Chapter 16 – Waves and Acoustics

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A closed organ pipe and an open organ pipe have their first overtones identical in frequency. Their lengths are in the ratio
29
Oct
A closed organ pipe and an open organ pipe have their first overtones identical in frequency. Their lengths are in the ratio A closed organ pipe and an open organ pipe have their first overtones identical in frequency. Their lengths are in the ratio October 29, 2020 Category: Cengage JEE Mains Physics by B.M Sharma [...]
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Tags: A closed organ pipe and an open organ pipe have their first overtones identical in frequency. Their lengths are in the ratio ,
A sonometer wire of length l vibrates in fundamental mode when excited by a tuning fork of frequency 416 Hz. If the length is double keeping other things same the string will
29
Oct
A sonometer wire of length l vibrates in fundamental mode when excited by a tuning fork of frequency 416 Hz. If the length is double keeping other things same the string will A sonometer wire of length l vibrates in fundamental mode when excited by a tuning fork of frequency 416 Hz. If the length [...]
Posted in: Cengage JEE Mains Physics by B.M Sharma , Chapter 16 - Waves and Acoustics ,
Tags: A sonometer wire of length l vibrates in fundamental mode when excited by a tuning fork of frequency 416 Hz. If the length is double keeping other things same the string will ,
A sound wave of wavelength λ travels towards the right horizontally with a velocity V. It strikes and reflects from a vertical plane surface, travelling at a speed v towards the left. The number of positive crests striking in a time interval of 3 s on the wall is
29
Oct
A sound wave of wavelength λ travels towards the right horizontally with a velocity V. It strikes and reflects from a vertical plane surface, travelling at a speed v towards the left. The number of positive crests striking in a time interval of 3 s on the wall is A sound wave of wavelength λ [...]
Posted in: Cengage JEE Mains Physics by B.M Sharma , Chapter 16 - Waves and Acoustics ,
Tags: A sound wave of wavelength λ travels towards the right horizontally with a velocity V. It strikes and reflects from a vertical plane surface , travelling at a speed v towards the left. The number of positive crests striking in a time interval of 3 s on the wall is ,
The equation of a stationary wave is y=0.8cos ( 20/πx )sin200πt where x is in cm and t is in seconds. The separation between consecutive nodes is
29
Oct
The equation of a stationary wave is y=0.8cos ( 20/πx )sin200πt where x is in cm and t is in seconds. The separation between consecutive nodes is The equation of a stationary wave is y=0.8cos ( 20/πx )sin200πt where x is in cm and t is in seconds. The separation between consecutive nodes is October [...]
Posted in: Cengage JEE Mains Physics by B.M Sharma , Chapter 16 - Waves and Acoustics ,
Tags: The equation of a stationary wave is y=0.8cos ( 20/πx )sin200πt where x is in cm and t is in seconds. The separation between consecutive nodes is ,
On sounding fork A with another tuning fork B of frequency 384 Hz,6beats are produced per second .After loading the prongs of A with wax and then sounding it again with B,4 beats are produced per second. What is the frequency of the tuning fork A.
29
Oct
On sounding fork A with another tuning fork B of frequency 384 Hz,6beats are produced per second .After loading the prongs of A with wax and then sounding it again with B,4 beats are produced per second. What is the frequency of the tuning fork A. 4 beats are produced per second. What is the [...]
Posted in: Cengage JEE Mains Physics by B.M Sharma , Chapter 16 - Waves and Acoustics ,
Tags: 4 beats are produced per second. What is the frequency of the tuning fork A. , 6beats are produced per second .After loading the prongs of A with wax and then sounding it again with B , On sounding fork A with another tuning fork B of frequency 384 Hz ,
The equation of displacement of two waves are given as y1=10sin(3πt + π/3),y2 = 5[sin3πt + 3–√cos3πt] Then what is the ratio of their amplitudes
29
Oct
The equation of displacement of two waves are given as y1=10sin(3πt + π/3),y2 = 5[sin3πt + 3–√cos3πt] Then what is the ratio of their amplitudes The equation of displacement of two waves are given as y1=10sin(3πt + π/3) y2 = 5[sin3πt + 3–√cos3πt] Then what is the ratio of their amplitudes October 29, 2020 Category: [...]
Posted in: Cengage JEE Mains Physics by B.M Sharma , Chapter 16 - Waves and Acoustics ,
Tags: The equation of displacement of two waves are given as y1=10sin(3πt + π/3) , y2 = 5[sin3πt + 3–√cos3πt] Then what is the ratio of their amplitudes ,
A source of sound of frequency f1 is placed on the ground. A detector placed at a height is released from rest on this source. The observed frequency f(Hz) is plotted against time t(sec) . The speed of sound in air is 300m/s. Find f1 (g=10m/s^2).
29
Oct
A source of sound of frequency f1 is placed on the ground. A detector placed at a height is released from rest on this source. The observed frequency f(Hz) is plotted against time t(sec) . The speed of sound in air is 300m/s. Find f1 (g=10m/s^2). A stationary observer receives a sound of frequency = [...]
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Tags: A stationary observer receives a sound of frequency = 2000Hz. The variation of apparent frequency and time is shown in figure. Find the speed of source , if velocity of sound is = 300m/s ,
A stationary observer receives a sound of frequency = 2000Hz. The variation of apparent frequency and time is shown in figure. Find the speed of source, if velocity of sound is = 300m/s
29
Oct
A stationary observer receives a sound of frequency = 2000Hz. The variation of apparent frequency and time is shown in figure. Find the speed of source, if velocity of sound is = 300m/s A stationary observer receives a sound of frequency = 2000Hz. The variation of apparent frequency and time is shown in figure. Find [...]
Posted in: Cengage JEE Mains Physics by B.M Sharma , Chapter 16 - Waves and Acoustics ,
Tags: A stationary observer receives a sound of frequency = 2000Hz. The variation of apparent frequency and time is shown in figure. Find the speed of source , if velocity of sound is = 300m/s ,
Source and observer start moving simultaneously along x and y-axis respectively. The speed of source is twice the speed of observer, V0 . If the ratio of observed frequency to frequency of the source is 0.75, find the velocity of sound
29
Oct
Source and observer start moving simultaneously along x and y-axis respectively. The speed of source is twice the speed of observer, V0 . If the ratio of observed frequency to frequency of the source is 0.75, find the velocity of sound find the velocity of sound Source and observer start moving simultaneously along x and [...]
Posted in: Cengage JEE Mains Physics by B.M Sharma , Chapter 16 - Waves and Acoustics ,
Tags: find the velocity of sound , Source and observer start moving simultaneously along x and y-axis respectively. The speed of source is twice the speed of observer , V0 . If the ratio of observed frequency to frequency of the source is 0.75 ,
Length of a string of density ρ and Young’s modulus Y under tension is increased by 1/n times of its original length If the velocity of transverse and longitudinal vibration of the string is same, find the value of such velocity.
29
Oct
Length of a string of density ρ and Young’s modulus Y under tension is increased by 1/n times of its original length If the velocity of transverse and longitudinal vibration of the string is same, find the value of such velocity. find the value of such velocity. Length of a string of density ρ and [...]
Posted in: Cengage JEE Mains Physics by B.M Sharma , Chapter 16 - Waves and Acoustics ,
Tags: find the value of such velocity. , Length of a string of density ρ and Young's modulus Y under tension is increased by 1/n times of its original length If the velocity of transverse and longitudinal vibration of the string is same ,