College Physics II – Mechanics, Sound, Oscillations, and Waves

Unit 1 – Units and Measurement in Physics

Unit 2 – Vectors in Physics

Unit 3 – Motion in a Straight Line

Unit 4 – Motion in 2D and 3D

Unit 5 – Newton's Laws of Motion

Unit 6 – Newton's Laws: Applications in Physics

Unit 7 – Work and Kinetic Energy

Unit 8 – Potential Energy & Energy Conservation

Unit 9 – Linear Momentum and Collisions

Unit 10 – Fixed-Axis Rotation

Unit 11 – Angular Momentum in Physics

Unit 12 – Static Equilibrium and Elasticity

Unit 13 – Gravitation: Fundamental Force of Attraction

Unit 14 – Fluid Mechanics

Unit 15 – Oscillations in Physics

Unit 16 – Waves in Physics

Unit 17 – Sound: Waves, Properties, and Perception

## What do you learn in College Physics: Mechanics, Sound, Oscillations, and Waves

You'll cover the basics of classical mechanics, including Newton's laws, energy, and momentum. Then you'll dive into sound waves, vibrations, and oscillations. You'll learn about simple harmonic motion, wave properties, and interference. The course also touches on fluid mechanics and thermodynamics, giving you a solid foundation in physics principles.

## Is College Physics: Mechanics, Sound, Oscillations, and Waves hard?

It can be challenging, especially if you're not a math whiz. The concepts aren't too bad, but applying them to problem-solving can be tricky. The math isn't super advanced, but you'll need to be comfortable with algebra and basic trigonometry. Most students find it manageable with consistent effort and practice. Don't let the equations scare you off, though - it's doable if you stay on top of the material.

## Tips for taking College Physics: Mechanics, Sound, Oscillations, and Waves in college

1. Use [Fiveable Study Guides](https://fiveable.me/cram-mode) to help you cram 🌶️
2. Practice, practice, practice! Do extra problems beyond homework.
3. Draw diagrams for every problem - it helps visualize forces and motion.
4. Form a study group to tackle tough concepts together.
5. Use online resources like Khan Academy for extra explanations.
6. Don't just memorize equations; understand the concepts behind them.
7. Review your notes regularly, not just before exams.
8. Watch "Cosmos: A Spacetime Odyssey" for mind-blowing physics context.
9. Try explaining concepts to others - it'll help solidify your understanding.
10. Don't be afraid to ask your professor or TA for help when you're stuck.

## Common pre-requisites for College Physics: Mechanics, Sound, Oscillations, and Waves

1. Calculus I: This course covers limits, derivatives, and basic integration. It's essential for understanding the mathematical foundations of physics.

2. Pre-Calculus: This class focuses on functions, trigonometry, and analytical geometry. It provides the mathematical tools needed for physics problem-solving.

## Classes similar to College Physics: Mechanics, Sound, Oscillations, and Waves

1. Classical Mechanics: This course dives deeper into Newtonian mechanics and introduces Lagrangian and Hamiltonian formulations. It's a more advanced look at the principles you'll learn in College Physics.

2. Thermodynamics: This class focuses on heat, energy, and their relationships to matter. It builds on some concepts from College Physics and applies them to larger systems.

3. Electromagnetism: This course covers electric and magnetic fields, Maxwell's equations, and electromagnetic waves. It's another fundamental area of physics that complements mechanics.

4. Optics: This class explores the behavior of light, including reflection, refraction, and interference. It's closely related to the waves portion of College Physics.

## Majors related to College Physics: Mechanics, Sound, Oscillations, and Waves

1. Physics: Focuses on understanding the fundamental laws governing the universe. Students study everything from subatomic particles to cosmic phenomena.

2. Engineering: Applies physics principles to design and build structures, machines, and systems. Different branches include mechanical, electrical, and civil engineering.

3. Astronomy: Studies celestial objects, space, and the physical universe as a whole. It heavily relies on physics principles to understand cosmic phenomena.

4. Applied Mathematics: Uses mathematical methods to solve real-world problems. Many of these problems involve physical systems, making physics knowledge crucial.

## What can you do with a degree in College Physics: Mechanics, Sound, Oscillations, and Waves?

1. Research Scientist: Conducts experiments and analyzes data to advance scientific knowledge. They might work in academia, government labs, or private research institutions.

2. Acoustical Engineer: Designs and develops sound systems or noise control solutions. They apply principles of sound and vibration to various industries, from music to construction.

3. Medical Physicist: Uses physics principles to develop and improve medical technologies. They might work on imaging techniques, radiation therapy, or other medical applications.

4. Data Scientist: Analyzes complex data sets to extract meaningful insights. The problem-solving and analytical skills from physics are highly valuable in this field.

## College Physics: Mechanics, Sound, Oscillations, and Waves FAQs

1. Do I need to be good at math to succeed in this class? You don't need to be a math genius, but being comfortable with algebra and basic trig is important. The math isn't super advanced, but you'll use it a lot.

2. Are there lab components to this course? Most College Physics courses include a lab section where you'll conduct experiments related to the concepts you're learning. It's a great way to see the principles in action.

3. How does this course differ from AP Physics in high school? College Physics typically goes more in-depth and covers topics at a faster pace. It also usually involves more rigorous problem-solving and mathematical applications.

4. Can I use a calculator during exams? This varies by professor, but many allow scientific calculators. Some might restrict graphing calculators, so always check your syllabus or ask your professor.

Physics

1.1 The Scope and Scale of Physics

1.2 Units and Standards

1.3 Unit Conversion

1.4 Dimensional Analysis

1.5 Estimates and Fermi Calculations

1.6 Significant Figures

1.7 Solving Problems in Physics

2.1 Scalars and Vectors

2.2 Coordinate Systems and Components of a Vector

2.3 Algebra of Vectors

2.4 Products of Vectors

3.1 Position, Displacement, and Average Velocity

3.2 Instantaneous Velocity and Speed

3.3 Average and Instantaneous Acceleration

3.4 Motion with Constant Acceleration

3.5 Free Fall

3.6 Finding Velocity and Displacement from Acceleration

4.1 Displacement and Velocity Vectors

4.2 Acceleration Vector

4.3 Projectile Motion

4.4 Uniform Circular Motion

4.5 Relative Motion in One and Two Dimensions

5.1 Forces

5.2 Newton's First Law

5.3 Newton's Second Law

5.4 Mass and Weight

5.5 Newton’s Third Law

5.6 Common Forces

5.7 Drawing Free-Body Diagrams

6.1 Solving Problems with Newton’s Laws

6.2 Friction

6.3 Centripetal Force

6.4 Drag Force and Terminal Speed

7.1 Work

7.2 Kinetic Energy

7.3 Work-Energy Theorem

7.4 Power

8.1 Potential Energy of a System

8.2 Conservative and Non-Conservative Forces

8.3 Conservation of Energy

8.4 Potential Energy Diagrams and Stability

8.5 Sources of Energy

9.1 Linear Momentum

9.2 Impulse and Collisions

9.3 Conservation of Linear Momentum

9.4 Types of Collisions

9.5 Collisions in Multiple Dimensions

9.6 Center of Mass

9.7 Rocket Propulsion

10.1 Rotational Variables

10.2 Rotation with Constant Angular Acceleration

10.3 Relating Angular and Translational Quantities

10.4 Moment of Inertia and Rotational Kinetic Energy

10.5 Calculating Moments of Inertia

10.6 Torque

10.7 Newton’s Second Law for Rotation

10.8 Work and Power for Rotational Motion

11.1 Rolling Motion

11.2 Angular Momentum

11.3 Conservation of Angular Momentum

11.4 Precession of a Gyroscope

12.1 Conditions for Static Equilibrium

12.2 Examples of Static Equilibrium

12.3 Stress, Strain, and Elastic Modulus

12.4 Elasticity and Plasticity

13.1 Newton's Law of Universal Gravitation

13.2 Gravitation Near Earth's Surface

13.3 Gravitational Potential Energy and Total Energy

13.4 Satellite Orbits and Energy

13.5 Kepler's Laws of Planetary Motion

13.6 Tidal Forces

13.7 Einstein's Theory of Gravity

14.1 Fluids, Density, and Pressure

14.2 Measuring Pressure

14.3 Pascal's Principle and Hydraulics

14.4 Archimedes’ Principle and Buoyancy

14.5 Fluid Dynamics

14.6 Bernoulli’s Equation

14.7 Viscosity and Turbulence

15.1 Simple Harmonic Motion

15.2 Energy in Simple Harmonic Motion

15.3 Comparing Simple Harmonic Motion and Circular Motion

15.4 Pendulums

15.5 Damped Oscillations

15.6 Forced Oscillations

16.1 Traveling Waves

16.2 Mathematics of Waves

16.3 Wave Speed on a Stretched String

16.4 Energy and Power of a Wave

16.5 Interference of Waves

16.6 Standing Waves and Resonance

17.1 Sound Waves

17.2 Speed of Sound

17.3 Sound Intensity

17.4 Normal Modes of a Standing Sound Wave

17.5 Sources of Musical Sound

17.6 Beats

17.7 The Doppler Effect

17.8 Shock Waves

Browse all College Physics II – Mechanics, Sound, Oscillations, and Waves Key Terms

About Us

Resources

Stay Connected

© 2024 Fiveable Inc. All rights reserved.

AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.

About Us

Resources

© 2024 Fiveable Inc. All rights reserved.

AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.

Back

Next