Physics SL
5
Chapters
329
Notes
Theme A - Space, Time & Motion
Theme B - The Particulate Nature Of Matter
Theme C - Wave Behaviour
Exploring Harmonic Oscillation: The Legacy of Joseph Fourier
Isochronous Oscillations: How Galileo Revolutionized Timekeeping
Understanding Periodic Motion: From Basics To Application
Understanding Simple Harmonic Motion: From Basics To Electromagnetic Radiation
Linking Circular Motion to Simple Harmonic Oscillation: An Insight
Unlocking Simple Harmonic Motion: Mass-Spring System Secrets
Simple Pendulum & Its Harmonic Motion Explained
Simple Harmonic Motion: Energy Transfers & Oscillation Insights
Linking Circular Motion To Simple Harmonic Motion: A Deep Dive
Unlocking Phase Angle: Dive Into Simple Harmonic Motion
Mastering Energy Equations in Harmonic Oscillators
Energy Transfer Through Waves: Mechanical Vs. Electromagnetic
Unlocking The Secrets Of Waves: Transverse Vs. Longitudinal Explained
Unlocking Wave Motion: Graphs Explained in Detail
Mastering Displacement-Distance Graphs in Wave Mechanics
Unlocking Displacement-Time Graphs: Dive Into Wave Mechanics!
Mastering Wave Equations: From Basics to Advanced Calculations
Unlocking The Secrets Of Sound Waves: From Smartphone To Ear
Unlocking the Secrets of Electromagnetic Waves: A Deep Dive
Unlocking Wavefronts & Rays: Dive Into 3D Wave Modelling!
Wavefronts & Rays: Unveiling The Mysteries Of Water Ripples
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Mastering Snell's Law: The Physics of Refraction Explained
Total Internal Reflection: From Ripple Tanks to Real-life Applications
Understanding The Principle Of Superposition In Waves
Unlocking Diffraction: From Grimaldi's Observations To Modern Science
Unveiling Light Diffraction: Single Slit Patterns Explained
Unraveling Diffraction Patterns
Understanding Single-Slit Diffraction: A Deep Dive
Understanding Double-Slit Interference and Coherence in Waves
Unlocking Light Mysteries: The Double-Slit Experiment
Unlocking The Double-Slit Equation: A Deep Dive Into Wave Interference
Unraveling Light's Mystery: Wave, Particle, or Both?
Unlocking The Secrets Of Multiple-Slit Interference
Unlocking Secrets of Diffraction Grating: A Deep Dive
Understanding Standing Waves: Origins & Key Principles
Understanding Standing Waves: Melde's Experiment Insights
Understanding Wave Reflection: Fixed vs. Free Ends Explained
Understanding String Harmonics: The Physics Behind Music
Exploring Harmonics: Free & Fixed Ends of Vibrating Strings
Unveiling Standing Waves: Understanding Harmonics & Calculations
Closed-End Reflection: Unraveling Longitudinal Waves in Pipes
Sound Wave Reflection: Understanding Open-End Pipe Phenomenon
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Unlocking The Secrets Of Natural Frequency In Mechanical Systems
Understanding Damping: From Light to Critical Oscillations
Understanding Forced Vibrations and Resonance Dynamics
Exploring Resonance: Advantages, Disadvantages & Real-World Applications
Understanding The Doppler Effect: More Than Just Sirens
Understanding The Doppler Effect: A 3D Perspective
Understanding The Doppler Effect: Moving Source Vs. Stationary Observer
Understanding The Doppler Effect: Light vs. Sound Waves
Unveiling Medical Ultrasound: Doppler Effect in Diagnostics
Radar & Doppler Effect: Unveiling Astronomical Secrets
Theme D - Fields
Theme E - Nuclear & Quantum Physics
Physics SL
Theme C - Wave Behaviour
Exploring Harmonic Oscillation: The Legacy of Joseph Fourier
658 words
4 mins read
Last edited on 5th Nov 2024
Table of content
Simple harmonic motion (SHM)
- What is it? SHM is like a dance. Imagine a swing going back and forth in a rhythm.
- Conditions: True SHM is a bit picky. It only shows up in certain systems with small displacements (think of it like trying to make a swing move with just a little push).
- Usage: Even if true SHM is a rare bird, we can still use its model for systems by playing by its rules.
🌍 Real-world Example: The pendulum of a grandfather clock moving back and forth is a good example of SHM. But if we push the pendulum too hard, it doesn't follow the SHM pattern anymore!
Meet joseph fourier - the wave maestro 🎼
- Who?: A French dude who loved math and physics (1768-1830).
- What did he do?: In 1807, Fourier gave a speech in Paris about how heat travels in solid objects. But the cool part? He used math to break down complex wavy movements into simple sine waves!
🌍 Real-world Example: Imagine listening to a song with multiple instruments. Fourier's method would be like identifying each individual instrument's sound wave from the whole musical mess!
Try it yourself - fourier's wave party 🎉
- Function Fun: Use a calculator or spreadsheet to plot y = sinx + 1/3 sin3x + 1/5 sin5x + ...
- For math nerds: Add terms of 1/n sinnx for odd values of integer n.
- Result: After a few terms, you’ll see this party of sine waves starts to form a square-wave shape! 📊
🌍 Real-world Example: Imagine you're combining different sound notes. Each note has its own wave. When you add them together, you can get a new, unique sound wave, just like our square-wave!
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Physics SL
Theme C - Wave Behaviour
Exploring Harmonic Oscillation: The Legacy of Joseph Fourier
658 words
4 mins read
Last edited on 5th Nov 2024
Table of content
Simple harmonic motion (SHM)
- What is it? SHM is like a dance. Imagine a swing going back and forth in a rhythm.
- Conditions: True SHM is a bit picky. It only shows up in certain systems with small displacements (think of it like trying to make a swing move with just a little push).
- Usage: Even if true SHM is a rare bird, we can still use its model for systems by playing by its rules.
🌍 Real-world Example: The pendulum of a grandfather clock moving back and forth is a good example of SHM. But if we push the pendulum too hard, it doesn't follow the SHM pattern anymore!
Meet joseph fourier - the wave maestro 🎼
- Who?: A French dude who loved math and physics (1768-1830).
- What did he do?: In 1807, Fourier gave a speech in Paris about how heat travels in solid objects. But the cool part? He used math to break down complex wavy movements into simple sine waves!
🌍 Real-world Example: Imagine listening to a song with multiple instruments. Fourier's method would be like identifying each individual instrument's sound wave from the whole musical mess!
Try it yourself - fourier's wave party 🎉
- Function Fun: Use a calculator or spreadsheet to plot y = sinx + 1/3 sin3x + 1/5 sin5x + ...
- For math nerds: Add terms of 1/n sinnx for odd values of integer n.
- Result: After a few terms, you’ll see this party of sine waves starts to form a square-wave shape! 📊
🌍 Real-world Example: Imagine you're combining different sound notes. Each note has its own wave. When you add them together, you can get a new, unique sound wave, just like our square-wave!
Unlock the Full Content!
Dive deeper and gain exclusive access to premium files of Physics SL. Subscribe now and get closer to that 45 🌟
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