〰️ Chapter At a Glance
84.6 min
Max Time Period of Pendulum
3×10⁸ m/s
Speed of EM Waves
340 m/s
Speed of Sound in Air
20–20000 Hz
Human Hearing Range
  • Periodic Motion — repeats at regular intervals along a fixed path
  • SHM — oscillation about mean position on a straight line; acceleration directed toward mean position
  • Waves — carriers of energy; two types: Mechanical & Electromagnetic
  • Sound — longitudinal mechanical wave; travels fastest in solids
  • Key topics: SHM · Simple Pendulum · EM spectrum · Sound characteristics · Echo · Mach number
📊 Key Formulae — Quick Look
T = 2π/ωTime Period (SHM)
T = 2π√(l/g)Simple Pendulum Time Period
n = 1/TFrequency | Unit: Hz
v = nλWave Speed
λ = v/nWavelength
v ∝ √TSpeed of Sound ∝ √Temperature
🔄 Periodic Motion & SHM
Periodic Motion
Regular Repetitive Motion

Motion that repeats itself along a fixed path at a regular interval of time.

  • Motion of a swing
  • Motion of a fan
  • Vibrations in musical instruments
  • Motion of a satellite around Earth
Simple Harmonic Motion (SHM)
Oscillation About Mean Position

Repetition of motion about the mean position on a straight line. Acceleration always directed toward the mean position.

  • Clock's pendulum
  • Load on a spring
  • Ball hanging from rigid support
📐 Important Terms in SHM
Term Meaning Formula / Unit
Displacement Change in position of particle relative to origin metres (m)
Amplitude Position of maximum displacement metres (m)
Phase Term expressing the direction of motion
Time Period (T) Time to complete one full vibration T = 2π/ω (seconds)
Frequency (n) Number of vibrations per second n = 1/T | Hz
Wavelength (λ) Distance between two successive crests or troughs λ = v/n | metres
⚠️ Exam Trap
  • In SHM, acceleration is NOT constant — it varies with displacement
  • Acceleration direction = always toward mean position (restoring force)
  • Frequency (Hz) = 1/Time Period. Higher frequency → shorter time period
🕰️ Simple Pendulum
📘 Definition

A heavy point mass (bob) suspended from a fixed support by a light, inextensible string, free to oscillate under gravity.

T = 2π√(l/g)Time Period of Simple Pendulum | l = length, g = gravitational acceleration
84.6 min
Maximum Time Period (T_max)
∞ (Infinite)
Time Period in Satellite
No Effect
Mass of Bob on T
📋 Conditions Affecting Simple Pendulum
Condition Effect on Time Period (T) Reason
Going Up (altitude) on Earth Increases ↑ g decreases with altitude
Going Down (depth) on Earth Increases ↑ g decreases with depth
In a Satellite (orbit) Infinite (∞) Effective g = 0 (weightlessness)
Summer (Temperature ↑) Increases ↑ Length increases with heat
Winter (Temperature ↓) Decreases ↓ Length decreases with cold
On Moon Increases ↑ g_moon = g_earth/6 (much lower g)
Change in Mass No Change T is independent of mass
⚠️ Exam Trap — Pendulum
  • T does NOT depend on mass of the bob — most commonly asked trap!
  • T depends on length (l) and g only
  • Going up OR down both increase T (g decreases both ways)
  • In a satellite, pendulum does NOT oscillate — T = ∞
  • T_max = 84.6 minutes (pendulum with length = Earth's radius)
〰️ Wave Motion
  • Wave = Disturbance that carries energy from one place to another
  • Wave motion = process of transmission of disturbance with a certain velocity
v = λ/T = nλWave Speed | n = frequency, λ = wavelength, T = time period
📂 Types of Waves
Type A
Mechanical Waves — require a medium
LONGITUDINAL WAVES
  • Particles vibrate along direction of wave
  • Transmission: compression & rarefaction
  • Examples: Sound, seismic, tsunami, spring vibrations
TRANSVERSE WAVES
  • Particles vibrate perpendicular to direction of wave
  • Transmission: crests & troughs
  • Examples: Light wave, spring motion
Type B
Electromagnetic Waves — NO medium required
  • Generated by high-frequency electrical oscillations
  • Can travel through vacuum
  • Nature: Neutral & Transverse
  • Speed: 3 × 10⁸ m/s (in vacuum)
⚠️ Exam Trap
  • Sound = Longitudinal wave; Light = Transverse wave
  • Sound needs a medium; Light does NOT (can travel in vacuum)
  • EM waves are transverse in nature (NOT longitudinal)
📡 Electromagnetic Wave Spectrum
Radio
Micro
IR
Visible
UV
X-ray
γ-ray

← Increasing Wavelength  |  Increasing Frequency →

Wave Wavelength Discoverer (Year) Key Use
Radio Wave > 0.1 m Marconi (1895) Radio & TV communication
Microwave 1 m to 1 mm Heinrich Hertz (1888) Satellites, wireless communication
Infrared 1 mm to 700 nm Herschel (1800) Remote control, fog photography
Visible Light 700 nm to 400 nm Newton (1666) Human vision, electric bulb
Ultraviolet (UV) 400 nm to 1 nm Ritter (1801) Forged document detection, food preservation
X-Rays 1 nm to 10⁻³ nm Roentgen (1895) Bone fractures, lung diseases
Gamma (γ) Rays < 10⁻³ nm Paul Villard (1900) Cancer treatment, nuclear structure
📘 Special Note

Gamma rays were named by Rutherford, though discovered by Paul Villard (1900). Microwaves are generated by a device called magnetron.

⚠️ Exam Trap — EM Wave Discoverers
  • Radio → Marconi (1895) | Microwave → Hertz (1888)
  • Infrared → Herschel (1800) | UV → Ritter (1801)
  • X-Ray → Roentgen (1895) | γ-Ray → Paul Villard (1900), named by Rutherford
  • Visible light spectrum (VIBGYOR): Violet (400 nm) to Red (700 nm)
🔊 Sound Wave — Basics
  • Sound = hearing sensation in ears; a form of energy
  • Type: Longitudinal mechanical wave
  • Requires a medium to travel (cannot travel in vacuum)
📘 Sources of Sound

Clapping · Birds chirping · Lightning · Musical instruments · Vehicle sounds

📊 Characteristics of Sound Waves
1. Loudness
Intensity of Sound
  • Loudness ∝ (Amplitude)²
  • Loudness ∝ 1/(Distance)²
  • Unit: Watt/m², Decibel (dB), Phon
  • Noise above 85 dB is harmful for human ears
Sound Source Loudness (dB)
Normal Breathing 10 dB
Whisper 15–30 dB
General Conversation 30–60 dB
Busy Traffic 70 dB
Jet Plane 140–150 dB
2. Pitch
Shrillness of Sound
  • Pitch ∝ Frequency
  • Women's voice → Higher pitch (shrill)
  • Men's voice → Lower pitch (grave)
3. Quality / Timbre
Distinguishing Quality
  • Distinguishes two sounds of same pitch & loudness
  • Tone = single frequency sound
  • Note = sound of multiple frequencies
  • Example: Harmonium, sitar, sarangi have different timbre at same frequency
4. Intensity
Sound Energy per Unit Area per Second
  • Unit: Watt/m²
👂 Audible Range of Sound
< 20 Hz
Infrasonic
Seismic waves, heartbeat
20–20,000 Hz
Audible (Human)
Normal human hearing range
> 20,000 Hz
Ultrasonic
Bat, Dog, Dolphin, Cat
Animal / Entity Hearing Range
Dolphin 150 – 1,50,000 Hz
Bat 1,000 – 1,20,000 Hz
Dog 15 – 45,000 Hz
Cat 60 – 65,000 Hz
Children Up to 25,000 Hz
Human (Adult) 20 – 20,000 Hz
📘 Applications of Ultrasonic Waves
  • Ultrasonography & Echocardiography (medical imaging)
  • Measuring depth of sea (SONAR)
  • Detecting submarines, icebergs
  • Industrial cleaning, welding
⚠️ Exam Trap — Ultrasonic Users

Bat, Dog, Cat, Dolphin all use ultrasound. Bat uses it for navigation (echolocation). SONAR = Sound Navigation And Ranging — uses ultrasonic waves to detect underwater objects.

💨 Speed of Sound in Different Media
📘 Key Rules
  • Speed of sound: Solid > Liquid > Gas
  • Speed & wavelength change when medium changes
  • Frequency remains unchanged when moving between media
  • Depends on elasticity and density of medium
State Medium Speed at 25°C
Solid Aluminium 6420 m/s
Solid Nickel 6040 m/s
Solid Steel 5960 m/s
Solid Iron 5950 m/s
Solid Brass 4700 m/s
Solid Glass 3980 m/s
Liquid Sea Water 1531 m/s
Liquid Distilled Water 1498 m/s
Liquid Ethanol 1207 m/s
Liquid Methanol 1103 m/s
Gas Hydrogen 1284 m/s
Gas Helium 965 m/s
Gas Air 340 m/s
Gas Oxygen 316 m/s
Gas Sulphur Dioxide 213 m/s
🌡️ Effect of Temperature on Speed of Sound
v ∝ √TSpeed of sound increases with temperature (T in Kelvin)
  • At constant temperature, pressure has NO effect on speed of sound
  • Moisture (humidity) ↑ → Speed ↑ (moist air is lighter than dry air)
  • Rainy days: Sound of whistle heard from farther away (due to moisture)
Temperature Speed in Air
0°C 332 m/s
22°C 344 m/s
25°C 346 m/s
⚠️ Exam Trap — Speed of Sound
  • Pressure change at constant temperature has NO effect on speed of sound
  • Speed in air at room temperature ≈ 340 m/s
  • Sound travels fastest in solids (Aluminium = 6420 m/s)
  • Frequency does NOT change when medium changes — only speed & wavelength change
🔁 Reflection of Sound, Echo & Reverberation
Reflection of Sound
Sound striking a surface and returning

The phenomenon of sound striking a surface and returning back along the same path.

Echo
Re-hearing of sound
  • Persistence of sound in human ears = 0.1 seconds
  • Minimum distance between source and obstacle = 17.2 m
Reverberation
Persistence of sound after source stops
  • Sound persists even after source has stopped
  • Used in: Megaphone, Loudspeakers, Stethoscope
  • Cinema halls: walls made rough or covered with sound-absorbent material to prevent reverberation
⚠️ Exam Trap — Echo vs Reverberation
  • Echo = distinct repetition of sound (min distance 17.2 m)
  • Reverberation = prolonged sound due to multiple reflections
  • Persistence of hearing = 0.1 sec (1/10th of a second)
  • Stethoscope works on the principle of reverberation/multiple reflection
✈️ Mach Number
Mach No. = Speed of body / Speed of sound (same medium)Named after Ernst Mach
Mach < 1
Subsonic
1 < Mach ≤ 5
Supersonic
Mach > 5
Hypersonic
📘 Examples
  • Fighter jets (e.g., MiG, F-22) → Supersonic
  • Space shuttles during re-entry → Hypersonic
  • Commercial aircraft → Subsonic (~Mach 0.8)
⚠️ Exam Trap — Mach Classification
  • Supersonic = Mach 1 to 5 (NOT everything above 1)
  • Hypersonic = Mach > 5
  • Sonic boom is produced when aircraft crosses the sound barrier (Mach 1)
🎯 High-Frequency BPSC/BSSC Exam Points
  • SHM: acceleration always toward mean position
  • Simple Pendulum: T = 2π√(l/g) — independent of mass
  • T_max of pendulum = 84.6 minutes
  • Pendulum in satellite: T = (g = 0 in orbit)
  • Speed of EM waves in vacuum = 3 × 10⁸ m/s
  • EM waves: transverse, neutral, no medium required
  • Radio → Marconi (1895); X-Ray → Roentgen (1895); γ-Ray → Villard (1900), named by Rutherford
  • Sound = longitudinal mechanical wave
  • Speed of sound: Solid > Liquid > Gas
  • Speed of sound in air ≈ 340 m/s at 25°C
  • Loudness ∝ (Amplitude)² | Pitch ∝ Frequency
  • Noise > 85 dB is harmful for ears
  • Human hearing range: 20 Hz to 20,000 Hz
  • Ultrasonic users: Bat, Dog, Cat, Dolphin
  • Echo: persistence of hearing = 0.1 sec; min distance = 17.2 m
  • Mach: Subsonic <1 | Supersonic 1–5 | Hypersonic >5
  • Pressure at constant temp has NO effect on speed of sound
  • Moisture ↑ → Speed of sound ↑
📋 Formula Quick Reference
T = 2π/ωTime Period (SHM)
T = 2π√(l/g)Simple Pendulum
n = 1/T  |  λ = v/nFrequency & Wavelength
v = nλWave Speed
v ∝ √TSound Speed vs Temperature
Mach = v_body / v_soundMach Number
⚠️ Most Common Exam Traps
  • T of pendulum does NOT depend on mass
  • Going up AND down both increase pendulum T
  • Sound = Longitudinal; Light = Transverse
  • Frequency does NOT change when sound changes medium
  • Pressure change has NO effect on speed of sound (at const. temp)
  • γ-Ray named by Rutherford, discovered by Villard
  • SONAR uses ultrasonic waves (not sound)
  • Echo min distance = 17.2 m (not 17 or 18)
  • Hypersonic = Mach > 5 (not Mach > 3)
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