1. Prove v = u + at: Let us consider a particle is moving with uniform velocity u. Then it accelerates uniformly with a and after time t its final velocity is v. The change in velocity is (v – u) for time t. The acceleration of the particle is a 
.
Or, 
Or, at = v – uÂ
.
2. Prove 
: Let us consider a particle is moving with uniform velocity u. Then it accelerates uniformly with a and after time t its final velocity is v. The distance travelled by it for time t is s.
The average speed of the particle during its motion is 
.
Then, 
Or, 
Or, 
 [as v = u +at]
.
3. Prove v2 = u2 +2as:Â Let us consider a particle is moving with uniform velocity u. Then it accelerates uniformly with a and after time t its final velocity is v. The distance travelled by it for time t is s.
We know that, v = u + at
Or, v2 = (u + at)2
Or, v2 = u2 +2uat + a2t2
Or, v2 = u2 + 2a(ut + 
)
v2 = u2 + 2as [as s = ut +Â ].
4. The distance traveled by a particle in 
second: Let us consider a particle is moving with uniform velocity u. Then it accelerates uniformly with a and after time n second the distance travelled by it is 
.
The distance travelled by it in (n-1) second is 
.
The distance travelled by it in second is 
Or, = un – u(n – 1) + 
 — 
Or, = u + 
= u + 
.
Concept on inclined plane: A ball is released downwards from the top of a frictionless inclined plane of inclination 
. What is the speed of the ball when it travels l distance on inclined plane? Also calculate the time to travel distance l.
The acceleration of the ball on inclined plane is 
. The speed of the ball when it travels l distance on inclined plane is v. Then, 
.
v = 
 [as u = 0].
If t is the time taken to travel distance l, then using the relation s = ut + 
at2 we get, 
Â
.
