Arihant Physics by D.C Pandey

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The potential energy of a particle of mass 1 kg U = 10 + (x-2)^(2). Here, U is in joule and x in metre. On the positive x=axis particle travels up to x=+6cm. Choose the wrong statement.
26
Jun
The potential energy of a particle of mass 1 kg U = 10 + (x-2)^(2). Here, U is in joule and x in metre. On the positive x=axis particle travels up to x=+6cm. Choose the wrong statement. The potential energy of a particle of mass 1 kg U = 10 + (x-2)^(2). Here U is [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: The potential energy of a particle of mass 1 kg U = 10 + (x-2)^(2). Here , U is in joule and x in metre. On the positive x=axis particle travels up to x=+6cm. Choose the wrong statement. ,
Maximum velocity in SHM is vm​. The average velocity during motion form one extreme point to the other extreme point will be
26
Jun
Maximum velocity in SHM is vm​. The average velocity during motion form one extreme point to the other extreme point will be Maximum velocity in SHM is vm​. The average velocity during motion form one extreme point to the other extreme point will be June 26, 2021 Category: Arihant Physics by D.C Pandey , Chapter [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: Maximum velocity in SHM is vm​. The average velocity during motion form one extreme point to the other extreme point will be ,
A particle moves according to the law, x = a cos(pit/2). The distance covered by it in time interval t=0 to t=3 second is
26
Jun
A particle moves according to the law, x = a cos(pit/2). The distance covered by it in time interval t=0 to t=3 second is A particle moves according to the law x = a cos(pit/2). The distance covered by it in time interval t=0 to t=3 second is June 26, 2021 Category: Arihant Physics by [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: A particle moves according to the law , x = a cos(pit/2). The distance covered by it in time interval t=0 to t=3 second is ,
A pendulum has time period T for small oscillations. An obstacle P is situated below the point of suspension O at a distance (3l)/4. The pendulum is released from rest. Throughout the motion, the moving string makes small angle with vertical. Time after which the pendulum returns back to its initial position is
26
Jun
A pendulum has time period T for small oscillations. An obstacle P is situated below the point of suspension O at a distance (3l)/4. The pendulum is released from rest. Throughout the motion, the moving string makes small angle with vertical. Time after which the pendulum returns back to its initial position is A pendulum [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: A pendulum has time period T for small oscillations. An obstacle P is situated below the point of suspension O at a distance (3l)/4. The pendulum is released from rest. Throughout the motion , the moving string makes small angle with vertical. Time after which the pendulum returns back to its initial position is ,
The frequency of a particle executing SHM is 10 Hz. The particle is suspended from a vertical spring. At the highest point of its oscillation, the spring is unstretched. Maximum speed of the particle is (g=10m/s^2)
26
Jun
The frequency of a particle executing SHM is 10 Hz. The particle is suspended from a vertical spring. At the highest point of its oscillation, the spring is unstretched. Maximum speed of the particle is (g=10m/s^2) The frequency of a particle executing SHM is 10 Hz. The particle is suspended from a vertical spring. At [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: The frequency of a particle executing SHM is 10 Hz. The particle is suspended from a vertical spring. At the highest point of its oscillation , the spring is unstretched. Maximum speed of the particle is (g=10m/s^2) ,
Two masses M and m are suspended together by a massless spring of spring constant k. When the masses are in equilibrium, M is removed without disturbing the system. The maximum speed of m during oscillation is
26
Jun
Two masses M and m are suspended together by a massless spring of spring constant k. When the masses are in equilibrium, M is removed without disturbing the system. The maximum speed of m during oscillation is M is removed without disturbing the system. The maximum speed of m during oscillation is Two masses M [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: M is removed without disturbing the system. The maximum speed of m during oscillation is , Two masses M and m are suspended together by a massless spring of spring constant k. When the masses are in equilibrium ,
Displacement-time equation of a particle executing SHM is x=4 sin omega t+3 sin(omega t+pi/3). Here, x is in cm and t in sec. The amplitude of oscillation of the particle is approximately.
26
Jun
Displacement-time equation of a particle executing SHM is x=4 sin omega t+3 sin(omega t+pi/3). Here, x is in cm and t in sec. The amplitude of oscillation of the particle is approximately. Displacement-time equation of a particle executing SHM is x=4 sin omega t+3 sin(omega t+pi/3). Here x is in cm and t in sec. [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: Displacement-time equation of a particle executing SHM is x=4 sin omega t+3 sin(omega t+pi/3). Here , x is in cm and t in sec. The amplitude of oscillation of the particle is approximately. ,
Two simple harmonic motions y_(1) = A sin omega t and y_(2) = A cos omega t are superimposed on a particle of mass m. The total mechanical energy of the particle is
26
Jun
Two simple harmonic motions y_(1) = A sin omega t and y_(2) = A cos omega t are superimposed on a particle of mass m. The total mechanical energy of the particle is Two simple harmonic motions y_(1) = A sin omega t and y_(2) = A cos omega t are superimposed on a particle [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: Two simple harmonic motions y_(1) = A sin omega t and y_(2) = A cos omega t are superimposed on a particle of mass m. The total mechanical energy of the particle is ,
The maximum acceleration of a particle in SHM is made two times keeping the maximum speed to be constant. It is possible when.
26
Jun
The maximum acceleration of a particle in SHM is made two times keeping the maximum speed to be constant. It is possible when. The maximum acceleration of a particle in SHM is made two times keeping the maximum speed to be constant. It is possible when. June 26, 2021 Category: Arihant Physics by D.C Pandey [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: The maximum acceleration of a particle in SHM is made two times keeping the maximum speed to be constant. It is possible when. ,
A simple pendulum 4 m long swing with an amplitude of 0.2m. What is its acceleration at the ends of its path?
26
Jun
A simple pendulum 4 m long swing with an amplitude of 0.2m. What is its acceleration at the ends of its path? A simple pendulum 4 m long swing with an amplitude of 0.2m. What is its acceleration at the ends of its path? June 26, 2021 Category: Arihant Physics by D.C Pandey , Chapter [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 11 - SHM ,
Tags: A simple pendulum 4 m long swing with an amplitude of 0.2m. What is its acceleration at the ends of its path? ,