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    SOUND

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    Hitesh kalra
    (i) Transverse waves have particle motion perpendicular to the direction of wave motion, while longitudinal waves have particle motion parallel to the direction of wave motion. (ii) Sound needs a medium to propagate through compressions and rarefactions of particles. The speed of sound depends on the properties of the medium. (iii) Characteristics of sound waves include wavelength, time period, frequency, amplitude, pitch, volume, intensity, note, tone, quality, and speed of sound in different media.

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    SOUND

    Uploaded by

    Hitesh kalra
    36 views4 pages
    (i) Transverse waves have particle motion perpendicular to the direction of wave motion, while longitudinal waves have particle motion parallel to the direction of wave motion. (ii) Sound needs a medium to propagate through compressions and rarefactions of particles. The speed of sound depends on the properties of the medium. (iii) Characteristics of sound waves include wavelength, time period, frequency, amplitude, pitch, volume, intensity, note, tone, quality, and speed of sound in different media.

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    (i) Transverse waves have particle motion perpendicular to the direction of wave motion, while longitudinal waves have particle motion parallel to the direction of wave motion. (ii) Sound needs a medium to propagate through compressions and rarefactions of particles. The speed of sound depends on the properties of the medium. (iii) Characteristics of sound waves include wavelength, time period, frequency, amplitude, pitch, volume, intensity, note, tone, quality, and speed of sound in different media.

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    © All Rights Reserved
    Download as DOCX, PDF, TXT or read online from Scribd
    Download as docx, pdf, or txt
    36 views4 pages

    SOUND

    Uploaded by

    Hitesh kalra
    (i) Transverse waves have particle motion perpendicular to the direction of wave motion, while longitudinal waves have particle motion parallel to the direction of wave motion. (ii) Sound needs a medium to propagate through compressions and rarefactions of particles. The speed of sound depends on the properties of the medium. (iii) Characteristics of sound waves include wavelength, time period, frequency, amplitude, pitch, volume, intensity, note, tone, quality, and speed of sound in different media.

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    © All Rights Reserved
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    Download as docx, pdf, or txt
    of 4

    Particle motion of mechanical waves

    (i) Transverse Waves


    Particle motion is perpendicular to the direction of wave motion.  This type of wave is a mechanical wave.
    E.g: Light and Mexican wave in a stadium.
    (ii) Longitudinal waves
    Particles travel parallel to the direction of wave motion, by means of successive compressions or elongations. This is
    also a mechanical wave.
    E. g: Sound waves in air.

    Sound Properties
    Introduction to sound waves
    Sound needs a medium to propagate. The matter or material through which sound propagates is called a medium.
    When particles vibrate about their mean positions, it pushes a region of compressed air, creating a region of high
    pressure, followed by a region of low pressure as the particle retreats to its mean position. The sound wave
    propagates by compressions and rarefactions of particles in a medium. Sound propagation can be visualised as the
    propagation of pressure variations in the medium.

    Characteristics of Sound Waves


    Wavelength
    The distance between two successive crests or troughs (or) successive compressions and rarefactions is called as
    wavelength (λ).  The SI unit of wavelength is metre (m).

    Time period
    Time taken by two consecutive compressions or rarefactions to cross a fixed point is called a Time period (T). The SI
    unit of time in seconds (s).

    Frequency
    The number of compressions or rarefactions per unit time is called frequency (
    The SI unit of frequency is Hertz. The  SI unit is Hertz (s−1)
    �=1�
    Speed (v), wavelength (λ) and frequency (

    Amplitude
    The magnitude of disturbance in a medium on either side of the mean value is called an amplitude (A).
    As shown in the figure below, the unit of amplitude will be the density or pressure. Distance between mean position
    and crest (maximum displacement).

                     
    Amplitude (A)

    Pitch
    The number of compressions or rarefactions per unit time. Directly proportional to frequency.
    Representation of low and high
    pitch

    Volume
    Volume or loudness of a sound depends on the amplitude. The force with which an object is made to vibrate gives
    the loudness.

    Higher force → higher amplitude → louder sound


    The amount of sound energy flowing per unit time through a unit area is called the intensity of sound.

                 The
    Intensity of Sound

    Note and Tone


    A sound of a single frequency is called a tone. A sound produced with a mixture of several frequencies is
    called a note.

    Quality of sound
    The richness or timber of sound is called the quality. Sound with the same pitch and loudness can be distinguished
    based on the quality. Music is pleasant to the ears while noise is not. But they both can have the same loudness and
    pitch.
    Speed of sound
    Sound travels through different media with different speeds. Speed of sound depends on the properties of the
    medium: pressure, density and temperature
    Speed of sound: Solids > Liquids > Gases
    Speed of sound in air = 331 m/s at 00C and 344 m/s at 22∘ C
    When a source emits sound with a speed greater than the speed of sound in air, it creates a sonic boom which
    produces shockwaves with lots of energy. They produce a very loud noise which is enough to shatter glass and
    damage buildings.

    Reflection of  Sound Waves


    Like light, sound also follows laws of reflection, it bounces off the surface of solid and liquid.

    Echo
    The phenomenon where a sound produced is heard again due to reflection is called an echo.
    E.g: Clapping or shouting near a tall building or a mountain.
    To hear distinct echo sound, the time interval between original and reflected sound must be at least 0.1s. As sound
    persists in our brain for about 0.1s. Minimum distance for obstruction or reflective surface to hear an echo should be
    17.2 m. Multiple echoes can be heard due to multiple reflections.

    Sonar and Radar


    SONAR – Sound Navigation And Ranging.
    It is a technique that uses sound or ultrasonic waves to measure distance. The human range of hearing is 20Hz-
    20kHz.
    What are Ultrasonic sounds?
    Ultrasonic sounds are high-frequency sound having a frequency greater than 20kHz (inaudible range).
    Applications of Ultrasound
    (i) Scanning images of human organs
    (ii) Detecting cracks in metal blocks
    (iii) Cleaning parts that are hard to reach
    (iv) Navigating, communicating or detecting objects on or under the surface of the water (SONAR).
    Sonar consists of a transmitter and detector mounted on a boat or ship. The transmitter sends ultrasonic sound
    waves to the seabed which gets reflected back and picked up by the detector. Knowing the speed of sound in water,
    distance can be measured using:   2d=v×t. This method is called echo-location or echo ranging.
    To know more about Uses of Radar, visit here.

    Reverberation
    Persistence of sound because of multiple reflections is called reverberation. Examples: Auditorium and a big hall.
    Excessive reverberation is undesirable and to reduce this, halls and auditoriums have sound-absorbing materials on
    the walls and roofs.  E.g: Fibreboard and rough plaster.
    To know more about Reverberation, visit here.

    Doppler’s effect
    If either the source of sound or observer is moving, then there will be a change in frequency and wavelength for the
    observer. The frequency will be higher when the observer moves towards the source and it decreases when the
    observer moves away from the source.
    Example: If one is standing on a street corner and an ambulance approaches with its siren blaring, the sound of the
    siren steadily gains in pitch as it comes closer and then, as it passes, the pitch suddenly lowers.
    To know more about Doppler’s Effect, visit here.

    Human Ear
    The ear is a sensitive organ of the human body. It is mainly involved with detecting, transmitting and transducing
    sound and maintaining a sense of balance is another important function of the human ear. Human ear includes:

     The outer ear or the visible part of the ear is called the pinna.
     Pinna collects sound from the surroundings.
     Sound passes through a tube called an auditory canal.
     Eardrum (tympanic membrane) vibrates in response to incident sound waves.
     Vibrations are amplified and transmitted further by three bones hammer, anvil and stirrup in the middle ear
    to the inner ear.
     In the inner ear, cochlea converts pressure signals into electrical signals.
     Electrical signals are transmitted by the auditory nerve to the brain for interpretation.

                  Human Ear

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