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Chapter-2
Motion along a straight line
Prepared by Dr
...
K
...
It is a scalar quantity and cannot be
negative
...
Displacement Vector
The shortest distance between the initial and final point is called displacement
...
If during a time interval ∆t the position vector of the particle changes from ݔଵ to ݔଶ, the
Ԧ
Ԧ
Displacement vector of the particle ߂ ݔfor that time interval is defined as: ߂ݔ = ݔଶ − ݔଵ
Ԧ
Ԧ
Ԧ
Ԧ
Speed
The amount of distance travelled by a body in one second is called its speed
...
It cannot be negative
...
ܽ= ݀݁݁ݏ ݁݃ܽݎ݁ݒ
ݔ ݈݈݀݁݁ݒܽݎݐ ݁ܿ݊ܽݐݏ݅݀ ݈ܽݐݐଵ + ݔଶ + ݔଷ …
...
Problem
A body moves with speed 50 km/h and returned with 40 km/h to the same point
...
ܽ= ݀݁݁ݏ ݁݃ܽݎ݁ݒ
ݔଵ + ݔଶ
ݔ+ݔ
= ݔ
/݉݇ 4
...
ܽ= ݕݐ݈݅ܿ݁ݒ ݁݃ܽݎ݁ݒ
ݒ௩ି௫ =
Ԧ
Ԧ
௱௫
௱௧
=
ሬሬሬሬԦି௫భ
௫మ ሬሬሬሬԦ
௧మ ି௧భ
ܿℎܽ݊݃݁ ݅݊ ݀݅ݐ݈݊݁݉݁ܿܽݏ
݈ܽݒݎ݁ݐ݊݅ ݁݉݅ݐ
Working formula
Instantaneous Velocity:
As discussed in rectilinear motion, a more interesting quantity is the instantaneous velocity ݒ
Ԧ,
which is the limit of the average velocity when we shrink the time interval ∆t to zero
...
The velocity ݒଶ differs both in magnitude and direction from the velocity ݒଵ
...
Ԧ
Ԧ
Instantaneous Acceleration
But the much more interesting quantity is the result of shrinking the period ߂ ݐto zero, which
gives us the instantaneous acceleration, ܽ It is the time derivative of the velocity vector ݒ
Ԧ
...
We want to derive two/three sets of equations to describe the x, y and z coordinates, each of which is similar to the equations in rectilinear motion
...
௩ ି௩
Therefore, the acceleration along x-direction will be, ܽ௫ = మೣ ି௧ భೣ
...
Then, ܽ௫ =
௩ೣ ି௩బೣ
௧ି
ݒ௫ = ݒ௫ + ܽ௫ )1
...
Then the average velocity will be
ݒ௩ି௫ =
ݔ − ݔ
… … … … … … … …
...
2)
ݐ
If the same body moves with initial velocity ݒ௫ and attain final velocity ݒ௫ after certain time,
then average velocity will be
ݒ௩ି௫ =
ݒ௩ି௫ =
௩బೣ ା௩ೣ
ଶ
(ݒ௫ + ݒ௫ + ܽ௫ )ݐ
2
1
⇒ ݒ௩ି௫ = ݒ௫ + ܽ௫ )3
...
… … … … … … … ݐ
2
From eq
...
2) and eq
...
3), we get
ݔ − ݔ
1
= ݒ௫ + ܽ௫ ݐ
ݐ
2
1
⇒ ݔ − ݔ = ݐ൬ݒ௫ + ܽ௫ ݐ൰
2
ଵ
ݔ − ݔ = ݒ௫ ܽ + ݐ௫ ݐଶ … … … … … … … … … …
...
4) Working formula
ଶ
Derivation of 3rd kinematic equation:
To relate displacement, acceleration, initial velocity and final velocity, we should find the time
from equation (1
...
(1
...
(1
...
6) Working formula
The above eq
...
1),(1
...
6) can be resolved in to three sets of equations to describe the
motion along the three Cartesian directions as
ݒ௫ = ݒ௫ + ܽ௫ ݒ ;ݐ௬ = ݒ௬ + ܽ௬ ݒ ;ݐ௭ = ݒ௭ + ܽ௭ ;ݐ
1
1
1
(ݔ − ݔ ) = ݒ௫ ܽ + ݐ௫ ݐଶ ; (ݕ − ݕ ) = ݒ௬ ܽ + ݐ௬ ݐଶ ; (ݖ − ݖ ) = ݒ௭ ܽ + ݐ௭ ݐଶ ;
2
2
2
ݒ௫ ଶ = ݒ௫ ଶ + 2ܽ௫ (ݔ − ݔ ); ݒ௬ ଶ = ݒ௬ ଶ + 2ܽ௬ (ݕ − ݕ ); ݒ௭ ଶ = ݒ௭ ଶ + 2ܽ௭ (ݖ − ݖ );
Best of luck