Simulink is a popular simulation and modeling tool used in various industries such as aerospace, automotive, and control systems. With the increasing demand for skilled Simulink professionals, the availability of online courses has become essential. The internet offers a vast range of Simulink courses that cater to the needs of both beginners and advanced users. This article aims to provide information on the best Simulink courses available online.
Here’s a look at the Best Simulink Courses and Certifications Online and what they have to offer for you!
- 10 Best Simulink Courses and Certifications Online
- 1. MATLAB/SIMULINK Bible|Go From Zero to Hero! by Dr. Ryan Ahmed, Ph.D., MBA, Mitchell Bouchard, Stemplicity School Online (Udemy) (Our Best Pick)
- 2. Learn MATLAB and Simulink Programming by Jordan Christman (Udemy)
- 3. Model a Car and Design a PID Controller in MATLAB/SIMULINK by Eliott Wertheimer (Udemy)
- 4. MATLAB/SIMULINK Masterclass – From a Beginner to an Expert by Tod Vachev, Rezk A. (Udemy)
- 5. MATLAB/Simulink for Power Electronics Simulations by Ricardo Romero, PE (Udemy)
- 6. MATLAB/Simulink for Power System Simulations by Ricardo Romero, PE (Udemy)
- 7. FPGA Design with MATLAB & Simulink by Digitronix Nepal (Udemy)
- 8. Inverters Design (SVPWM) MATLAB/Simulink by Mo’ath Yousef AbuTo’amah (Udemy)
- 9. MATLAB/Simulink for Analog and Digital Electronics by Ricardo Romero, PE (Udemy)
- 10. SIMULINK : Beginner Course on MATLAB/SIMULINK by Ansar Mulla (Udemy)
1. MATLAB/SIMULINK Bible|Go From Zero to Hero! by Dr. Ryan Ahmed, Ph.D., MBA, Mitchell Bouchard, Stemplicity School Online (Udemy) (Our Best Pick)
The MATLAB/SIMULINK Bible|Go From Zero to Hero! course is instructed by Dr. Ryan Ahmed, Ph.D., MBA and Mitchell Bouchard of Stemplicity School Online. This project-based Simulink course aims to teach students the basics of Simulink, allowing them to create Simulink models and run simulations of physical systems. The course offers a unique approach to learning, where students will develop practical Simulink models from scratch.
The course provides a practical project-based learning experience, where students can build 10 Simulink projects together. Students will have complete access to all Simulink models and slides, and will receive a certificate of completion to showcase their skills in Simulink to employers. Additionally, students can take advantage of a risk-free trial with a 30-day money-back guarantee.
The course content is divided into 10 practical projects, covering topics such as generating, displaying, and exporting source generating sine waves, building mathematical equation systems, simulating mass spring damper systems in time and S-domain, building and simulating battery models, building proportional integral derivative controllers in Simulink, applying a PID controller to mass spring damper systems, tuning a proportional integral derivative controller, developing and simulating adaptive cruise control systems, and DC motor position control in Simulink.
Students can check out preview videos and the course outline to get a better understanding of the projects covered in this course. The course introduction and welcome message are included, and upon completion, students will receive a certificate of completion to showcase their skills on LinkedIn.
The Learn MATLAB and Simulink Programming course is designed to teach students about the various commands, functions, and features of MATLAB and Simulink. The emphasis is on the main topics to help students become comfortable creating their own scripts and Simulink models. The course is structured to include a combination of articles and videos, as well as quizzes to test understanding. The course covers several topics, including generating figures, plotting data, basic MATLAB commands, vectors, matrices and matrix commands, MATLAB scripts, programming loops and conditional statements, user-defined functions, Simulink, Simulink features, and example Simulink projects.
Each project in the course contains instructions, a demonstration, and a step-by-step solution to help students complete the project. There are multiple projects that require students to solve problems using MATLAB and Simulink. Appendices include instructions for downloading and installing MATLAB and Simulink, an overview of the MATLAB environment, and instructions for restoring the workspace. Overall, the course is designed to help students master MATLAB Programming fundamentals and Simulink to increase their number crunching abilities.
This course, titled “Model a Car and Design a PID Controller in MATLAB/SIMULINK”, is taught by Eliott Wertheimer. The course focuses on modelling and simulating an electric car, specifically a Tesla Model S, using MATLAB and SIMULINK, and designing a PID speed controller. It is an online course that covers the mathematical modelling of engineering systems, MATLAB/SIMULINK implementation, and PID control design.
The course provides a comprehensive overview of control systems and their applications in various industries, from cars to military aircrafts. It offers students the opportunity to learn and understand the physics behind an electric car, establish a mathematical model of an electric DC motor, derive the mathematical model behind the dynamics of a car, and implement an engineering model in SIMULINK using blocks, transfer functions, MATLAB functions, etc. Additionally, students will learn how to test and fit their model to relevant real-life performance and design, test and tune a PID speed controller for the Model S’ cruise control.
The course instructor, Eliott Wertheimer, will guide students through the course content in detail and explain any subject-specific vocabulary. This course is suitable for beginners, intermediate and advanced learners interested in engineering systems’ mathematics, the use of MATLAB and SIMULINK in engineering design and PID control. It is designed to cater to a diverse audience that may include students, engineers, sci-fi enthusiasts, amateur roboticists, drone builders, computer scientists, and business or sports persons.
Additionally, if students have questions during the course, the instructor is available to answer within 24 hours. The course is highly recommended for personal growth, career, or academic endeavors.
The course content is divided into two main sections: the mathematical model and SIMULINK model implementation. The mathematical model section covers understanding and harnessing the physics behind an electric car, establishing the mathematical model of an electric DC motor, and deriving the mathematical model behind the dynamics of a car.
The MATLAB/SIMULINK Masterclass course provides a comprehensive learning opportunity for beginners and experts alike. The course instructors, Tod Vachev and Rezk A., offer step-by-step exercises with real-life applications to provide hands-on experience in modeling and simulation using MATLAB/SIMULINK.
Course participants can expect to master the basics and move on to an advanced level of modeling and simulation. By taking the course, participants can learn various modeling and simulation techniques using MATLAB/SIMULINK, advance their careers as model-based design engineers, enhance their problem-solving skills in modeling and simulation, and learn how to build control systems and design PID controllers.
The course covers different topics related to modeling and simulation using MATLAB/SIMULINK. Participants will learn various types of modeling and simulation, mathematical modeling of systems such as Mechanical, Hydraulic & Electrical, drawing block diagrams for systems, and using MATLAB/SIMULINK from beginning to mastery point.
Additionally, the course covers advanced techniques in modeling and simulation, including modeling and simulation of vehicle suspension systems, DC servo motors, and tank level control. Participants will also understand the difference between continuous and discreet systems and learn to design and simulate finite state machines using stateflow, which is useful for building systems such as traffic light systems, car lane change signals, and MP3 player software.
Overall, the MATLAB/SIMULINK Masterclass provides participants with a comprehensive learning experience using real-life examples and applications. By completing the course, participants can distinguish themselves as model-based design engineers.
The MATLAB/Simulink for Power Electronics Simulations course is designed to teach students how to simulate power electronics devices using MATLAB/Simulink. The course covers the theory and simulation of rectifiers, dc-to-dc converters, and inverters. Each section includes several models which are available for download so that students can follow along and modify them to create their own designs. The course also offers a 30-day money-back guarantee and the instructor is available for questions throughout the course.
The first section of the course is an introduction to MATLAB/Simulink for Power Electronics. Students will review the theory behind semiconductor devices used in power electronics, voltage sources, current sources, and passive components (resistors, capacitors, and inductors). They will also learn how to put these components together in a model using Simulink and how to take measurements to ensure proper simulation.
The second section of the course covers Rectifier Simulations in MATLAB/Simulink. Students will review the theory behind the operation and topologies of power electronics rectifiers and learn how to simulate both single-phase and three-phase rectifiers using Simulink.
The third section of the course covers DC-to-DC Converter Simulations in MATLAB/Simulink. Students will review the theory behind the operation and topologies of power electronics DC-to-DC converters and learn how to simulate buck, boost, and buck/boost converters.
The fourth section of the course covers Inverter Simulations in MATLAB/Simulink. Students will review the theory behind the operation and topologies of inverters and learn how to simulate single-phase and three-phase inverters.
In each section, students will have access to several models which illustrate how to design and simulate power electronics devices in MATLAB/Simulink. By learning how to simulate power electronics devices in MATLAB/Simulink, students will be able to further their careers in electrical engineering and power electronics.
The course titled “MATLAB/Simulink for Power System Simulations” is instructed by Ricardo Romero, PE. The course provides an in-depth knowledge of how to simulate power systems in MATLAB/Simulink. The course aims to review the theory of power systems and provide various examples of running different power system studies using MATLAB/Simulink. The course is divided into four different sections.
The first section of the course is “Introduction to MATLAB/Simulink for Power Systems,” where the available libraries in Simulink are reviewed to represent generators, transformers, transmission lines, and loads. The section teaches how to model these components in Simulink and how to put them together in a model. It also provides knowledge on how to take measurements in the model to ensure proper simulation.
The second section of the course is “Power System Studies in MATLAB/Simulink,” where a large power system model is built that includes generators, transformers, transmission lines, loads, and capacitor banks. The section also covers modeling the turbine control systems and excitation control systems for all generators to simulate the realistic dynamic behavior of power systems in real life. The section concludes by running several types of studies, including load flow, short circuit, and stability studies, to simulate the behavior of the system under several conditions.
The course also provides several models that illustrate how to design and simulate power systems in MATLAB/Simulink. The models are available for download, which helps the candidates to follow along with the course and use these models to create their own power system models. By completing the course, candidates can further their career in electrical engineering and power engineering.
The course is covered in four sections, with a bonus section added at the end. The course includes a course introduction, a section on “Introduction to MATLAB/Simulink for Power Systems,” a section on “Power System Studies in MATLAB/Simulink,” and a course exam. The bonus section provides additional knowledge to candidates.
The “FPGA Design with MATLAB & Simulink” course offered by Digitronix Nepal focuses on designing FPGA based signal processing projects with the help of MATLAB/Simulink and FPGA design tool such as Xilinx VIVADO/ISE, using Xilinx System Generator and HDL Coder. The course aims to provide a complete design flow to the participants. The course covers topics such as FIR, IIR, LMS Filter Design, and OFDM Modulation Algorithm implementation on FPGA.
The course is divided into six sections, starting with the installation of MATLAB/Simulink and VIVADO/ISE. The second section introduces the participants to HDL Coder and System Generator, followed by a project with System Generator in section three. Advanced design with HDL Coder is covered in section four, while section five deals with advanced design using System Generator. The sixth section focuses on Zynq Development with System Generator and VIVADO. A bonus lecture is also included in the course.
MATLAB and Simulink are considered as the best tools for signal processing projects, while FPGA is the ideal hardware platform for such projects due to its flexibility and processing capabilities. The course enables participants to design FPGA based signal processing projects efficiently, using MATLAB/Simulink and FPGA design tool. The course is recommended for individuals who want to learn how to design FPGA based signal processing projects on MATLAB/Simulink.
This course, titled “Inverters Design (SVPWM) MATLAB/Simulink,” is aimed at teaching participants how to design a Voltage Source Inverter with Space Vector Pulse Width Modulation (SVPWM) using a step-by-step approach. The course is instructed by Mo’ath Yousef AbuTo’amah and covers topics such as abc to Alpha-Beta-Zero, sectors, switching time during sectors, and inverter circuit and filters.
The course is designed to provide participants with a comprehensive understanding of how to design an inverter and build droop control effectively. Therefore, students are required to study the levels step by step to gain the knowledge necessary to design the inverter and use droop control.
The course is divided into four sections, namely abc to Alpha-Beta-Zero, sectors, switching time during sectors, and inverter circuit and filters. Each section is structured to provide students with a deep understanding of the underlying concepts and principles.
Overall, this course offers a detailed and structured approach to designing an inverter with SVPWM. It provides students with a comprehensive understanding of the critical concepts and principles, enabling them to build droop control effectively.
This course, titled “MATLAB/Simulink for Analog and Digital Electronics,” is led by Ricardo Romero, PE, and allows individuals to simulate both analog and digital electronics circuits using MATLAB/Simulink. The course covers a wide range of topics, including active low-pass and high-pass filters, audio equalizers, inverting amplifiers, non-inverting amplifiers, analog-to-digital converters (ADCs), and digital-to-analog converters (DACs).
The course is divided into four sections. In Section 2, individuals will be introduced to MATLAB/Simulink for Analog and Digital Electronics and learn how to locate components in the library browser, add them to models, and run simulations. Section 3 focuses on the simulation of analog electronics, with topics including inverting/non-inverting amplifiers and low-pass/high-pass filters. Two projects will be included at the end of this section, where individuals will design an audio equalizer and a full-wave power electronics rectifier circuit.
Section 4 covers digital electronics simulation, with topics such as ADCs, DACs, and building combinational and sequential digital circuits. Two projects will be included in this section as well, where individuals will design a circuit that detects a combination of three consecutive logic 1s in a string of eight bits and a garage door opener.
Throughout the course, individuals will have access to MATLAB/Simulink models of the electronics devices discussed during the lectures. These models are available for download, allowing individuals to follow along, modify them, and create their own designs. By completing this course, individuals will be able to further their careers in electrical engineering and electronics design.
Udemy offers a 30-day money-back guarantee, and the instructor is always available to answer any questions during the course.
The SIMULINK: Beginner Course on MATLAB/SIMULINK is designed to provide an introduction to the MATLAB software with coding interface and a broad beginning for the SIMULINK interface of MATLAB software. The course is presented in three parts, including a MATLAB software interface and coding introduction, an introduction to the SIMULINK interface, and designing, developing, and simulating a few applications in SIMULINK. The curriculum consists of theory, actual MATLAB hands-on, exercises based on the learning from the respective section with its solution, and multiple-choice questions to give confidence about the learning.
The course is divided into 11 sections. Section 1 provides a welcome to the course, while Section 2 provides an introduction to the MATLAB software. Section 3 covers basic coding in the Command Window and coding in MATLAB coding file .m files. Section 4 covers starting with the SIMULINK interface, while Section 5 talks about commonly used blocks in SIMULINK. Section 6 covers blocks related to sources and sinks, and Section 7 covers math operations.
Section 8 covers the mechanical vibration model, while Section 9 is about the electric motor. Section 10 covers PID control, and Section 11 covers fuzzy logic control. At the end of the course, learners will be completely familiarized with the MATLAB SIMULINK interface, skill developed to use the SIMULINK interface, can design, develop their own simulation models and simulate it effectively.
Overall, the SIMULINK: Beginner Course on MATLAB/SIMULINK offers a comprehensive introduction to the software and its interface. The course’s structure is well-organized and offers both theory and practical exercises for learners. By the end of the course, learners will have gained proficiency in designing, developing, and simulating applications in SIMULINK, as well as using PID control and fuzzy logic control.