Physics - Rotational Motion 2 - Dynamics - College and AP from Udemy

This course is one of several courses designed for Algebra Based AP Physics 1. In this course we will dive into Rotational Motion, specifically Rotational Dynamics, which includes Torque, Center of Mass, Balance, and Rotational Inertia.

The videos and resources will include lectures, demonstrations, and plenty of worked out example problems with High School physics curriculum and the AP Physics 1 curriculum in mind. This is perfect for any student planning to take the AP exam or any Introductory College physics student. While this course does not cover calculus based physics, any student enrolled in such course will still benefit from the ground work laid out here.

While this course does have sections for both High School and AP Level Physics, the videos intended for the AP crowd will be clearly labeled.

What's inside

Learning objective

This rotational motion course will specifically focus on rotational dynamics including torque and rotational inertia

Syllabus

Center of Mass, Torque, Stability, and Equilibrium

Rotational Dynamics Workbook

Physics Course Online Course Map

1 - Center of Mass Intro

Traffic lights

Read about what's good

what should give you pause

and possible dealbreakers

Provides a strong foundation in rotational dynamics, which is essential for success in more advanced physics courses and engineering disciplines

Includes lectures, demonstrations, and worked examples, which are helpful for visual learners and those who benefit from step-by-step problem-solving

Focuses on algebra-based physics, which may not be suitable for students who require a calculus-based approach to rotational dynamics

Specifically designed for the AP Physics 1 curriculum, which makes it highly relevant for students preparing for the AP exam

Covers topics such as torque, center of mass, balance, and rotational inertia, which are fundamental concepts in mechanics and engineering

Reviews summary

Rotational dynamics for college and ap physics

According to learners, this course provides a strong foundation for understanding rotational dynamics, specifically covering concepts like torque and rotational inertia. Many students preparing for AP Physics 1 or introductory college physics find the explanations and worked examples clear and helpful. Reviewers appreciate the focus on algebra-based physics, making complex topics accessible. Some highlight the usefulness of the provided resources, including workbooks and example problems. Overall, the course is considered a valuable resource for mastering this specific physics topic, particularly for exam preparation and foundational understanding.

Concentrates specifically on rotational dynamics.

"This course really focuses tightly on rotational dynamics as advertised."

"It doesn't cover all of rotational motion, just dynamics, which is fine."

"The scope is very specific to torque and inertia."

"Perfect if you only need a deep dive into this one area."

Workbooks and supplemental materials are useful.

"The workbook provided was a great supplement to the videos."

"Liked having the course map and extra resources available."

"The conceptual examples really made me think."

"The materials supported the video lessons effectively."

Provides a strong base in rotational dynamics.

"Gave me a solid understanding of the fundamental principles."

"Great course for building the groundwork for rotational motion."

"Helped me build confidence in my understanding of dynamics."

"Learned the core ideas of torque and inertia very well."

Plenty of helpful example problems provided.

"The worked examples were incredibly helpful for practice."

"Seeing the problems worked out step-by-step solidified my learning."

"Found the examples section invaluable for applying the concepts."

"The problems covered a good range of difficulties."

Concepts are explained clearly and concisely.

"The instructor explains the concepts really clearly."

"Helped me finally understand torque and rotational inertia through clear lectures."

"I liked the straightforward way the material was presented, easy to follow."

"The videos made complex topics easy to grasp."

Well-suited for AP Physics 1 preparation.

"This course is perfect for preparing for the AP Physics 1 exam."

"It covered exactly what I needed for my AP class."

"Felt much more confident about rotational motion on the AP test after this."

"Highly recommend for anyone taking algebra-based AP Physics."

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 Physics - Rotational Motion 2 - Dynamics - College and AP with these activities:

Review Linear Motion Concepts

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Reinforce your understanding of linear motion concepts, as they form the foundation for understanding rotational motion.

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Review definitions of displacement, velocity, and acceleration.
Practice solving problems involving constant acceleration.
Review Newton's Laws of Motion.

Read 'Fundamentals of Physics' Chapter on Rotational Motion

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Deepen your understanding of rotational motion by reading a chapter from a standard physics textbook.

View Principles of Physics, Extended on Amazon

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Read the chapter on rotational motion.
Work through the example problems in the chapter.
Attempt the end-of-chapter problems.

Torque Calculation Practice

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Sharpen your skills in calculating torque for various scenarios, which is crucial for understanding rotational dynamics.

Browse courses on Torque

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Solve problems involving torque calculation with different force application points.
Practice calculating torque using different angles between force and lever arm.
Work through problems involving multiple torques acting on an object.

Three other activities

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Explore 'Physics for Scientists and Engineers' for Advanced Topics

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Expand your understanding of rotational motion with a more advanced physics textbook.

View Physics for Scientists and Engineers, Cengage... on Amazon

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Read relevant sections on rotational dynamics.
Review the worked examples and try the practice problems.

Create a Rotational Motion Demonstration

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Solidify your understanding by creating a video demonstrating rotational motion principles, such as conservation of angular momentum.

Browse courses on Rotational Motion

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Plan a demonstration showcasing a rotational motion concept.
Gather materials and equipment for the demonstration.
Record a video explaining the concept and demonstrating it.
Edit the video and add explanations.

Design a Rotational Inertia Experiment

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Apply your knowledge by designing an experiment to measure the rotational inertia of different objects.

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Choose objects with different shapes and mass distributions.
Develop a procedure to measure the rotational inertia.
Conduct the experiment and record the data.
Analyze the data and compare the results with theoretical calculations.

Career center

Learners who complete Physics - Rotational Motion 2 - Dynamics - College and AP will develop knowledge and skills that may be useful to these careers:

Mechanical Engineer

A mechanical engineer designs, develops, and tests mechanical devices. This often involves the understanding of rotational motion and dynamics. This course specifically explores rotational dynamics, including torque, center of mass, and rotational inertia, all of which are fundamental concepts in mechanical engineering. A solid understanding of these principles, as taught in this course, is crucial for analyzing and designing mechanical systems, such as engines, machines, and robotics. The course's focus on example problems and worked solutions can greatly help a mechanical engineer develop practical problem solving skills.

See salaries and explore the career path for Mechanical Engineer

Automotive Engineer

Automotive engineers design and develop vehicles. A central component of their job is understanding rotational dynamics. This course, with its focus on torque, rotational inertia, and the center of mass, helps an automotive engineer understand how vehicle components like wheels, axles, and engines behave. The course's emphasis on worked examples provides valuable skills for solving practical engineering problems encountered in the automotive field. They need to account for the rotational motion of tires, gears, and engine parts.

See salaries and explore the career path for Automotive Engineer

Aerospace Engineer

Aerospace engineers design aircraft, spacecraft, and satellites. An understanding of rotational motion is crucial because these vehicles rotate on their axes. Therefore, this course on rotational dynamics, which includes torque, center of mass, and rotational inertia, directly applies to the field of aerospace engineering. The course can help an aerospace engineer analyze the stability and control of aircraft and spacecraft. The worked examples and conceptual explanations in the course, related to dynamics, are very useful in this career.

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Simulation Engineer

Simulation engineers use software to model and simulate complex systems. Understanding rotational motion is crucial, especially when modeling physical systems in motion. This course on rotational dynamics including topics like torque and inertia, will help the simulation engineer build accurate models of rotating objects. The principles of rotational dynamics shown here are critical for creating realistic simulations. The course's focus on problem solving and examples is very useful in this capacity.

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Test Engineer

Test engineers develop and conduct tests to evaluate the performance of products. Understanding rotational motion and its related dynamics is important when designing tests for rotating equipment or systems. This course covers center of mass, torque, and rotational inertia. The principles explained here directly contribute to designing effective test protocols that accurately gauge the performance and safety of devices involving rotation. A test engineer will find the course's worked examples and clear explanations beneficial.

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Robotics Engineer

Robotics engineers design, build and program robots. Rotational motion is central to the design of robotic arms, wheels and joints. This course, which covers rotational dynamics, including torque, center of mass, and rotational inertia, helps robotic engineers understand how to control and predict the movements of robotic systems. The problem-solving approach of this course, with its worked examples, helps a robotics engineer design robots that are stable and efficient.

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Structural Engineer

Structural engineers analyze and design structures that support and withstand loads. Concepts like torque and stability, which are taught in this course, are crucial for analyzing how loads and forces affect structural integrity. The course's focus on center of mass and equilibrium is valuable for understanding how structures remain stable under different forces. The practical approach of this course, with its worked examples, provides a strong foundation in these core concepts needed by a structural engineer.

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High School Physics Teacher

A High School Physics teacher educates students on the principles of physics. Teaching rotational motion is a central aspect of high school physics curricula, especially in AP Physics. This course covers the key areas of rotational dynamics including torque and rotational inertia, therefore this course may be of great use for a physics teacher who wants to deepen their knowledge, or prepare for classroom instruction. The course's structure, with its lectures, demonstrations, and worked examples, provides insight on how to engage and teach students.

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Curriculum Developer

A curriculum developer designs educational materials and learning experiences. This course, with its focus on rotational dynamics, including torque, center of mass, and rotational inertia, provides a well-structured approach to teaching this complex topic. A curriculum developer can use this course as a reference for structuring their own courses. The course's inclusion of lectures, demonstrations, and worked examples offers practical insights into effective teaching methods. The level and content of this course is useful in understanding the needs of students taking high school or introductory college courses.

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College Physics Professor

College physics professors teach physics at the undergraduate level, often covering topics like rotational mechanics. While this course covers algebra based physics and not calculus, the course will be useful for instructors to understand the fundamentals clearly. The course's focus on torque, center of mass, and rotational inertia, provides a foundational understanding that a college professor can build upon, and use in instruction. The inclusion of demonstrations and worked examples in this course also helps a professor develop effective teaching practices.

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Product Designer

A product designer creates physical products that are functional and aesthetically pleasing. Considering rotational dynamics, especially aspects like torque and stability, is crucial when designing products with moving parts. This course, which covers rotational motion concepts, can help a product designer understand how forces and motion impact design. For example, a product's stability relies on the principles of torque, which are explored here in this course. A product designer can use these concepts in their design work.

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Civil Engineer

Civil engineers design and oversee the construction of infrastructure projects. While this role is heavily involved with structural analysis, understanding rotational dynamics, such as torque and stability, is important for designing structures that are safe and stable. Understanding the concepts of center of mass and equilibrium, as taught in this course, helps a civil engineer analyze how forces interact with structures. This course, with its focus on practical examples and problem-solving, may be valuable for civil engineers tackling complex structural problems.

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Science Writer

A science writer communicates scientific concepts to a general audience. They often need a sound understanding of physics. This course may be helpful for a science writer covering rotational dynamics. The course's explanations of torque, center of mass and rotational inertia provide a solid base. The course's inclusion of demonstrations and worked examples aids the science writer in understanding the practical implications of these concepts, which is useful for communicating them to a wider audience.

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Research Scientist

Research scientists conduct experiments and investigations in various scientific fields. Depending on their field, a research scientist may need a deep understanding of rotational motion. This course, which delves into rotational dynamics, including torque, center of mass, and rotational inertia, may be helpful, depending on the research. This course helps the research scientist develop a strong grasp of the underlying principles, which can be useful in experimental design and analysis. The course's focus on examples helps the research scientist appreciate how theory is used practically.

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Data Analyst

Data analysts interpret and analyze data. While they don't directly work with physics, they require a strong foundation in problem solving and conceptual thinking. This course may be useful in helping a data analyst develop better analytical skills. The course's focus on problem solving, with worked examples, helps develop the analytical mindset needed for this role. This course's clear teaching of physics through the use of worked examples can help someone in any analytical field.

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Physics - Rotational Motion 2 - Dynamics - College and AP

What's inside

Learning objective

Syllabus

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Reviews summary

Rotational dynamics for college and ap physics

Activities

Career center

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