Volume 1

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The extension in a string, obeying Hooke’s law, is x. The speed of sound in the stretched string is v. If the extension in the string is increase to 1.5 x, the speed of transverse waves in it will be:
01
Nov
The extension in a string, obeying Hooke’s law, is x. The speed of sound in the stretched string is v. If the extension in the string is increase to 1.5 x, the speed of transverse waves in it will be: is x. The speed of sound in the stretched string is v. If the extension [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: is x. The speed of sound in the stretched string is v. If the extension in the string is increase to 1.5 x , obeying Hooke's law , The extension in a string , the speed of transverse waves in it will be: ,
The velocity of sound through a diatomic gaseous medium of molecular weight M at 0 degree C
01
Nov
The velocity of sound through a diatomic gaseous medium of molecular weight M at 0 degree C The velocity of sound through a diatomic gaseous medium of molecular weight M at 0 degree C November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: The velocity of sound through a diatomic gaseous medium of molecular weight M at 0 degree C ,
If the temperature of the medium drops by 1 %, the velocity of sound in that medium
01
Nov
If the temperature of the medium drops by 1 %, the velocity of sound in that medium If the temperature of the medium drops by 1 % the velocity of sound in that medium November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: If the temperature of the medium drops by 1 % , the velocity of sound in that medium ,
Under the same conditions of pressure and temperature, the velocity of sound in oxygen and hydrogen gases are vo and vH , then
01
Nov
Under the same conditions of pressure and temperature, the velocity of sound in oxygen and hydrogen gases are vo and vH , then the velocity of sound in oxygen and hydrogen gases are vo and vH then Under the same conditions of pressure and temperature November 1, 2020 Category: Arihant Physics by D.C Pandey , [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: the velocity of sound in oxygen and hydrogen gases are vo and vH , then , Under the same conditions of pressure and temperature ,
Intensity level of intensity l is 30 dB. The ratio I/I0 is (where I0 is the threshold of hearing)
01
Nov
Intensity level of intensity l is 30 dB. The ratio I/I0 is (where I0 is the threshold of hearing) Intensity level of intensity l is 30 dB. The ratio I/I0 is (where I0 is the threshold of hearing) November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: Intensity level of intensity l is 30 dB. The ratio I/I0 is (where I0 is the threshold of hearing) ,
If frequency of sound produced by a siren increases from 400 to 1200 Hz while the wave amplitude remains constant, the ratio of intensity of the 1200 Hz to that of 400 Hz wave will
01
Nov
If frequency of sound produced by a siren increases from 400 to 1200 Hz while the wave amplitude remains constant, the ratio of intensity of the 1200 Hz to that of 400 Hz wave will If frequency of sound produced by a siren increases from 400 to 1200 Hz while the wave amplitude remains constant [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: If frequency of sound produced by a siren increases from 400 to 1200 Hz while the wave amplitude remains constant , the ratio of intensity of the 1200 Hz to that of 400 Hz wave will ,
Two strings A and B have lengths lA ​and lB ​ carry masses MA and MB at their lower ends the upper ends being supported by rigid supports. If nA and nB are the fundamental frequencies of their vibration, then nA : nB is
01
Nov
Two strings A and B have lengths lA ​and lB ​ carry masses MA and MB at their lower ends the upper ends being supported by rigid supports. If nA and nB are the fundamental frequencies of their vibration, then nA : nB is A stationary wave set up on a string have the equation [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A stationary wave set up on a string have the equation y = (2mm) sin [(6.25 m^-1) x cos (ωt)]. This stationary wave is created by two identical waves , of amplitude A each moving in opposite directions along the string. Then ,
A stationary wave set up on a string have the equation y = (2mm) sin [(6.25 m^-1) x cos (ωt)]. This stationary wave is created by two identical waves, of amplitude A each moving in opposite directions along the string. Then
01
Nov
A stationary wave set up on a string have the equation y = (2mm) sin [(6.25 m^-1) x cos (ωt)]. This stationary wave is created by two identical waves, of amplitude A each moving in opposite directions along the string. Then A stationary wave set up on a string have the equation y = (2mm) [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A stationary wave set up on a string have the equation y = (2mm) sin [(6.25 m^-1) x cos (ωt)]. This stationary wave is created by two identical waves , of amplitude A each moving in opposite directions along the string. Then ,
In order to double the frequency of the fundamental note emitted by a stretched string, the length is reduced to 3/4th of the original length and the tension is changed. The factor by which the tension is to be changed is
01
Nov
In order to double the frequency of the fundamental note emitted by a stretched string, the length is reduced to 3/4th of the original length and the tension is changed. The factor by which the tension is to be changed is In order to double the frequency of the fundamental note emitted by a stretched [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: In order to double the frequency of the fundamental note emitted by a stretched string , the length is reduced to 3/4th of the original length and the tension is changed. The factor by which the tension is to be changed is ,
If you set up the ninth harmonic on a string fixed at both ends, its frequency compared to the seventh harmonic is
01
Nov
If you set up the ninth harmonic on a string fixed at both ends, its frequency compared to the seventh harmonic is If you set up the ninth harmonic on a string fixed at both ends its frequency compared to the seventh harmonic is November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: If you set up the ninth harmonic on a string fixed at both ends , its frequency compared to the seventh harmonic is ,