Volume 1

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The displacement equation of a particle is x = 3sin2t + 4cos2t. The amplitude and maximum velocity will be respectively
01
Nov
The displacement equation of a particle is x = 3sin2t + 4cos2t. The amplitude and maximum velocity will be respectively The displacement equation of a particle is x = 3sin2t + 4cos2t. The amplitude and maximum velocity will be respectively November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter 11 - SHM , [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: The displacement equation of a particle is x = 3sin2t + 4cos2t. The amplitude and maximum velocity will be respectively ,
Five identical springs are used in the following three configurations. The time periods of vertical oscillations in configurations (i), (ii) and (iii) are in the ratio
01
Nov
Five identical springs are used in the following three configurations. The time periods of vertical oscillations in configurations (i), (ii) and (iii) are in the ratio (ii) and (iii) are in the ratio Five identical springs are used in the following three configurations. The time periods of vertical oscillations in configurations (i) November 1, 2020 [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: (ii) and (iii) are in the ratio , Five identical springs are used in the following three configurations. The time periods of vertical oscillations in configurations (i) ,
A particle is attached to a vertical spring and is pulled down a distance 0.04m below its equilibrium position and is released from rest. The initial upward acceleration of the particle is 0.30ms^−2. The period of the oscillation is
01
Nov
A particle is attached to a vertical spring and is pulled down a distance 0.04m below its equilibrium position and is released from rest. The initial upward acceleration of the particle is 0.30ms^−2. The period of the oscillation is simple harmonic motion is related to time t ( in second ) as x = 0.01cos(πt+π/4) [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: simple harmonic motion is related to time t ( in second ) as x = 0.01cos(πt+π/4) the frequency of the motion will be , The displacement x (in metre ) of a particle in ,
The displacement x (in metre ) of a particle in, simple harmonic motion is related to time t ( in second ) as x = 0.01cos(πt+π/4) the frequency of the motion will be
01
Nov
The displacement x (in metre ) of a particle in, simple harmonic motion is related to time t ( in second ) as x = 0.01cos(πt+π/4) the frequency of the motion will be simple harmonic motion is related to time t ( in second ) as x = 0.01cos(πt+π/4) the frequency of the motion will [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: simple harmonic motion is related to time t ( in second ) as x = 0.01cos(πt+π/4) the frequency of the motion will be , The displacement x (in metre ) of a particle in ,
The equation of SHM of a particle is d^2y/dt^2 +ky = 0, where k is a positive constant. The time period of motion is given by
01
Nov
The equation of SHM of a particle is d^2y/dt^2 +ky = 0, where k is a positive constant. The time period of motion is given by The equation of SHM of a particle is d^2y/dt^2 +ky = 0 where k is a positive constant. The time period of motion is given by November 1, 2020 [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: The equation of SHM of a particle is d^2y/dt^2 +ky = 0 , where k is a positive constant. The time period of motion is given by ,
A particle executes linear simple harmonic motion with an amplitude of 2 cm . When the particle is at 1 cm from the mean position the magnitude of its velocity is equal to that of its acceleration. Then its time period in seconds is
31
Oct
A particle executes linear simple harmonic motion with an amplitude of 2 cm . When the particle is at 1 cm from the mean position the magnitude of its velocity is equal to that of its acceleration. Then its time period in seconds is A particle starts Simple harmonic motion from the mean position. Its [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: A particle starts Simple harmonic motion from the mean position. Its amplitude is a and total energy E. At on instant its kinetic energy is 4/3E ​. Its displacement at that instant is-duplicate-1 ,
A mass m is suspended from a spring. Its frequency of oscillation is f. The spring is cut into equal halves and the same mass is suspended from one of the two pieces of the spring. The frequency of oscillation is the mass will be
31
Oct
A mass m is suspended from a spring. Its frequency of oscillation is f. The spring is cut into equal halves and the same mass is suspended from one of the two pieces of the spring. The frequency of oscillation is the mass will be A particle starts Simple harmonic motion from the mean position. [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: A particle starts Simple harmonic motion from the mean position. Its amplitude is a and total energy E. At on instant its kinetic energy is 4/3E ​. Its displacement at that instant is-duplicate-1 ,
A particle starts Simple harmonic motion from the mean position. Its amplitude is a and total energy E. At on instant its kinetic energy is 4/3E ​. Its displacement at that instant is
31
Oct
A particle starts Simple harmonic motion from the mean position. Its amplitude is a and total energy E. At on instant its kinetic energy is 4/3E ​. Its displacement at that instant is A particle starts Simple harmonic motion from the mean position. Its amplitude is a and total energy E. At on instant its [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: A particle starts Simple harmonic motion from the mean position. Its amplitude is a and total energy E. At on instant its kinetic energy is 4/3E ​. Its displacement at that instant is-duplicate-1 ,
A particle starts Simple harmonic motion from the mean position. Its amplitude is a and total energy E. At on instant its kinetic energy is 4/3E ​. Its displacement at that instant is
31
Oct
A particle starts Simple harmonic motion from the mean position. Its amplitude is a and total energy E. At on instant its kinetic energy is 4/3E ​. Its displacement at that instant is
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: A particle starts Simple harmonic motion from the mean position. Its amplitude is a and total energy E. At on instant its kinetic energy is 4/3E ​. Its displacement at that instant is ,
Two simple harmonic motions y1 ​= Asinωt and y2 ​= Acosωt are superimposed on a particle of mass m. The total mechanical energy of the particle is
31
Oct
Two simple harmonic motions y1 ​= Asinωt and y2 ​= Acosωt are superimposed on a particle of mass m. The total mechanical energy of the particle is Two simple harmonic motions y1 ​= Asinωt and y2 ​= Acosωt are superimposed on a particle of mass m. The total mechanical energy of the particle is October [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 ,
Tags: Two simple harmonic motions y1 ​= Asinωt and y2 ​= Acosωt are superimposed on a particle of mass m. The total mechanical energy of the particle is ,