Sound waves of frequency 660 ,,Hz fall normally on a perfectly reflecting wall. The shortest distance from the wall at which the air particle has

Q: Sound waves of frequency $660 \,\,Hz$ fall normally on a perfectly reflecting wall. The shortest distance from the wall at which the air particle has maximum amplitude of vibration is .... $m$ (velocity of sound in air is $330 \,\,m/s$)

a Frequency of sound waves $\nu=660 \mathrm{Hz}$ and velocity $v=330 \mathrm{m} / \mathrm{s}$ Now wavelength of the sound waves $\lambda=\frac{v}{\nu}=\frac{330}{660}=0.5 \mathrm{m}$ Stationary waves will be formed due to the interference between the incident and the reflected wave and the displacement node is formed at the reflecting surface. Thus the shortest distance between the wall (node) and the point where the air particles have maximum amplitude of vibration (antinode) $d=\frac{\lambda}{4}=\frac{0.5}{4}=0.125 \mathrm{m}$

SECTION - A [PHYSICS - MCQ]

GSEB - English Medium

Sound waves of frequency $660 \,\,Hz$ fall normally on a perfectly reflecting wall. The shortest distance from the wall at which the air particle has maximum amplitude of vibration is .... $m$ (velocity of sound in air is $330 \,\,m/s$)

A$0.125$
B$0.5$
C$0.25$
D$2$

Diffcult

STD 11 Science
NEET
STD 11 - 14. waves and sound
Physics

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