In the figure given , A and B are two particles having same magnitude of angular velocity in opposite sense, at t = 0 , then `vec(V) _(A)- vecV_B" at " t = pi/(2omega)` sec is

If vec a and vec b are two vectors of the same magnitude inclined at an angle of 30^0 such that vec adot vec b=3, find | vec a|,| vec b| .

vec(A) and vec(B) are two vectors having the same magnitude but acting at right angle to each other . On the same diagram represent vec(A) + vec(B) and vec(A) - vec(B) using a suitable scale ?

vec(A) and vec(B) are two vectors having the same magnitude . What is the condition that (i) the vector sum vec(A)+vec(B) and (ii) the vector differece vec(A) + vec(B) have the same magnitude as vec(A) and vec(B) ?

A force F of constant magnitude acts on a block of mass 'm' and t=0,initially along positive x-direction. The direction of force F starts rotating with a constant angular velocity omega in anticlockwise sense. Then the magnitude of velocity of the block as a function of time 't' is ( initial block was at rest )

Two charged particles traverse identical helical paths in a completely opposite sense in a uniform magnetic field vec(B)=B_(0)hat(K)

Two charged particles traverse identical helical paths in a completely opposite sense in a uniform magnetic field vec(B)=B_(0)hat(K)

Two charged particles traverse identical helical paths in a completely opposite sense in a uniform magnetic field vec(B)=B_(0)hat(K)

Find the magnitude of two vectors vec a and vec b having the same magnitude and such that the angle between them is 60^0 and their scalar product is 1/2 .

If velocity of a particle is given by v=(2t+3)m//s . Then average velocity in interval 0letle1 s is :

Two particles A,B are moving on two concentric circles of radii R_1 and R_2 with equal angular speed omega . At t=0 ,their positions and direction of motion are shown in the figure. The relative velocity vecV_a-vecV_b at t=pi//2omega is given by :