Arihant Physics by D.C Pandey

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A standing wave is represented by y = A sin (100t) cos (0.01x), where t is in second and is in metre, Then the velocity the constituent wave is
01
Nov
A standing wave is represented by y = A sin (100t) cos (0.01x), where t is in second and is in metre, Then the velocity the constituent wave is A standing wave is represented by y = A sin (100t) cos (0.01x) Then the velocity the constituent wave is where t is in second and [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A standing wave is represented by y = A sin (100t) cos (0.01x) , Then the velocity the constituent wave is , where t is in second and is in metre ,
A string is tied on a sonometer, second end is hanging downward through a pulley with tension T. The velocity of the transverse wave produced is proportional to
01
Nov
A string is tied on a sonometer, second end is hanging downward through a pulley with tension T. The velocity of the transverse wave produced is proportional to A string is tied on a sonometer second end is hanging downward through a pulley with tension T. The velocity of the transverse wave produced is proportional [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A string is tied on a sonometer , second end is hanging downward through a pulley with tension T. The velocity of the transverse wave produced is proportional to ,
A string of length 1m has a mass per unit length 0.1 g/cm. What would be the fundamental frequency of vibration of this string under the tension of 400 N ?
01
Nov
A string of length 1m has a mass per unit length 0.1 g/cm. What would be the fundamental frequency of vibration of this string under the tension of 400 N ? A string of length 1m has a mass per unit length 0.1 g/cm. What would be the fundamental frequency of vibration of this string [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A string of length 1m has a mass per unit length 0.1 g/cm. What would be the fundamental frequency of vibration of this string under the tension of 400 N ? ,
A tube of length 1.05 m is closed at one end. If the velocity of sound in air be 336 m/s, then the fundamental and the next higher overtone in Hz are
01
Nov
A tube of length 1.05 m is closed at one end. If the velocity of sound in air be 336 m/s, then the fundamental and the next higher overtone in Hz are A tube of length 1.05 m is closed at one end. If the velocity of sound in air be 336 m/s then the [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A tube of length 1.05 m is closed at one end. If the velocity of sound in air be 336 m/s , then the fundamental and the next higher overtone in Hz are ,
In a travelling wave, y=01 sin π[x − 330 t + 2/3]. The phase difference between x1 = 3 and x2 = 3.5 m is
01
Nov
In a travelling wave, y=01 sin π[x − 330 t + 2/3]. The phase difference between x1 = 3 and x2 = 3.5 m is In a travelling wave y=01 sin π[x − 330 t + 2/3]. The phase difference between x1 = 3 and x2 = 3.5 m is November 1, 2020 Category: Arihant [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: In a travelling wave , y=01 sin π[x − 330 t + 2/3]. The phase difference between x1 = 3 and x2 = 3.5 m is ,
The equation of progressive wave is given by y = a sin π( 2/t − 4/x ), where ‘t’ is in seconds and x is in metre. The distance through which the wave moves in 8 seconds is in (metre)
01
Nov
The equation of progressive wave is given by y = a sin π( 2/t − 4/x ), where ‘t’ is in seconds and x is in metre. The distance through which the wave moves in 8 seconds is in (metre) The equation of progressive wave is given by y = a sin π( 2/t − [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: The equation of progressive wave is given by y = a sin π( 2/t − 4/x ) , where 't' is in seconds and x is in metre. The distance through which the wave moves in 8 seconds is in (metre) ,
A transverse sinusoidal wave of amplitude a, wavelength λ and frequency n is travelling on a stretched string. The maximum speed of particle is 1 /10th, the speed of propagation of the wave. If a=10^−3m and v=10m/s, then λ and n are given by
01
Nov
A transverse sinusoidal wave of amplitude a, wavelength λ and frequency n is travelling on a stretched string. The maximum speed of particle is 1 /10th, the speed of propagation of the wave. If a=10^−3m and v=10m/s, then λ and n are given by A transverse sinusoidal wave of amplitude a the speed of propagation [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A transverse sinusoidal wave of amplitude a , the speed of propagation of the wave. If a=10^−3m and v=10m/s , then λ and n are given by , wavelength λ and frequency n is travelling on a stretched string. The maximum speed of particle is 1 /10th ,
The equation of a progressive wave is y = 8 sin[π(t/10 − x/4) + π/3]. The wavelength of the wave is
01
Nov
The equation of a progressive wave is y = 8 sin[π(t/10 − x/4) + π/3]. The wavelength of the wave is The equation of a progressive wave is y = 8 sin[π(t/10 − x/4) + π/3]. The wavelength of the wave is November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter 16 - [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: The equation of a progressive wave is y = 8 sin[π(t/10 − x/4) + π/3]. The wavelength of the wave is ,
Equation of a progressive wave is given by y = 0.2 cos π(0.04t + 0.02x − π/6). The distance is expressed in cm and time in second. What will be the minimum distance between two particles having the phase difference of π/2 ?
01
Nov
Equation of a progressive wave is given by y = 0.2 cos π(0.04t + 0.02x − π/6). The distance is expressed in cm and time in second. What will be the minimum distance between two particles having the phase difference of π/2 ? A wave t))=0.03sinπ(2t−0.01x) travels in a medium. Here x is in metre. [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A wave , t))=0.03sinπ(2t−0.01x) travels in a medium. Here , x is in metre. The instantaneous phase difference ( in rad) between the two point separated by 25 cm is , y(x ,
A wave, y(x, t))=0.03sinπ(2t−0.01x) travels in a medium. Here, x is in metre. The instantaneous phase difference ( in rad) between the two point separated by 25 cm is
01
Nov
A wave, y(x, t))=0.03sinπ(2t−0.01x) travels in a medium. Here, x is in metre. The instantaneous phase difference ( in rad) between the two point separated by 25 cm is A wave t))=0.03sinπ(2t−0.01x) travels in a medium. Here x is in metre. The instantaneous phase difference ( in rad) between the two point separated by 25 [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 16 - Waves , Volume 1 ,
Tags: A wave , t))=0.03sinπ(2t−0.01x) travels in a medium. Here , x is in metre. The instantaneous phase difference ( in rad) between the two point separated by 25 cm is , y(x ,