FEM - Linear, Nonlinear Analysis & Post-Processing from Coursera

In this hands-on project, you will learn about the Finite Element Method (FEM) and perform a linear & nonlinear static analysis study using the cloud-based simulation tool SimScale. We will set up simulation cases with provided geometries to learn the fundamentals of the Finite Element Method and how a static linear and nonlinear analysis is approached in the first place. We will walk through the classical three step process of every simulation which includes the pre-processing, processing and post-processing step.

SimScale is an engineering simulation platform that is revolutionizing the way engineers, designers, scientists, and students design products. The SimScale platform is accessible completely via a standard web browser, with an easy-to-use interface which supports numerous simulation types including solid mechanics (FEM), fluid dynamics (CFD) & thermodynamics.

This course runs on Coursera's hands-on project platform called Rhyme. On Rhyme, you do projects in a hands-on manner in your browser. You will get instant access to pre-configured cloud desktops containing all of the software and data you need for the project, for this project you need no special setup or any data. Everything is already set up directly in your internet browser so you can just focus on learning!

Notes:

- This course works best for learners who are based in the North America region. We’re currently working on providing the same experience in other regions.

What's inside

Syllabus

Module 1

Good to know

Know what's good

, what to watch for

, and possible dealbreakers

Suitable for those new to the Finite Element Method (FEM) and simulation tools

Taught by an experienced instructor in the field

Introduces learners to cloud-based simulation tools, which are valuable in the industry

Provides hands-on experience through interactive materials and project-based learning

Requires no setup or special data, making it accessible to learners without prior technical expertise

Activities

Be better prepared before your course. Deepen your understanding during and after it. Supplement your coursework and achieve mastery of the topics covered in FEM - Linear, Nonlinear Analysis & Post-Processing with these activities:

Review Linear Algebra and Calculus Concepts

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Refresh your understanding of linear algebra and calculus to ensure you have a strong mathematical foundation for the Finite Element Method.

Browse courses on Linear Algebra

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Review lecture notes or textbooks on linear algebra and calculus.
Solve practice problems to test your understanding.

Review Engineering Mechanics

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Review the fundamentals of engineering mechanics to build a strong foundation for understanding the Finite Element Method.

View Engineering Mechanics on Amazon

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Read chapters 1-3 of the textbook.
Solve the practice problems at the end of each chapter.

Organize Course Resources

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Organize and review course materials, including lecture notes, assignments, and quizzes, to reinforce your understanding and enhance your recall.

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Create a digital or physical filing system for all course materials.
Periodically review and summarize key concepts from the materials.

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SimScale Tutorial Series

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Go through the official SimScale tutorials to familiarize yourself with the software platform and its capabilities.

Browse courses on Finite Element Method

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Complete the 'Getting Started with SimScale' tutorial.
Complete the 'Linear Static Analysis with Solid Mechanics' tutorial.

Participate in Course Discussion Forum

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Actively engage in the course discussion forum to clarify concepts, share knowledge, and assist fellow learners, deepening your own understanding in the process.

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Post questions and respond to queries from other participants.
Provide explanations and share insights based on your knowledge and experience.

Finite Element Analysis Practice Problems

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Solve a series of practice problems to reinforce your understanding of the Finite Element Method and its application to linear and nonlinear static analysis.

Browse courses on Finite Element Method

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Find practice problems in textbooks or online resources.
Solve the problems using the SimScale platform.

Identify a Simulation Expert for Guidance

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Seek guidance from an experienced simulation engineer to gain insights, troubleshoot challenges, and accelerate your learning in the field of Finite Element Analysis.

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Network with professionals in the industry or online communities.
Attend webinars or workshops to connect with potential mentors.

Design and Analyze a Cantilever Beam

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Apply the Finite Element Method to design and analyze a cantilever beam using the SimScale platform, providing you with practical experience in structural mechanics.

Browse courses on Finite Element Method

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Define the geometry and material properties of the cantilever beam.
Create a simulation setup in SimScale.
Run the simulation and analyze the results.

Career center

Learners who complete FEM - Linear, Nonlinear Analysis & Post-Processing will develop knowledge and skills that may be useful to these careers:

Simulation Engineer

A Simulation Engineer uses computer simulations to model and analyze physical systems. As part of this work, it is necessary to use the Finite Element Method to understand how different forces will impact a given structure. This course may be useful for someone working in this field because it can provide a solid foundation in the theory and practice of the Finite Element Method.

See salaries and explore the career path for Simulation Engineer

Naval Architect

A Naval Architect designs and builds ships, boats, and other floating structures. Because ships and boats are stress-concentrated structures, it is necessary for Naval Architects to understand how forces will impact them by using the Finite Element Method. This course may be useful for a Naval Architect because it introduces the Finite Element Method and provides a way to potentially prepare for downstream work on boat and ship structures.

See salaries and explore the career path for Naval Architect

Biomedical Engineer

A Biomedical Engineer designs and builds medical devices, and simulations are used to better understand how these devices will behave. Biomedical Engineers use the Finite Element Method to determine stress, strain, and deformation in the development of stents, implants, and other medical devices. This course may be useful for a Biomedical Engineer because it teaches the basics of the Finite Element Method.

See salaries and explore the career path for Biomedical Engineer

Aerospace Engineer

An Aerospace Engineer develops and builds aircraft and spacecraft, and various analyses, including those based on the Finite Element Method, are vital to these processes. Similar to the work of a Civil Engineer, an Aerospace Engineer uses the Finite Element Method to understand how forces impact the structures of aircraft and spacecraft. This course offers an introduction to the Finite Element Method, which may help someone working as an Aerospace Engineer to prepare for work on complex structures.

See salaries and explore the career path for Aerospace Engineer

Materials Engineer

A Materials Engineer develops and tests new materials, including metals, ceramics, and polymers. A Materials Engineer might use the Finite Element Method to understand how a material will behave under stress and how it will fail. This course may be useful for Materials Engineers who want to learn more about the Finite Element Method.

See salaries and explore the career path for Materials Engineer

Mechatronic Engineer

A Mechatronic Engineer works with a combination of mechanical, electrical, and computer engineering to design and build products. In this field, it can be necessary to use the Finite Element Method to analyze stress, strain, and deformation, especially of new products that are still in development. This course may be useful to a Mechatronic Engineer because of its focus on the Finite Element Method.

See salaries and explore the career path for Mechatronic Engineer

Nuclear Engineer

A Nuclear Engineer designs and builds nuclear power plants and reactors. Engineers in this field sometimes use the Finite Element Method to analyze stress, strain, and deformation in materials to make sure that reactors will be safe and functional. This course may be useful, as it teaches the basics of the Finite Element Method.

See salaries and explore the career path for Nuclear Engineer

Chemical Engineer

A Chemical Engineer can design and build facilities to turn raw materials into useful products. The Finite Element Method can be used to analyze everything from chemical reactions to pipe stress and flow. This course teaches the basics of the Finite Element Method and can be useful for a Chemical Engineer who wants to learn more about the subject, either for project work or research.

See salaries and explore the career path for Chemical Engineer

Industrial Engineer

An Industrial Engineer designs and builds processes. In this line of work, it can become necessary to use the Finite Element Method to determine the stress, strain, and deformation of a given structure. This course may be useful, as it teaches the basics of the Finite Element Method and can help an Industrial Engineer to develop expertise in the subject.

See salaries and explore the career path for Industrial Engineer

Civil Engineer

A Civil Engineer designs and builds infrastructure, and one common project in this field is the creation of bridges. Bridges are stress-concentrated structures, and engineers must use tools like the Finite Element Method to see how these structures will respond to different loads. This course may be useful, as it teaches the basics of the Finite Element Method. More specifically, it may help a Civil Engineer prepare for downstream work on bridges.

See salaries and explore the career path for Civil Engineer

Automotive Engineer

An Automotive Engineer designs and builds vehicles, and the Finite Element Method is essential for the development of cars, trucks, and other such vehicles. Using this method, engineers can understand the stress, strain, and deformation of various parts of a vehicle. This course may be useful because an Automotive Engineer needs a knowledge base encompassing the Finite Element Method. More specifically, an Automotive Engineer may find this course to be useful in understanding how forces impact vehicle structure.

See salaries and explore the career path for Automotive Engineer

Petroleum Engineer

A Petroleum Engineer designs and builds structures and equipment used in the oil and gas industry. Engineers in this line of work sometimes use the Finite Element Method to analyze the integrity of oil pipelines, which are stress-concentrated structures. This course may be useful to a Petroleum Engineer because it offers an introduction to the Finite Element Method.

See salaries and explore the career path for Petroleum Engineer

Electrical Engineer

An Electrical Engineer designs and builds electrical systems, including those that are in aircraft, vehicles, and consumer products. An Electrical Engineer can work on projects where the Finite Element Method is necessary for stress-strain analysis. This course may be useful to Electrical Engineers who are interested in expanding their knowledge of the Finite Element Method.

See salaries and explore the career path for Electrical Engineer

Mechanical Engineer

A Mechanical Engineer designs, builds, and tests mechanical systems. As part of this work, it may be necessary to use the Finite Element Method to determine the stress, strain, and deformation of a structure. An FEM-based analysis of a given structure can ensure the integrity of the structure. This course may be useful in this process, as it teaches the basics of the Finite Element Method.

See salaries and explore the career path for Mechanical Engineer

Mining Engineer

A Mining Engineer designs and builds mines. The Finite Element Method can be used to assess the stability of rock and soil as a way to ensure the safety of workers. This course can help Mining Engineers learn about the Finite Element Method, potentially enabling them to prepare for downstream work around the stability of soil and rock.

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FEM - Linear, Nonlinear Analysis & Post-Processing

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