By the end of this chapter you'll be able to…

  • 1Explain that sound is a longitudinal mechanical wave
  • 2Apply the echo/SONAR formula d = vt/2
  • 3Distinguish echo from reverberation
  • 4State the audible range and define ultrasonic/infrasonic
  • 5List applications of ultrasound and reflection of sound
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Why this chapter matters
Acoustics explains how sound travels and reflects, and how ultrasound and SONAR are used. The echo/SONAR formula gives easy, reliable numerical marks in the TN SSLC Science exam.

Before you start — revise these

A 5-minute refresher here will save you 30 minutes of confusion below.

Acoustics — Class 10 Science (Samacheer Kalvi)

TN State Board (Samacheer Kalvi) Class 10 Science, Physics — Chapter 5. The science of sound — how it travels, reflects, and is used.


1. About this chapter

This chapter studies sound waves, their reflection (echo, reverberation), useful applications like SONAR, the audible range, and ultrasonic sound with its many uses.

2. Nature of sound

  • Sound is a longitudinal mechanical wave — it needs a material medium (cannot travel through vacuum).
  • It travels as compressions and rarefactions.
  • Speed of sound is greatest in solids, less in liquids, least in gases (≈ 340 m s⁻¹ in air).

3. Reflection of sound

  • Echo: a sound heard again after reflection. To hear a distinct echo the reflecting surface must be at least 17 m away (so the gap ≥ 0.1 s). Echo formula: 2d = v × t → distance d = v t / 2.
  • Reverberation: persistence of sound by repeated reflections in a hall; reduced using sound-absorbing materials.
  • Applications of reflection: SONAR, stethoscope, megaphone, sound boards in auditoriums.

4. SONAR and the audible range

  • SONAR (Sound Navigation and Ranging) sends ultrasonic pulses and times the echo to find depth/distance: d = v t / 2.
  • Audible range for humans: 20 Hz to 20,000 Hz.
    • Below 20 Hz → infrasonic; above 20 kHz → ultrasonic.
  • Uses of ultrasound: SONAR, cleaning fine machinery, detecting flaws in metals, and medical imaging (ultrasound scan).

5. Worked examples

Example 1. An echo returns in 2 s. If the speed of sound is 340 m s⁻¹, how far is the wall? d = v t / 2 = 340 × 2 / 2 = 340 m.

Example 2. A SONAR pulse returns from the seabed in 4 s; speed of sound in water = 1500 m s⁻¹. Find the depth. d = v t / 2 = 1500 × 4 / 2 = 3000 m.

Example 3. Why can't sound travel through vacuum? Because sound is a mechanical wave that needs particles of a medium to transfer compressions and rarefactions.

6. Common mistakes

  • Mistake: Forgetting the factor 2 in the echo formula. Fix: Sound travels to the surface and back: 2d = vt, so d = vt/2.
  • Mistake: Calling sound a transverse wave. Fix: Sound is a longitudinal wave.
  • Mistake: Confusing ultrasonic and infrasonic. Fix: Ultrasonic > 20 kHz; infrasonic < 20 Hz.

7. Practice (book-back style)

  1. Why is sound a mechanical wave?
  2. State the conditions to hear a distinct echo.
  3. Write the echo/SONAR distance formula.
  4. A sound reflects from a cliff in 3 s (v = 340 m s⁻¹). Find the distance.
  5. Define the audible range and name two uses of ultrasound.

8. Answer key

  1. It needs a material medium to propagate (via compressions and rarefactions).
  2. Reflecting surface at least 17 m away; the echo must arrive at least 0.1 s after the original sound.
  3. d = v t / 2 (since 2d = vt).
  4. d = vt/2 = 340 × 3 / 2 = 510 m.
  5. 20 Hz to 20,000 Hz; uses — SONAR, ultrasound scanning, cleaning, flaw detection (any two).

9. Quick revision

  • Physics Ch 5 · sound, reflection, echo, SONAR, ultrasound.
  • Sound = longitudinal wave, needs a medium; ≈ 340 m s⁻¹ in air.
  • Echo/SONAR: d = v t / 2 (factor 2 for to-and-fro).
  • Distinct echo: surface ≥ 17 m, gap ≥ 0.1 s.
  • Audible 20 Hz–20 kHz; ultrasonic > 20 kHz; infrasonic < 20 Hz.

Key formulas & results

Everything you need to memorise, in one card. Screenshot this for revision.

Echo / SONAR distance
d = v t / 2
2d = vt (sound goes and returns).
Wave speed
v = f λ
Speed = frequency × wavelength.
Audible range
20 Hz – 20,000 Hz
Below = infrasonic; above = ultrasonic.
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Common mistakes & fixes

These are the exact errors that cost students marks in board exams. Read them once, save yourself the trouble.

WATCH OUT
Forgetting the factor 2 in the echo formula
Sound travels to the surface and back: 2d = vt, so d = vt/2.
WATCH OUT
Calling sound a transverse wave
Sound is a longitudinal wave (compressions and rarefactions).
WATCH OUT
Confusing ultrasonic and infrasonic
Ultrasonic > 20 kHz; infrasonic < 20 Hz.

Practice problems

Try each one yourself before tapping "Show solution". Active recall > rereading.

Q1EASY· Concept
Why can't sound travel through vacuum?
Show solution
Sound is a mechanical wave that needs a material medium to transfer compressions and rarefactions.
Q2EASY· Numerical
An echo returns in 2 s (v = 340 m s⁻¹). How far is the wall?
Show solution
d = vt/2 = 340 × 2 / 2 = 340 m.
Q3MEDIUM· Numerical
A SONAR pulse returns from the seabed in 4 s (v = 1500 m s⁻¹). Find the depth.
Show solution
d = vt/2 = 1500 × 4 / 2 = 3000 m.
Q4EASY· Concept
State the conditions to hear a distinct echo.
Show solution
The reflecting surface must be at least 17 m away and the echo must arrive at least 0.1 s after the original sound.
Q5MEDIUM· Numerical
A sound reflects from a cliff in 3 s (v = 340 m s⁻¹). Find the distance to the cliff.
Show solution
d = vt/2 = 340 × 3 / 2 = 510 m.
Q6MEDIUM· Concept
Define the audible range and give two uses of ultrasound.
Show solution
20 Hz to 20,000 Hz. Uses: SONAR, ultrasound (medical) scanning, cleaning machinery, detecting flaws in metals — any two.

5-minute revision

The whole chapter, distilled. Read this the night before the exam.

  • Physics Chapter 5 of Samacheer Kalvi Class 10 Science.
  • Sound is a longitudinal mechanical wave; needs a medium.
  • Echo/SONAR: d = vt/2 (factor 2 for to-and-fro).
  • Distinct echo: surface ≥ 17 m, gap ≥ 0.1 s.
  • Audible 20 Hz–20 kHz; ultrasonic > 20 kHz; infrasonic < 20 Hz.
  • Ultrasound: SONAR, scanning, cleaning, flaw detection.

Tamil Nadu (TNBSE) marks blueprint

Where the marks come from in this chapter — so you can plan your prep.

Typical chapter weightage: 4-7 marks across MCQ, short answer and numerical questions

Question typeMarks eachTypical countWhat it tests
MCQ11-2Nature of sound, ranges
Short Answer2-31-2Echo, reverberation, ultrasound uses
Numerical21Echo / SONAR distance
Prep strategy
  • Memorise d = vt/2 and apply the factor 2
  • Learn echo conditions and audible range
  • List ultrasound and reflection applications
  • Distinguish echo from reverberation

Where this shows up in the real world

This chapter isn't just an exam topic — it lives in the world around you.

SONAR

Ships measure ocean depth and detect objects underwater.

Medical ultrasound

Ultrasound scans image internal organs safely.

Auditorium design

Sound boards and absorbers control reverberation.

Exam strategy

Battle-tested tips from teachers and toppers for this chapter.

  1. Always include the factor 2 in echo/SONAR sums
  2. State the unit and keep speed in m s⁻¹
  3. Give precise echo conditions (17 m, 0.1 s)
  4. List two clear applications when asked

Going beyond the textbook

For olympiad aspirants and curious learners — topics that build on this chapter.

  • Calculate the minimum distance for an echo from the 0.1 s rule.
  • Explain why solids transmit sound faster than gases.

Where else this chapter is tested

CBSE board isn't the only one — other exams test this chapter too.

TN SSLC Class 10 Public ExamHigh
Foundation / NTSE PhysicsMedium
School unit testsHigh

Questions students ask

The real ones — pulled from the Q&A community and tutor sessions.

An echo is a single distinct reflected sound heard after a clear gap; reverberation is the persistence of sound due to many repeated reflections, as in a large hall.

It sends an ultrasonic pulse to the seabed and times the returning echo. Depth = v × t / 2, where v is the speed of sound in water and t the total time.
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Last reviewed on 2 June 2026. Written and reviewed by subject-matter experts — read about our process.
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