The position vector of a aprticle is given as `vecr=(5t^2-4t+6)hati+(t^2)hatj`. The time after which the velocity vector and acceleration vector becomes perpendicular to each other is equal to

The position vector of a aprticle is given as vecr=(t^2-4t+6)hati+(t^2)hatj . The time after which the velocity vector and acceleration vector becomes perpendicular to each other is equal to

The position vector of a aprticle is given as vecr=(3t^2-2t+5)hati+(3t^2)hatj . The time after which the velocity vector and acceleration vector becomes perpendicular to each other is equal to

The position vector of a aprticle is given as vecr=(t^2-t+2)hati+(3t)hatj . The time after which the velocity vector and acceleration vector becomes perpendicular to each other is equal to

The position vector of car w.r.t. its starting point is given as vecr="at" hati+bt^(2)hatj where a and b are positive constants. find the equation of trajectory :-

The velocity of a particle is given by v=(5t^(2)-6t+5)m//s where t is time in seconds. Find its acceleration at t=4 second.

The position vector of a particle is given by vecr=vecr_(0) (1-at)t, where t is the time and a as well as vecr_(0) are constant. After what time the particle retursn to the starting point?

The velocity of a particle is v=6hati+2hatj-2hatk The component of the velocity parallel to vector a=hati+hatj+2hatk invector from is

The angular velocity of a particle is given by omega=1.5t-3t^(2)+2 , Find the time when its angular acceleration becomes zero.

Suppose velocity of a cricket ball hit by a batsman is given by vec(v) = (2hati +6hatj + (@0-10t)hatk)m//s Find the time (t) the acceleration of the ball is perpendicular to its velocity.

Assertion: If the positon vector of a particle moving in space is given by vecr=2thati-4t^(2)hatj , then the particle moves along a parabolic trajector. Reason: vecr=xhati+yhatj and vecr=2thati-4t^(2)j rArr y=-x^(2) .