Part 1

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A simple pendulum is suspended from the roof of a trolley that moves freely down a plane of inclination theta. The time period of oscillation of the pendulum is
30
Oct
A simple pendulum is suspended from the roof of a trolley that moves freely down a plane of inclination theta. The time period of oscillation of the pendulum is A simple pendulum is suspended from the roof of a trolley that moves freely down a plane of inclination theta. The time period of oscillation of [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A simple pendulum is suspended from the roof of a trolley that moves freely down a plane of inclination theta. The time period of oscillation of the pendulum is ,
A simple pendulum is set up in a trolley which moves to the right with an acceleration a on a horizontal plane. Then the thread of the pendulum in the mean position makes an angle θ with the vertical
30
Oct
A simple pendulum is set up in a trolley which moves to the right with an acceleration a on a horizontal plane. Then the thread of the pendulum in the mean position makes an angle θ with the vertical A simple pendulum is set up in a trolley which moves to the right with an [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A simple pendulum is set up in a trolley which moves to the right with an acceleration a on a horizontal plane. Then the thread of the pendulum in the mean position makes an angle θ with the vertical ,
A simple pendulum is oscillating in a lift. If the lift starts moving upwards with a uniform acceleration, the period will
30
Oct
A simple pendulum is oscillating in a lift. If the lift starts moving upwards with a uniform acceleration, the period will A simple pendulum is oscillating in a lift. If the lift starts moving upwards with a uniform acceleration the period will October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter 13 - [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A simple pendulum is oscillating in a lift. If the lift starts moving upwards with a uniform acceleration , the period will ,
The length of a simple pendulum is increased by 44%. The percentage increase in its time period will be
30
Oct
The length of a simple pendulum is increased by 44%. The percentage increase in its time period will be The length of a simple pendulum is increased by 44%. The percentage increase in its time period will be October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: The length of a simple pendulum is increased by 44%. The percentage increase in its time period will be ,
Time period of a simple pendulum is T. If its length increases by 2%, the new time period becomes
30
Oct
Time period of a simple pendulum is T. If its length increases by 2%, the new time period becomes the new time period becomes Time period of a simple pendulum is T. If its length increases by 2% October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: the new time period becomes , Time period of a simple pendulum is T. If its length increases by 2% ,
Starting from the origin a body oscillates simple harmonically with a period of 2s . After what time will its kinetic energy be 75% of its total energy ,
30
Oct
Starting from the origin a body oscillates simple harmonically with a period of 2s . After what time will its kinetic energy be 75% of its total energy , Starting from the origin a body oscillates simple harmonically with a period of 2s . After what time will its kinetic energy be 75% of its [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: Starting from the origin a body oscillates simple harmonically with a period of 2s . After what time will its kinetic energy be 75% of its total energy ,
A body is executing SHM, At a displacement x, its potential energy is E1 and at a displacement y, its potential energy is E2. Find its potential energy E at displacement ( x + y) is
30
Oct
A body is executing SHM, At a displacement x, its potential energy is E1 and at a displacement y, its potential energy is E2. Find its potential energy E at displacement ( x + y) is A body is executing SHM At a displacement x its potential energy is E1 and at a displacement y [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A body is executing SHM , At a displacement x , its potential energy is E1 and at a displacement y , its potential energy is E2. Find its potential energy E at displacement ( x + y) is ,
The kinetic energy and potential energy of a particle executing SHM will be equal when displacement (amplitude = a) is
30
Oct
The kinetic energy and potential energy of a particle executing SHM will be equal when displacement (amplitude = a) is The kinetic energy and potential energy of a particle executing SHM will be equal when displacement (amplitude = a) is October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: The kinetic energy and potential energy of a particle executing SHM will be equal when displacement (amplitude = a) is ,
The potential energy of a particle with displacement X is U(X). The motion is simple harmonic, when (K is a positive constant)
30
Oct
The potential energy of a particle with displacement X is U(X). The motion is simple harmonic, when (K is a positive constant) The potential energy of a particle with displacement X is U(X). The motion is simple harmonic when (K is a positive constant) October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: The potential energy of a particle with displacement X is U(X). The motion is simple harmonic , when (K is a positive constant) ,
A particle executes SHM with a time period of 16s. At time t=2s, the particle crosses the mean position while at t=4s, its velocity is 4 ms^−1. The amplitude of motion in metre is?
30
Oct
A particle executes SHM with a time period of 16s. At time t=2s, the particle crosses the mean position while at t=4s, its velocity is 4 ms^−1. The amplitude of motion in metre is? A particle executes SHM with a time period of 16s. At time t=2s its velocity is 4 ms^−1. The amplitude of [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A particle executes SHM with a time period of 16s. At time t=2s , its velocity is 4 ms^−1. The amplitude of motion in metre is? , the particle crosses the mean position while at t=4s ,