When it comes to mastering the intricacies of Comsol Multiphysics software, online courses can be an effective way to gain knowledge and skills at your own pace. With a plethora of options available, it can be challenging to identify the best courses that offer in-depth knowledge and hands-on practice. In this article, we will explore some of the best Comsol Multiphysics courses available online, highlighting their key features and benefits to help you make an informed decision.
Here’s a look at the Best Comsol Multiphysics Courses and Certifications Online and what they have to offer for you!
10 Best Comsol Multiphysics Courses and Certifications Online
- 10 Best Comsol Multiphysics Courses and Certifications Online
- 1. COMSOL Multiphysics simulation 2022 : Basics to Advanced by Bibhatsu Kuiri (Udemy) (Our Best Pick)
- 2. CFD simulations in COMSOL Multiphysics by Bibhatsu Kuiri (Udemy)
- 3. COMSOL Multiphysics all features walk through by Bibhatsu Kuiri (Udemy)
- 4. COMSOL Multiphysics complete course 2022 by Laureano Boira Radiu (Udemy)
- 5. Corrosion Modeling & Protection with COMSOL Multiphysics by Mr.Amol Mali (Udemy)
- 6. 1D Lithium Air battery Simulation in COMSOL Multiphysics by Bibhatsu Kuiri (Udemy)
- 7. COMSOL Complete basic course on Electrical Circuit by Bibhatsu Kuiri (Udemy)
- 8. Magnetic FEM Simulation with verification in COMSOL by Bibhatsu Kuiri (Udemy)
- 9. Capacitor Modelling in COMSOL Multiphysics & FEMM by Bibhatsu Kuiri (Udemy)
- 10. Ferroelectric material hysteresis In COMSOL Multiphysics by Bibhatsu Kuiri (Udemy)
1. COMSOL Multiphysics simulation 2022 : Basics to Advanced by Bibhatsu Kuiri (Udemy) (Our Best Pick)
The COMSOL Multiphysics simulation 2022 course offers a comprehensive introduction to the industry-leading simulation platform. The course covers basic concepts on simulations, boundary conditions, meshing, and results. The instructor, Bibhatsu Kuiri, has published in top journals and has taught over 5000 students across 105 countries. The course supports multiple languages, including Arabic, French, Portuguese, and Spanish.
The course is designed for beginners and is continuously updated based on student feedback. In the course, students will learn how to create a 3D model for simulation, add physics and boundary conditions, add mesh in simulation, run simulations, and verify results. An assignment and interactive quizzes are included to test understanding. The course also covers thermal modeling and equation-based modeling.
The content is presented in a general manner, making it accessible to everyone, and 1v1 support is available if needed. The course includes tips and tricks useful for simulation. The instructor offers to answer any queries about the course, material, or pricing.
The course is divided into sections, including an introduction to COMSOL, software basics, meshing concepts, adding physics to models, solving simulation models, analysis and simulation verification, and advanced examples. The course also includes a bonus video on advanced examples and tips and tricks useful for simulation.
This course, titled “CFD Simulations in COMSOL Multiphysics,” offers instruction in basic CFD simulation techniques for fluid flow simulations using COMSOL Multiphysics software. The course is designed for students without prior knowledge of any CFD software, providing guidance from the ground up to develop a complete simulation workflow. The course instructor, Bibhatsu Kuiri, is highly qualified with experience instructing over 5000 students across 105 countries, as well as numerous publications in top journals and authorship of best-selling COMSOL courses on Udemy.
Students in the course will receive complete guidance on using CFD for their project, including creating geometry, adding boundary conditions, adding mesh, simulating, and post-processing results. Common mistakes made by beginners in COMSOL will be addressed, and instruction will be provided on comparing results with experimental data to assess accuracy and quality. Additionally, students will learn how to conclude results after post-processing for use in project reports, thesis reports, or research papers. New videos, examples, and notes will be updated regularly based on student feedback, and the instructor offers 24/7 support.
The course boasts over 200+ 5-star reviews and offers quick informative videos for easy and quick execution. Supplemental resources include books, input/output files, solution files, ppt slides, PDFs for all lectures, and software links and instructions for installation. Full lifetime access is provided, and the course can be accessed on mobile, TV, desktop, and laptop. The course is broken down into three sections, including a complete basic simulation on a CFD model, a second level section, and tips and tricks useful for simulation.
The COMSOL Multiphysics all features walk through course is designed for novice users of the software. The course instructor, Bibhatsu Kuiri, has extensive experience teaching and modeling devices in council multiphysics for top journals such as Nature Materials. The course provides a compact and comprehensive overview of the software’s capabilities, with video lectures covering all features and examples of manual mesh, geometry, and results. It is not intended for experienced COMSOL users.
The course covers the different options and menus in COMSOL Multiphysics, including file and preference settings, measure functions, physics settings, and results. It is designed to make students aware of the software’s functionality and capabilities. While no simulations are performed, each feature is explained in detail. The course is divided into sections on introduction, file, home tab, definitions, geometry, materials, physics, mesh, study, and results, with a bonus lecture on understanding meshing and an additional example of a 2D thermal simulation.
The 2022 COMSOL Multiphysics Complete Course is designed to provide a simple and practical way for students, engineers, and researchers to quickly learn to solve multiphysics simulations from scratch. This comprehensive course covers various physical simulations, including structural, frequency, and CFD problems. It is suitable for beginners with no prior experience in Finite Elements or COMSOL, and learners will finish the course with mastery of the subject.
The course instructor, Laureano Boira Radiu, emphasizes the importance of mastering Finite Elements to solve physical problems in engineering, as it provides many job opportunities and economic benefits. COMSOL Multiphysics offers a multitude of physical modules for simulation, making it one of the leaders in the sector and highly sought after by companies. However, learning the software can be complex and challenging, and this course aims to simplify the learning process by providing step-by-step instructions and detailed resolutions for complete on-demand problems.
The course covers five main sections, including Structural Problems, Flow Problems, and Frequency and Acoustics analysis. Learners will master the different physical applications of COMSOL Multiphysics, such as solid mechanics physics, CFD, and eigenfrequency study. The course also provides a hands-on learning experience, allowing learners to understand the physical sense and logic of the procedure.
The course instructor is available to answer any questions learners may have promptly. Overall, the COMSOL Multiphysics Complete Course is an excellent opportunity to learn the software and solve various types of problems quickly, making versatile and complete use of the software.
The Corrosion Modeling & Protection with COMSOL Multiphysics course focuses on the use of the Corrosion Module, an add-on package for COMSOL Multiphysics® software, for modeling and simulating corrosion and corrosion protection processes. The course includes various types of corrosion simulations such as galvanic corrosion, cathodic protection, crevice corrosion, and general electrochemistry.
The Corrosion Module features several physics interfaces that describe the transport and reaction of charged and neutral ions in aqueous electrolytes, surface reactions (electrochemical and chemical), and the formation of adsorbed species or coatings on metal surfaces. The module also covers the transport of current in electrolytes and metals, transport of current in thin metal structures (treated as shells), fluid flow, and heat transfer.
The course content is divided into four sections. The first section is an introduction to the Corrosion Module. The second section covers atmospheric corrosion of a busbar. The third section includes a case study on galvanic corrosion with electrode deformation. The fourth and final section explores stress corrosion cracking of steel buried pipelines in soil.
Overall, this course is designed to provide participants with a comprehensive understanding of corrosion modeling and protection using COMSOL Multiphysics software. By the end of the course, participants will be equipped with the skills and knowledge necessary to simulate and analyze a variety of corrosion scenarios.
The 1D Lithium Air battery Simulation in COMSOL Multiphysics Course is designed to teach advanced Lithium Battery Simulations using multiple Physics interfaces. The course is intended for those who have some knowledge of COMSOL Multiphysics and are interested in energy storage and next-generation energy demand. Participants who are new to COMSOL Multiphysics are recommended to complete the “Learn COMSOL Multiphysics simulation: Basics to Advanced” course before taking this course.
The course instructor, Bibhatsu Kuiri, has instructed over 5000 students across 105 countries and has published 17 international publications involving modelling and simulation using finite element simulation, DFT simulation, or analysis using Matlab Python or Simulink. He is also the author of the best-selling COMSOL courses on Udemy.
The course covers the 1D simulation of a complex Lithium-ion battery and provides files and parameter values for participants to watch and prepare their own model. It also provides a basic understanding of how to do simulations and offers high-quality lectures.
The course focuses on the simulation of a rechargeable Lithium-air battery that attracts great interest due to its high energy density. The course uses the Lithium-Ion Battery interface to simulate the discharge of a Lithium-air battery and models the transport of oxygen (from external air) in the porous carbon electrode using the Transport of Diluted Species in Porous Media interface. The electrochemical reaction of oxygen reduction in the carbon electrode leads to changes in the concentration of the reaction product and electrode porosity. Participants can analyze the model for a range of discharge current densities and compare the oxygen concentration, porosity, and film thickness in the positive electrode to understand their effect on the cell voltage profiles.
The course is a starting point in the simulation of batteries and participants can implement the same idea in 2D and 3D after trying out the 1D simulation.
This course is titled “COMSOL Complete basic course on Electrical Circuit” and is instructed by Bibhatsu Kuiri. The course is designed to teach the basics of electrical circuit simulation in COMSOL Multiphysics using the AC DC module (cir). Students will learn to add voltage source, resistor, capacitor, inductor, AC input, study settings, concepts, error calculation, comparison with analysis value, and more.
The instructor, Bibhatsu Kuiri, has instructed over 5000 students across 105 countries and has publications in top journals such as Nature Materials. Additionally, he has authored the best-selling COMSOL courses on Udemy.
To enroll in this course, students must have access to COMSOL Multiphysics software with AC/DC module (cir) license, basic school-level knowledge on capacitor, inductor, potential drop, and an interest to learn.
During the course, students will learn how to simulate electrical circuits involving R, L, C components, add DC/AC voltage sources, evaluate results, compare results from analytic values, perform error calculations of simulation results, convert AC input to DC, and learn tips for COMSOL simulations. The course is suitable for both slow and fast learners, and is distraction-free, to-the-point learning experience.
The course is updated regularly with new lectures and is not suitable for students who already know how to use the electric circuit (CIR) module in COMSOL Multiphysics. The course consists of five sections: Introduction & RC circuit simulation, Complete LC Circuit Simulation in COMSOL Multiphysics, AC Analysis of Circuit, Full Wave Rectifier in COMSOL, and Advanced Multiphysics. Students will have access to 24/7 support from the instructor if they encounter any difficulties while taking the course.
The course “Magnetic FEM Simulation with verification in COMSOL” focuses on utilizing the Finite Element Method (FEM) for numerical solutions of differential equations in engineering and mathematics. The course primarily deals with analyzing structural systems, heat transfer, fluid flow, mass transport, and electromagnetic potential. The FEM technique involves dividing larger systems into smaller, simpler sections known as finite elements. The numerical domain for the solution is created through space discretization, which involves the development of an object mesh.
The instructor for this course, Bibhatsu Kuiri, has instructed over 5000 students from more than 105 countries worldwide. Kuiri has published 17 international publications related to modeling and simulation using finite element simulation, DFT simulation, or analysis with Matlab Python or Simulink. Kuiri is the author of the best-selling COMSOL courses on Udemy.
The course utilizes COMSOL Multiphysics software as a tool to solve a real problem using FEM. It is a self-contained course, with high-quality lectures, step-by-step processes, quizzes, PDF notes, and simulation comparisons with real experiments. The course is designed to provide students with a good idea of how to solve real problems using FEM.
The course content and sections revolve around the concept of a magnet falling through a pipe. Students will learn how to run advanced simulations, use COMSOL Multiphysics, make 2D geometry, mesh the model, add physics, equations, integrals, run simulations, and analyze results. The instructor is a best-selling simulation course author with 3000+ students globally and 300+ 5-star ratings. The course’s design is intended to be quick and easy to follow, and students will gain valuable insights into FEM simulations.
The Capacitor Modelling in COMSOL Multiphysics & FEMM Course is a comprehensive course designed for individuals interested in 3D capacitor modelling. The course will cover capacitor modelling in both COMSOL Multiphysics and FEMM, with a focus on solving and modelling realistic capacitors. Capacitors, being passive electronic components with two terminals used for energy storage, are integral parts of electronic devices. Capacitance calculation is crucial, especially when designing device contacts and calculating impedances in frequency-dependent studies.
The course instructor, Bibhatsu Kuiri, is a seasoned instructor with extensive experience in instructing over 5000 students across 105 countries. Kuiri has published in prestigious journals, including Nature Materials, and authored best-selling COMSOL courses on Udemy. This course will provide learners with high-quality lectures, assignments, and notes for additional learning, as well as support in case of any doubts or questions.
The course covers various sections, including Dielectric Variation of a Capacitor, FEMM Simulation, and Capacitor Modelling in COMSOL Multiphysics. Learners will also gain knowledge on 3D Capacitor Modelling in DC and AC current in COMSOL Multiphysics and Capacitor Modelling using FEMM (free software). The course is quick, avoiding unnecessary discussions with a runtime of approximately 50 minutes. Additionally, the course is updated regularly based on student suggestions.
The COMSOL Multiphysics course on Ferroelectric material simulation covers the modelling and simulation of ferroelectric materials, including hysteresis curve simulation using the Jiles-Atherton model. The course is designed to be concise and to-the-point, with lectures that cover the essential concepts. The instructor, Bibhatsu Kuiri, has extensive experience in modelling and simulation, with over 17 international publications and more than 5000 students instructed across 105 countries. Kuiri is also the author of the best-selling COMSOL courses on Udemy and updates the course content constantly based on student feedback.
The course covers the basics of ferroelectric material simulation, including creating a Ferroelectric model, simulating the hysteresis curve, and using interdomain coupling and pinning loss. Ferroelectricity is a property of certain nonconducting crystals that exhibit spontaneous electric polarization, which can be reversed in direction by the application of an appropriate electric field. The course is designed to provide a comprehensive overview of the topic and its practical applications.
The course is divided into several sections, including an introduction to the model, adding parameters in the model, creating geometry, adding physics materials and mesh, study and results, and voltage variation consistency check. The course is intended for anyone interested in ferroelectric material simulation, including students, researchers, and professionals in related fields. By the end of the course, participants will have gained a solid understanding of ferroelectric material simulation and the practical applications of the Jiles-Atherton model.