Projectile motion: Difference between revisions

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Projectile motion is a form of motion where a particle (called a projectile) is thrown obliquely near the earth's surface, it moves along a curved path under the action of gravity. The path followed by a projectile motion is called its trajectory. Projectile motion only occurs when there is one force applied at the beginning of the trajectory after which there is no interference apart from gravity.

If the projectile is launched with an initial velocity v₀, then it can be written as

${\displaystyle \mathbf {v} _{0}=v_{0x}\mathbf {i} +v_{0y}\mathbf {j} }$.

The components v_0x and v_0y can be found if the angle, ϴ is known:

${\displaystyle v_{0x}=v_{0}\cos \theta }$,

${\displaystyle v_{0y}=v_{0}\sin \theta }$.

If the projectile's range, launch angle, and drop height are known, launch velocity can be found by

${\displaystyle V_{0}={\sqrt {{R^{2}g} \over {R\sin 2\theta +2h\cos ^{2}\theta }}}}$.

The launch angle is usually expressed by the symbol theta, but often the symbol alpha is used.

In projectile motion, the horizontal motion and the vertical motion are independent of each other; that is, neither motion affects the other.

Since there is no acceleration in the horizontal direction velocity in horizontal direction is constant which is equal to ucosα. The vertical motion of the projectile is the motion of a particle during its free fall. Here the acceleration is constant, equal to g.^[1] The components of the acceleration:

${\displaystyle a_{x}=0}$,

${\displaystyle a_{y}=-g}$.

The horizontal component of the velocity remains unchanged throughout the motion. The vertical component of the velocity increases linearly, because the acceleration is constant. At any time t, the components of the velocity:

${\displaystyle v_{x}=v_{0}\cos(\theta )}$,

${\displaystyle v_{y}=v_{0}\sin(\theta )-gt}$.

The magnitude of the velocity (under the Pythagorean theorem):

${\displaystyle v={\sqrt {v_{x}^{2}+v_{y}^{2}\ }}}$.

At any time t, the projectile's horizontal and vertical displacement:

${\displaystyle x=v_{0}t\cos(\theta )}$,

${\displaystyle y=v_{0}t\sin(\theta )-{\frac {1}{2}}gt^{2}}$.

The magnitude of the displacement:

${\displaystyle \Delta r={\sqrt {x^{2}+y^{2}\ }}}$.

Consider the equations,

${\displaystyle x=v_{0}t\cos(\theta )}$,

${\displaystyle y=v_{0}t\sin(\theta )-{\frac {1}{2}}gt^{2}}$.

If we eliminate t between these two equations we will obtain the following:

${\displaystyle y=\tan(\theta )\cdot x-{\frac {g}{2v_{0}^{2}\cos ^{2}\theta }}\cdot x^{2}}$,

This equation is the equation of. Since g, α, and v₀ are constants, the above equation is of the form

${\displaystyle y=ax+bx^{2}}$,

in which a and b are constants. This is the equation of a parabola, so the path is parabolic. The axis of the parabola is vertical.

The highest height which the object will reach is known as the peak of the object's motion. The increase of the height will last, until v_y = 0.

${\displaystyle 0=v_{0}\sin(\theta )-gt_{h}}$,

Time to reach the maximum height:

${\displaystyle t_{h}={v_{0}\sin(\theta ) \over g}}$.

From the vertical displacement the maximum height of projectile:

${\displaystyle h=v_{0}t_{h}\sin(\theta )-{\frac {1}{2}}gt_{h}^{2}}$,

so

${\displaystyle h={v_{0}^{2}\sin ^{2}\theta \over {2g}}}$ .

For the relation between the distance traveled, the maximum hight and angle of launch, the equation below has been developed.

${\displaystyle h={d\tan \theta \over {4}}}$

• Budó Ágoston:, összefüggések és adatok, Budapest, Nemzeti Tankönyvkiadó, 2004. ISBN 963-19-3506-X Template:Hu

• NCLab provides an interactive graphical module for projectile motion with and without air resistance.
• Open Source Physics computer model
• A Java simulation of projectile motion, including first-order air resistance

NOTE: Since the value of g is not specific the body with high velocity over g limit cannot be measured using the concept of the projectile motion.