Assertion: In vertical circular motion, acceleration of bob at position `A` is greater than `'`g'` .

Reason: Net acceleration at `A` is resultant of tangential and radial components of acceleration.

In a uniform circular motion, the centripetal acceleration is

Assertion In circular motion, acceleration of particle is not always towards centre. Reason If speed of particle is not constant, acceleration is not towards centre.

Assertion: A uniform circular motion is an acceleration motion. Reason: Direction of acceleration is parallel to velocity vector.

In case of a uniform circular motion, velocity and acceleration are

Position-time graph for motion with zero acceleration is

Assertion: A pendulam is oscillating between points A , B and C . Acceleration of bob at points A or C is zero. Reason: Velocity at these points is zero.

Position - time graph for motion with negative acceleration is

Assertion:- A particle is moving in a circle with constant tangential acceleration such that its speed v is increasing. Angle made by resultant acceleration of the particle with tangential acceleration increases with time. Reason:- Tangential acceleration =|(dvecv)/(dt)| and centripetal acceleration =(v^(2))/(R)

A particle moves in a circle with constant tangential acceleration starting from rest. At t = 1/2 s radial acceleration has a value 25% of tangential acceleration. The value of tangential acceleration will be correctly represented by

For any particle moving with some velocity (vecv) & acceleration (veca) , tangential acceleration & normal acceleration are defined as follows. Tangential acceleration - The component of acceleration in the direction of velocity. Normal acceleration - The component of acceleration in the direction perpendicular to velocity. If at a given instant, velocity & acceleration of a particle are given by . vecc=4hati +3hatj veca=10hati+15hatj+20hatk Find the tangential acceleration of the particle at the given instant :-