Sunday, 4 June 2017

THREE EQUATIONS OF MOTION
The three equations of motion v = u + at ; s = ut + (1/2) at2 and v2 = u2 + 2as can be derived with the help of graphs as described below.
1. Derive v = u + at by Graphical Method
Consider the velocity – time graph of a body shown in the below Figure.Velocity–Time graph to derive the equations of motion.
The body has an initial velocity u at point A and then its velocity changes at a uniform rate from A to B in time t. In other words, there is a uniform acceleration 'a' from A to B, and after time t its final velocity becomes 'v' which is equal to BC in the graph. The time t is represented by OC. To complete the figure, we draw the perpendicular CB from point C, and drawAD parallel to OCBE is the perpendicular from point Bto OE.
Now, Initial velocity of the body,u
=
OA...... (1)
And, Final velocity of the body, v
=
BC........ (2)
But from the graph BC
=
BD + DC
Therefore, v
=
BD + DC ......... (3)
Again DC
=
OA
So, v
=
BD + OA
Now, From equation (1), OA
=
u
So, v
=
BD + u ........... (4)
We should find out the value of BD now. We know that the slope of a velocity – time graph is equal to acceleration, a.
Thus, Acceleration, a
=
slope of line AB
or a
=
BD/AD
But AD
=
OC = t,
so putting t in place of AD in the above relation, we get:
a
=
BD/t
or BD
=
at
Now, putting this value of BD in equation (4) we get :
v
=
at + u
This equation can be rearranged to give:
v
=
u + at
And this is the first equation of motion. It has been derived here by the graphical method.
2. Derive s = ut + (1/2) at2 by Graphical Method
Velocity–Time graph to derive the equations of motion.
Suppose the body travels a distance s in time t. In the above Figure, the distance travelled by the body is given by the area of the space between the velocity – time graph AB and the time axis OC,which is equal to the area of the figure OABC. Thus:
Distance travelled
=
Area of figure OABC
=
Area of rectangle OADC + Area of triangle ABD
We will now find out the area of the rectangle OADCand the area of the triangle ABD.
(i) Area of rectangle OADC
=
OA × OC
=
u × t
=
ut ...... (5)
(ii) Area of triangle ABD
=
(1/2) × Area of rectangle AEBD
=
(1/2) × AD × BD
=
(1/2) × t × at (because AD = tand BD = at)
=
(1/2) at2...... (6)
So, Distance travelled, s
=
Area of rectangle OADC + Area of triangle ABD
or s = ut + (1/2) at2
This is the second equation of motion. It has been derived here by the graphical method.
3. Derive v2 = u2 + 2as by Graphical Method
Velocity–Time graph to derive the equations of motion.
We have just seen that the distance travelled s by a body in time t is given by the area of the figure OABCwhich is a trapezium. In other words,
Distance travelled, s
=
Area of trapezium OABC
Now, OA + CB = u + v and OC = t. Putting these values in the above relation, we get:
 ...... (7)
We now want to eliminate t from the above equation. This can be done by obtaining the value of t from the first equation of motion. Thus, v = u + at (First equation of motion)
And, at = v – u or 
Now, putting this value of t in equation (7) above, we get: 
or 2as
=
v2 – u2 [because (v + u) × (v – u) = v2 – u2]
or v2
=
u2 + 2as
This is the third equation of motion.

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