If `v=(t+2)(t+3)` then acceleration`(i.e(dv)/(dt))` at t=1 sec.

If the velocity of a paraticle moving along x-axis is given as v=(4t^(2)+3t=1)m//s then acceleration of the particle at t=1sec is :

A particle moves in such a way that its position vector at any time t is vec(r)=that(i)+1/2 t^(2)hat(j)+that(k) . Find as a function of time: (i) The velocity ((dvec(r))/(dt)) (ii) The speed (|(dvec(r))/(dt)|) (iii) The acceleration ((dvec(v))/(dt)) (iv) The magnitude of the acceleration (v) The magnitude of the component of acceleration along velocity (called tangential acceleration) (v) The magnitude of the component of acceleration perpendicular to velocity (called normal acceleration).

The position of a particle moving along a. straight line is given by x = 2 - 5t + t ^(3) The acceleration of the particle at t = 2 sec. is ...... Here x is in meter.

if position vector is vecr =4t^4−6t^3+3t^2+4tm find the acceleration at t=2 sec.

The position vector of an object moving in X-Z plane is vec(r)=v_(0)that(i)+a_(0)e^(b_(0)t)hat(k) . Find its (i) velocity (vec(v)=(dvec(r))/(dt)) (ii) speed (|vec(v)|) (iii) Acceleration ((dvec(v))/(dt)) as a function of time.

The displacement of particle with respect to time is s = 3^(t3) - 7t^(2) + 5t + 8 where s is in m and t is in s, then acceleration of particle at t = ls is

If v=(t^(2)-4t+10^(5)) m/s where t is in second. Find acceleration at t=1 sec.

The velocity of a particle is given by v=(2t^(2)-4t+3)m//s where t is time in seconds. Find its acceleration at t=2 second.

Block B has a downward velocity in m//s and given by v_(B)=t^(2)/2+t^(3)/6 , where t is in s. Acceleration of A at t=2 second is

A particle covers distance S in time t is given by S=t^(3)-6t^(2)+6t+8 . When the acceleration is 0, the velocity is …………