelling” is offered by JMH Integrated Training as a part of the Process Control Hands-On Series. The course primarily focuses on hands-on dynamic mathematical modelling of mass, component, and energy for chemical processes. The series comprises six parts, and this course is the first part of the series.
The course content includes general mathematical modelling principles and step-by-step procedures for developing total mass balance, total component balance, and total energy balance for chemical processes. It comprises 10 exercises for mass balance, 13 exercises for component balance, and 11 exercises for energy balance. The exercises are selected in increasing order of degree of difficulty.
The course is targeted towards chemical engineering undergraduate students who wish to extend their knowledge in process dynamics, process engineers who want to develop dynamic models for process plants, process control engineers who wish to design control strategies for new processes, and process engineers who want to optimize process operating conditions.
The teaching method of the course is hands-on, based on several exercises with incremental difficulty levels. The course includes assignments at the end of every sub-section to assess the participant’s capability in deriving mathematical models.
In summary, the Process Control: Hands-On for Dynamic Mathematical Modelling course offers comprehensive training on mathematical modelling principles and procedures for mass, component, and energy balance in chemical processes. It is suitable for a target audience with interest in process dynamics, control strategies, and optimization.
The Control Valve Masterclass: Design and Maintenance is a professional certificate course that aims to provide students with a complete understanding of the construction and functioning of control valves. The course is designed to be accessible for students working in various industries, such as Refinery, Petrochemical, Chemical, and Process.
The course begins with a discussion of fundamental laws of physics, such as Bernoulies Theorem, Equation of Continuity, and critical valve phenomena like Cavitation, Flashing, and Chocked Flow. The course also covers tips and tricks for avoiding Cavitation and Flashing.
The course covers control designs like the selection of material, noise calculation, leakage classification, and control valve characteristics. The differences between installed and inherent characteristics are discussed in detail, and control valve sizing is also explained in a simple yet detailed way. The curriculum is full of thumb rules and practical examples.
The course is divided into ten sections, including Introduction, Control Valve Selection and Sizing, Control Valve Material Selection, Different Types of Valve, Control Valve Fundamental, Control Valve Actuator, Control Valve Accessories, Control Valve Symbols, Control Valve Maintenance, and Interview Questions.
As an enrolled student, you will have unlimited access to the course materials and one-on-one instructor support. The course instructors are available to assist students in the Q&A section when needed. The course aims to help students gain practical knowledge and valuable information through years of experience.
Course Title: Bode Plots and Stability of Power Supplies (Buck Converters)
Course Instructors: Kayhan Ince
The course covers stability analysis and phase cross over frequency using Bode plots for power supplies in the frequency domain. The course explains various concepts, such as gain margin, phase margin, cross over frequency, and power supply stability criteria.
One of the main focuses of the course is on power supplies, which are frequently designed in the frequency domain to obtain more information about their relative stability. In comparison, in the time domain, stability criteria are not investigated properly by just examining the transient response of the power supply under a step load.
The course is divided into two sections, with the first section covering the Bode plot of a switching DC/DC converter. The second section provides an introduction to the stability analysis of power supplies using Bode plots.