We were discussing the importance of friction i.e. positive and negative effects of friction, Classification of friction and Coulomb's law of dry friction with the help of our previous post.
Above equation shows that it will be a parabolic
equation and hence projectile motion trajectory will be parabolic.
Now, we will be interested further to understand a
very important topic in engineering mechanics i.e. projectile motion - trajectory equation, definition and formulas with the
help of this post. We will find out here the basics of projectile motion,
classification of projectile motion and various equations and formulas associated
with the projectile motion.
Let us first start here with the basic definition of projectile motion
Projectile motion is basically defined as a motion
where a particle moves in a vertical plane with some initial velocity but its
acceleration will always be the free fall acceleration i.e. acceleration due to
gravity which will be acting towards downward direction.
When a particle will be thrown in to the space, it
will have motion in x direction i.e. in horizontal direction and it will have
motion in y direction too i.e. in vertical direction.
The combination of motion of particle in x direction i.e.
in horizontal direction and in y direction i.e. in vertical direction could be
considered as the projectile motion.
We must need to note it here that the horizontal
motion and vertical motion of the particle in a projectile motion will be
independent with each other.
Let us consider that a particle is thrown in to the
space with initial velocity u with an angle θ with the horizontal direction as
displayed here in following figure.
Following equations, as displayed below, will be used in
order to determine the various desired formulas for a particle following the
projectile trajectory.
Where,
u = Initial velocity of the particle
V = Final velocity of the particle
a = Acceleration of the particle
t = Time of travel of the particle
Above equations will be only valid for a particle
which is under motion with constant acceleration.
In case of projectile motion, a i.e. acceleration of
the particle will be basically acceleration due to gravity i.e. g and it will
be acting towards downward direction.
We will have following equations, as mentioned below,
for particle motion in horizontal and in vertical direction.
Projectile trajectory equation
Time taken to reach the ground
Time taken to reach the ground i.e. T will be
determined with the help of following equation as mentioned below.
Range or horizontal distance traveled by the particle
Range or horizontal distance traveled by the particle
will be determined with the help of following equation as mentioned below.
Maximum height or maximum vertical distance traveled by the particle
Maximum height or maximum vertical distance traveled
by the particle will be determined with the help of following equation as
mentioned below.
Classification of projectile motion
Projectile motion will be basically classified in two
types as mentioned here.
- Horizontal plane projectile motion
- Inclined plane projectile motion
If we have a problem or a case of projectile motion
where the point of projection and point of striking both are on inclined plane,
we will say such projectile motion as inclined plane projectile motion.
Otherwise, we will say horizontal plane projectile
motion.
We must note it here very clearly that for inclined
plane projectile motion, the point of projection and point of striking both must
be on inclined plane.
Therefore, we have studied here the basics of projectile motion,
classification of projectile motion, equations associated with projectile
motion, time of flight, range and maximum height traveled by the particle in a
projectile motion with the help of this post.
Further we will find out another concept in engineering mechanics i.e. terminal velocity and its expression with
the help of our next post.
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Reference:
Engineering Mechanics, By Prof K. Ramesh
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