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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 ,
A 1 cm long string vibrates with fundamental frequency of 256 Hz . If the length is reduced to 1/4 cm keeping the tension unaltered, the new fundamental frequency will be (in Hz)
01
Nov
A 1 cm long string vibrates with fundamental frequency of 256 Hz . If the length is reduced to 1/4 cm keeping the tension unaltered, the new fundamental frequency will be (in Hz) A 1 cm long string vibrates with fundamental frequency of 256 Hz . If the length is reduced to 1/4 cm keeping [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A 1 cm long string vibrates with fundamental frequency of 256 Hz . If the length is reduced to 1/4 cm keeping the tension unaltered , the new fundamental frequency will be (in Hz) ,
Consider the three waves z1 z2 and z3 as z1 = A sin (kx – ωt) z2 = A sin (kx + ωt) z3 = A sin (ky – ωt) Which of the following represents a standing wave?
01
Nov
Consider the three waves z1 z2 and z3 as z1 = A sin (kx – ωt) z2 = A sin (kx + ωt) z3 = A sin (ky – ωt) Which of the following represents a standing wave? Consider the three waves z1 z2 and z3 as z1 = A sin (kx – ωt) z2 [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: Consider the three waves z1 z2 and z3 as z1 = A sin (kx – ωt) z2 = A sin (kx + ωt) z3 = A sin (ky – ωt) Which of the following represents a standing wave? ,
Stationary waves of frequency 300Hz are formed in a medium in which the velocity of sound is 1200 metre/sec. The distance between a node and the neighbouring antinode is
01
Nov
Stationary waves of frequency 300Hz are formed in a medium in which the velocity of sound is 1200 metre/sec. The distance between a node and the neighbouring antinode is Stationary waves of frequency 300Hz are formed in a medium in which the velocity of sound is 1200 metre/sec. The distance between a node and the [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: Stationary waves of frequency 300Hz are formed in a medium in which the velocity of sound is 1200 metre/sec. The distance between a node and the neighbouring antinode is ,
First overtone frequency of a closed organ pipe is equal to the first overtone frequency of an open organ pipe. Further nth harmonic of closed organ pipe is also equal to the nth harmonic of open pipe, where n and m are
01
Nov
First overtone frequency of a closed organ pipe is equal to the first overtone frequency of an open organ pipe. Further nth harmonic of closed organ pipe is also equal to the nth harmonic of open pipe, where n and m are First overtone frequency of a closed organ pipe is equal to the first [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: First overtone frequency of a closed organ pipe is equal to the first overtone frequency of an open organ pipe. Further nth harmonic of closed organ pipe is also equal to the nth harmonic of open pipe , where n and m are ,
Two identical strings are stretched at tensions TA and TB. A tuning fork is used to set them in vibration. A vibrates in its fundamental mode and B in its second harmonic mode then
01
Nov
Two identical strings are stretched at tensions TA and TB. A tuning fork is used to set them in vibration. A vibrates in its fundamental mode and B in its second harmonic mode then Two identical strings are stretched at tensions TA and TB. A tuning fork is used to set them in vibration. A [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: Two identical strings are stretched at tensions TA and TB. A tuning fork is used to set them in vibration. A vibrates in its fundamental mode and B in its second harmonic mode then ,
A tuning fork of frequency 340 Hz is sounded above a cylindrical tube 1m long. water is slowly poured into the tube. If the speed of sound is 340m/s at what levels of water in the tube will the sound of the tuning fork be appreciably intensified ?
01
Nov
A tuning fork of frequency 340 Hz is sounded above a cylindrical tube 1m long. water is slowly poured into the tube. If the speed of sound is 340m/s at what levels of water in the tube will the sound of the tuning fork be appreciably intensified ? how many nodes and antinodes are set [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: how many nodes and antinodes are set up in it ? , If you set up the seventh harmonic on a string fixed at both ends ,