Physics-
General
Easy

Question

The velocity-time diagram of a harmonic oscillator is shown in the adjoining figure. The frequency of oscillation is

  1. 25 Hz    
  2. 50 Hz    
  3. 12.25 Hz    
  4. 33.3 Hz    

The correct answer is: 25 Hz

Related Questions to study

General
Physics-

For a particle executing S.H.M. the displacement x is given by x equals A cos invisible function application omega t. Identify the graph which represents the variation of potential energy (P.E.) as a function of time t and displacement x

For a particle executing S.H.M. the displacement x is given by x equals A cos invisible function application omega t. Identify the graph which represents the variation of potential energy (P.E.) as a function of time t and displacement x

Physics-General
General
Physics-

The graph shows the variation of displacement of a particle executing S.H.M. with time. We infer from this graph that

The graph shows the variation of displacement of a particle executing S.H.M. with time. We infer from this graph that

Physics-General
General
Physics-

The displacement time graph of a particle executing S.H.M. is as shown in the figure

The corresponding force-time graph of the particle is

The displacement time graph of a particle executing S.H.M. is as shown in the figure

The corresponding force-time graph of the particle is

Physics-General
parallel
General
Physics-

The acceleration a of a particle undergoing S.H.M. is shown in the figure. Which of the labelled points corresponds to the particle being at – xmax

The acceleration a of a particle undergoing S.H.M. is shown in the figure. Which of the labelled points corresponds to the particle being at – xmax

Physics-General
General
Physics-

A particle of mass m is attached to three identical springs A, B and C each of force constant k a shown in figure. If the particle of mass m is pushed slightly against the spring A and released then the time period of oscillations is

A particle of mass m is attached to three identical springs A, B and C each of force constant k a shown in figure. If the particle of mass m is pushed slightly against the spring A and released then the time period of oscillations is

Physics-General
General
Physics-

One end of a spring of force constant k is fixed to a vertical wall and the other to a block of mass m resting on a smooth horizontal surface. There is another wall at a distance x subscript 0 end subscript from the black. The spring is then compressed by 2 x subscript 0 end subscript and released. The time taken to strike the wall is

One end of a spring of force constant k is fixed to a vertical wall and the other to a block of mass m resting on a smooth horizontal surface. There is another wall at a distance x subscript 0 end subscript from the black. The spring is then compressed by 2 x subscript 0 end subscript and released. The time taken to strike the wall is

Physics-General
parallel
General
Physics-

Two identical balls A and B each of mass 0.1 kg are attached to two identical massless springs. The spring mass system is constrained to move inside a rigid smooth pipe bent in the form of a circle as shown in the figure. The pipe is fixed in a horizontal plane. The centres of the balls can move in a circle of radius 0.06 m. Each spring has a natural length of 0.06p m and force constant 0.1N/m. Initially both the balls are displaced by an angle theta equals pi divided by 6 radian with respect to the diameter P Q of the circle and released from rest. The frequency of oscillation of the ball B is

Two identical balls A and B each of mass 0.1 kg are attached to two identical massless springs. The spring mass system is constrained to move inside a rigid smooth pipe bent in the form of a circle as shown in the figure. The pipe is fixed in a horizontal plane. The centres of the balls can move in a circle of radius 0.06 m. Each spring has a natural length of 0.06p m and force constant 0.1N/m. Initially both the balls are displaced by an angle theta equals pi divided by 6 radian with respect to the diameter P Q of the circle and released from rest. The frequency of oscillation of the ball B is

Physics-General
General
Physics-

On a smooth inclined plane, a body of mass M is attached between two springs. The other ends of the springs are fixed to firm supports. If each spring has force constant K, the period of oscillation of the body (assuming the springs as massless) is

On a smooth inclined plane, a body of mass M is attached between two springs. The other ends of the springs are fixed to firm supports. If each spring has force constant K, the period of oscillation of the body (assuming the springs as massless) is

Physics-General
General
Physics-

A cylindrical piston of mass M slides smoothly inside a long cylinder closed at one end, enclosing a certain mass of gas. The cylinder is kept with its axis horizontal. If the piston is disturbed from its equilibrium position, it oscillates simple harmonically. The period of oscillation will be

A cylindrical piston of mass M slides smoothly inside a long cylinder closed at one end, enclosing a certain mass of gas. The cylinder is kept with its axis horizontal. If the piston is disturbed from its equilibrium position, it oscillates simple harmonically. The period of oscillation will be

Physics-General
parallel
General
Physics-

Two blocks A and B each of mass m are connected by a massless spring of natural length L and spring constant K. The blocks are initially resting on a smooth horizontal floor with the spring at its natural length as shown in figure. A third identical block C also of mass m moves on the floor with a speed v along the line joining A and B and collides with A. Then

Two blocks A and B each of mass m are connected by a massless spring of natural length L and spring constant K. The blocks are initially resting on a smooth horizontal floor with the spring at its natural length as shown in figure. A third identical block C also of mass m moves on the floor with a speed v along the line joining A and B and collides with A. Then

Physics-General
General
Physics-

Two masses m1 and m2 are suspended together by a massless spring of constant K. When the masses are in equilibrium, m1 is removed without disturbing the system. The amplitude of oscillations is

Two masses m1 and m2 are suspended together by a massless spring of constant K. When the masses are in equilibrium, m1 is removed without disturbing the system. The amplitude of oscillations is

Physics-General
General
Physics-

The springs shown are identical. When A equals 4 k g, the elongation of spring is 1 cm. If B equals 6 k g, the elongation produced by it is

The springs shown are identical. When A equals 4 k g, the elongation of spring is 1 cm. If B equals 6 k g, the elongation produced by it is

Physics-General
parallel
General
Physics-

Two springs of force constants K and 2K are connected to a mass as shown below. The frequency of oscillation of the mass is 

Two springs of force constants K and 2K are connected to a mass as shown below. The frequency of oscillation of the mass is 

Physics-General
General
Physics-

A mass m is suspended separately by two different springs of spring constant K1 and K2 gives the time-period t subscript 1 end subscript and t subscript 2 end subscript respectively. If same mass m is connected by both springs as shown in figure then time-period t is given by the relation

A mass m is suspended separately by two different springs of spring constant K1 and K2 gives the time-period t subscript 1 end subscript and t subscript 2 end subscript respectively. If same mass m is connected by both springs as shown in figure then time-period t is given by the relation

Physics-General
General
Physics-

The frequency of oscillation of the springs shown in the figure will be

The frequency of oscillation of the springs shown in the figure will be

Physics-General
parallel

card img

With Turito Academy.

card img

With Turito Foundation.

card img

Get an Expert Advice From Turito.

Turito Academy

card img

With Turito Academy.

Test Prep

card img

With Turito Foundation.