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Yang-Hann Kim

Introduction to Advanced Vibrations starts with a review of single and double degree of freedom systems. After that, multiple degrees of freedom systems are introduced to explain the vibrations of string and beam. These vibration systems provide to apply or use them into practical problems

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What's inside

Syllabus

Introduction
Vibrations of Linear Multiple-degree-of-freedom System 1: Equations of motion, the stiffness and flexibility methods
You will going to learn basic concepts of vibration of string.
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Vibrations of Linear Multiple-degree-of-freedom Systems 2: Modal analysis
Vibrations of Continuous Systems 1: The vibration of string
Vibrations of Continuous Systems 2: The vibration of beam
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Good to know

Know what's good
, what to watch for
, and possible dealbreakers
Provides a strong foundation for understanding advanced vibrations
Useful for students in engineering and physics
Covers fundamental concepts and applications of vibrations

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Reviews summary

Well-received vibrations course

According to students, the course titled Introduction to Advanced Vibrations is a well-received course with learners saying it has excellent content and a knowledgeable instructor. The course's assignments are also said to be helpful in enriching knowledge on the topics.

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 Introduction to Advanced Vibrations with these activities:
Review basic calculus and linear algebra
Revisiting calculus and linear algebra will strengthen your foundation for the more advanced concepts in this course.
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  • Review your notes from previous calculus and linear algebra courses.
  • Take practice problems on calculus and linear algebra.
  • Watch video tutorials on calculus and linear algebra.
Review basic physics
Reviewing basic physics principles will help you better understand the physical phenomena behind vibrations.
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  • Review your notes from previous physics courses.
  • Take practice problems on basic physics.
  • Watch video tutorials on basic physics.
Watch video tutorials on vibrations
Watching video tutorials is a relatively passive way to approach learning that still provides value.
Browse courses on Vibrations
Show steps
  • Search for video tutorials on vibrations on YouTube or other video sharing platforms.
  • Watch the tutorials and take notes on the key concepts.
  • Review the tutorials later to reinforce your understanding.
Six other activities
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Preview the course textbook
Reading the textbook early can help you become familiar with the concepts covered in the course.
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  • Read the first chapter of the textbook.
  • Make a list of any concepts that you don't understand.
  • Highlight any sections that you find particularly helpful or interesting.
  • Take notes on the main points of the chapter.
Solve vibration problems
Practice is crucial for mastery. Solving problems regularly will help you retain information.
Browse courses on Vibrations
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  • Find a set of practice problems online or in a textbook.
  • Solve the problems on your own.
  • Check your answers against the provided solutions.
  • Review the problems you got wrong and try to understand why you made mistakes.
Join a study group
Study groups provide a collaborative environment where learning is facilitated through discourse.
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  • Find other students in your class who are interested in forming a study group.
  • Decide on a meeting time and place.
  • Meet regularly to discuss the course material.
Create a vibration resource library
By organizing resources that you find helpful, you make future learning and review easier and more efficient.
Browse courses on Vibrations
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  • Collect resources on vibrations from various sources, such as books, journal articles, and websites.
  • Organize the resources into a library, using a system that makes sense to you.
  • Share your library with other students.
Design a vibration isolation system
Applying the concepts of vibrations to a real-world problem helps deepen your understanding and abilities.
Browse courses on Vibrations
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  • Identify a system that experiences unwanted vibrations.
  • Research different types of vibration isolation systems.
  • Design a vibration isolation system for the identified system.
  • Write a report on your design.
Participate in a vibration design competition
Competitions simulate real-world engineering challenges and provide a motivating context for applying knowledge.
Browse courses on Vibrations
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  • Find a vibration design competition that is open to students.
  • Form a team and develop a design for the competition.
  • Submit your design to the competition.

Career center

Learners who complete Introduction to Advanced Vibrations will develop knowledge and skills that may be useful to these careers:
Mechanical Engineer
A Mechanical Engineer designs and builds machines, such as engines, turbines, and robots. Mechanical Engineers typically hold a Bachelor’s degree in Mechanical Engineering. In this Introduction to Advanced Vibrations course, you will learn about linear multiple-degree-of-freedom systems, which is a valuable concept in Mechanical Engineering. By understanding these concepts, you will be better prepared to design machines that can withstand these vibrations.
Biomedical Engineer
A Biomedical Engineer designs and creates equipment, devices, computer systems, and software used in healthcare. This can include things like medical imaging systems, prosthetics, and pacemakers. Biomedical Engineers typically hold a Bachelor’s degree in Biomedical Engineering, though sometimes a Bachelor’s degree in a related field is sufficient. In this Introduction to Advanced Vibrations course, you will learn about the vibrations of continuous systems, which is a valuable concept in Biomedical Engineering. By understanding these concepts, you will be better prepared to design medical devices that can withstand these vibrations.
Structural Engineer
A Structural Engineer designs and analyzes the structural integrity of buildings and other structures. Structural Engineers typically hold a Bachelor’s degree in Structural Engineering or a related field. In this Introduction to Advanced Vibrations course, you will learn about structural vibrations, which can inform your work as a Structural Engineer. By understanding these concepts, you will be better prepared to design structures that can withstand these vibrations.
Civil Engineer
A Civil Engineer designs and constructs infrastructure projects, such as roads, bridges, and dams. Civil Engineers typically hold a Bachelor’s degree in Civil Engineering. However, those with a Bachelor’s degree in a related field, such as Construction Management, may also qualify for some positions. In this Introduction to Advanced Vibrations course, you will discuss linear multiple-degree-of-freedom systems and vibrations of continuous systems. This knowledge can help you better understand the design and construction of structures.
Electrical Engineer
An Electrical Engineer designs, develops, and tests electrical equipment, such as power systems, motors, and generators. Electrical Engineers typically hold a Bachelor’s degree in Electrical Engineering. However, those with a Bachelor’s degree in a related field, such as Computer Engineering, might also qualify. In this Introduction to Advanced Vibrations course, you will study linear multiple-degree-of-freedom systems, which is a valuable concept in Electrical Engineering. By understanding these concepts, you will be better prepared to design electrical equipment that can withstand these vibrations.
Computer Engineer
A Computer Engineer designs, develops, and tests computer systems and applications. Computer Engineers typically hold a Bachelor’s degree in Computer Engineering, though sometimes a degree in a related field is sufficient. In this Introduction to Advanced Vibrations course, you will learn about linear multiple-degree-of-freedom systems, which is a valuable concept in Computer Engineering. By understanding these concepts, you will be better prepared to design computer systems that can withstand these vibrations.
Aerospace Engineer
An Aerospace Engineer designs primarily aircraft, spacecraft, satellites, and missiles. While most Aerospace Engineers will work on civilian projects, a small number work on the military side. Aerospace Engineers must possess strong analytical skills as they apply theories of aerodynamics, thermodynamics, and propulsion to the design of aerospace systems. Aerospace Engineers typically hold a Bachelor's degree in Aerospace Engineering. However, those with a Master's degree in a related field may also qualify. In this Introduction to Advanced Vibrations course, you will study the vibrations of string and beam, as well as linear multiple-degree-of-freedom systems. By understanding these concepts, you will be better prepared to work as an Aerospace Engineer.
Architectural Engineer
An Architectural Engineer designs buildings and other structures, such as bridges, tunnels, and towers. Those who wish to enter this profession typically must have strong analytical skills, a keen attention to detail, and a working knowledge of blueprints and building codes. Architectural Engineers typically hold a Bachelor’s degree in Architectural Engineering or a related field. In this Introduction to Advanced Vibrations course, you will learn about structural vibrations, which can inform your work as an Architectural Engineer. By understanding these concepts, you will be better prepared to design structures that are safe.
Chemical Engineer
A Chemical Engineer designs chemical plants, equipment, and processes. They also work to improve the efficiency and safety of chemical processes. Chemical Engineers typically hold a Bachelor’s degree in Chemical Engineering. Some employers might accept related degrees, such as Chemistry, but these candidates might have to complete additional coursework in Chemical Engineering. In this Introduction to Advanced Vibrations course, you will learn about linear multiple-degree-of-freedom systems, which can inform your work as a Chemical Engineer. By understanding these concepts, you will be better prepared to design chemical plants.
Industrial Engineer
An Industrial Engineer designs and improves systems for producing and delivering goods and services. Industrial Engineers typically hold a Bachelor’s degree in Industrial Engineering.
Nuclear Engineer
A Nuclear Engineer designs and operates nuclear power plants and other nuclear facilities. Nuclear Engineers typically hold a Bachelor’s degree in Nuclear Engineering.
Software Engineer
A Software Engineer designs, develops, and maintains software applications. Software Engineers typically hold a Bachelor’s degree in Computer Science or a related field.
Manufacturing Engineer
A Manufacturing Engineer designs, develops, and implements manufacturing processes. Manufacturing Engineers typically hold a Bachelor’s degree in Manufacturing Engineering.
Materials Engineer
A Materials Engineer designs and develops materials used in a variety of products, such as cars, airplanes, and computers. Materials Engineers typically hold a Bachelor’s degree in Materials Engineering.
Petroleum Engineer
A Petroleum Engineer designs and develops methods for extracting oil and gas from the earth. Petroleum Engineers typically hold a Bachelor’s degree in Petroleum Engineering.

Reading list

We've selected nine books that we think will supplement your learning. Use these to develop background knowledge, enrich your coursework, and gain a deeper understanding of the topics covered in Introduction to Advanced Vibrations.
Comprehensive resource on vibration and control, and it is particularly useful for students and researchers in the field. It provides a solid foundation in vibration theory and covers topics such as modal analysis, damping, and control techniques.
Classic textbook on vibration and it provides a comprehensive treatment of the subject. It is particularly useful for students and researchers who are interested in a more in-depth understanding of vibration theory.
Comprehensive resource on vibration theory and it is particularly useful for students and researchers who are interested in a more theoretical treatment of the subject.
Comprehensive resource on the dynamics of structures and it is particularly useful for students and researchers who are interested in earthquake engineering.
Comprehensive resource on structural dynamics and it is particularly useful for students and researchers who are interested in the theoretical and computational aspects of the subject.
Comprehensive resource on the vibration of mechanical systems and it is particularly useful for students and researchers who are interested in the theoretical and computational aspects of the subject.
Comprehensive resource on vibration and it is particularly useful for students and researchers who are interested in the theoretical and computational aspects of the subject.
Comprehensive resource on the vibration of plates and shells and it is particularly useful for students and researchers who are interested in the theoretical and computational aspects of the subject.
Comprehensive resource on vibration and sound and it is particularly useful for students and researchers who are interested in the theoretical and computational aspects of the subject.

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