Simple Harmonic Motion and Waves

Subject: Physics
Topic: 5
Cambridge Code: 0625

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Simple Harmonic Motion

SHM - Oscillation with restoring force proportional to displacement

Defining SHM

$a = -ω^2x$

Where:

• a = acceleration
• ω = angular frequency
• x = displacement from equilibrium
• Negative sign indicates opposite direction

Equations of Motion

Displacement: $x = A\cos(ωt)$ or $x = A\sin(ωt)$

Velocity: $v = -Aω\sin(ωt)$ or $v = Aω\cos(ωt)$

Acceleration: $a = -Aω^2\cos(ωt) = -ω^2x$

Where:

• A = amplitude
• ω = angular frequency = 2πf = 2π/T
• f = frequency (Hz)
• T = period (s)

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Energy in SHM

Total mechanical energy (constant): $E_{\text{total}} = \frac{1}{2}kA^2$

Where k is spring constant

Kinetic energy: $E_k = \frac{1}{2}mv^2 = \frac{1}{2}mω^2(A^2 - x^2)$

Potential energy: $E_p = \frac{1}{2}kx^2 = \frac{1}{2}mω^2x^2$

Energy oscillates between KE and PE

Maximum Values

Maximum velocity: $v_{\text{max}} = Aω$

• Occurs at equilibrium (x = 0)

Maximum acceleration: $a_{\text{max}} = Aω^2$

• Occurs at maximum displacement (x = ±A)

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Examples of SHM

Mass-Spring System

Spring force: $F = -kx$ $a = -\frac{k}{m}x$

Frequency: $f = \frac{1}{2π}\sqrt{\frac{k}{m}}$

Period: $T = 2π\sqrt{\frac{m}{k}}$

Simple Pendulum

For small angles: $a ≈ -\frac{g}{L}x$

Period: $T = 2π\sqrt{\frac{L}{g}}$

• Independent of mass (!)
• Independent of amplitude (for small angles)
• Depends on length and g

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Damped Oscillations

Damping - Energy loss due to friction, air resistance

Types:

1. Light damping: Oscillates with decreasing amplitude
2. Critical damping: Returns to equilibrium without oscillating
3. Heavy damping: Slow return to equilibrium

Amplitude decreases: $A(t) = A_0e^{-t/τ}$

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Forced Oscillations and Resonance

Forced oscillation - External driving force causes vibration

Resonance - Maximum amplitude when driving frequency = natural frequency

$f_{\text{drive}} = f_{\text{natural}}$

Characteristics:

• Dramatic amplitude increase
• Occurs at natural frequency
• Damping affects amplitude and sharpness
• Practical examples: bridges, buildings, speakers

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Wave Properties

Wave - Disturbance propagating through medium

Wave Types

Transverse: Oscillation perpendicular to propagation

• Light, water ripples, S-waves (earthquakes)

Longitudinal: Oscillation parallel to propagation

• Sound, P-waves (earthquakes)

Wavelength and Frequency

Wavelength (λ) - Distance between successive wavefronts

Wave speed: $v = fλ$

Where:

• v = wave speed
• f = frequency
• λ = wavelength

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Electromagnetic Spectrum

Arranged by frequency/wavelength:

Radio → Microwave → Infrared → Visible → UV → X-ray → Gamma

• Increasing frequency (left to right)
• Decreasing wavelength (left to right)
• All travel at speed of light (c = 3 × 10⁸ m/s) in vacuum

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Sound Waves

Speed of sound:

• Air (20°C): 343 m/s
• Water: 1480 m/s
• Solids: 3000-6000 m/s
• Increases with temperature

Frequency and Pitch

Frequency determines pitch:

• Higher frequency → higher pitch
• Human hearing: 20 Hz to 20,000 Hz
• Ultrasound: > 20 kHz

Intensity and Loudness

Intensity: Power per unit area (W/m²)

Decibel scale: $L = 10\log_{10}\frac{I}{I_0}$

Where $I_0 = 10^{-12}$ W/m² (threshold of hearing)

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Superposition and Interference

Superposition - Waves combine by adding displacements

Constructive Interference

Waves in phase:

• Path difference = nλ (n = 0, 1, 2, ...)
• Amplitudes add
• Maximum intensity

Destructive Interference

Waves out of phase:

• Path difference = (n + ½)λ
• Amplitudes cancel
• Minimum intensity

Standing Waves

Formation: Interference of waves traveling in opposite directions

Nodes: Points of zero displacement Antinodes: Points of maximum displacement

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Diffraction

Diffraction - Bending of waves around obstacles

Single-Slit Diffraction

First minimum: $a\sin θ = λ$

Where a = slit width

Narrower slit → wider diffraction pattern

Diffraction Through Door

Audible if wavelength > door width

• Low frequency (longer λ): Easy to hear around corner
• High frequency (shorter λ): Difficult to hear

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Doppler Effect

Frequency change when source moves:

$f' = f\frac{v ± v_{\text{observer}}}{v ∓ v_{\text{source}}}$

Source approaching: f' > f (frequency increases, sounds higher) Source receding: f' < f (frequency decreases, sounds lower)

Applications: Radar speed guns, astronomy

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Key Points

1. SHM: a = -ω²x
2. Energy in SHM oscillates between KE and PE
3. Period T = 2π/ω
4. Pendulum period independent of mass
5. Wave speed = frequency × wavelength
6. Constructive interference: path difference = nλ
7. Destructive interference: path difference = (n+½)λ
8. Resonance at natural frequency
9. Doppler effect: frequency changes with relative motion
10. Standing waves have nodes and antinodes

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Practice Questions

1. Solve SHM equations
2. Calculate periods
3. Analyze energy in SHM
4. Calculate wave properties
5. Apply wave equation
6. Solve interference problems
7. Analyze diffraction patterns
8. Calculate Doppler shifts
9. Predict standing wave patterns
10. Solve resonance problems

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Revision Tips

• Understand SHM definition
• Know equations for x, v, a
• Understand energy interchange
• Know wave properties
• Practice interference calculations
• Understand constructive/destructive
• Know Doppler effect application
• Draw wave diagrams
• Understand resonance concept