For a particle travelling along a straight line the equation of motion is s = 16 t+5`t^(2)`. Show that it will always travel with uniform acceleration.

If the equation of motion for a body is s=16 t + 5t^2 then show that it will always move--------.

Distance covered by a particle moving in a straight line from origin in time t is given by x = t- 6t^(2)+t^(3) . For what value of t, will the particle's acceleration be zero?

The distance travelled by an object along a straight line in time 't' is given by S = 3 - 4t + 5t^(2) , the initial velocity of the object is

The velocity of a car travelling on a straight road is 36kmh^(-1) at an instant of time. Now travelling with uniform acceleration for 10s, the velocity becomes exactly double. If the wheel radius of the car is 25cm, then which of the following numbers is the closest to the number of revolutions that the wheel makes during this 10s?

The distance S metres moved by a particle traveling in a straight line in t second is given by S = 45t +11t^2-t^3 . Find the time when the particle comes to rest.

A particle is moving in a vertical line whose equation of motion is given by s = 32 + 46t+9t^2 where 's' is measured in meters and 't' is measured in seconds. Find the velocity and acceleration of the particle at t=3 sec.

A particle starting from a point A and moving with a positive constant acceleration along a straight line reaches another point B is time T. Suppose that the initial velocity of the particle is u gt0 and P is the midpoint of the line AB. If the velocity of the particle at point P is v_(1) and if the velocity at time (T)/(2) is v_(2) , then -

Starting from rest a particle moving along a straight line attains a speed of 2 "m.s"^(-1) in 1.5 s. What is the particle's speed after an additional 3 s has elapsed assuming that the particle is moving with constant acceleration?

A particle moves along a straight line by a metre and then makes an angle theta with the line and travels b metre. Find the resultant displacement of the particle.