# Projectile Motion

We have seen various types of motions in our previous sessions. We also know what happens to objects thrown into space. In this article, we will be discussing projectile motion and other concepts like the time of flight formula, horizontal range, maximum height of projectile, the equation of trajectory along with solved examples.

## What is Projectile?

A projectile is any object thrown into space upon which the only acting force is gravity. The primary force acting on a projectile is gravity. This doesn’t necessarily mean that other forces do not act on it, just that their effect is minimal compared to gravity. The path followed by a projectile is known as a trajectory. A baseball batted or thrown is an example of the projectile.

## What is Projectile Motion?

When a particle is thrown obliquely near the earth’s surface, it moves along a curved path under constant acceleration that is directed towards the centre of the earth (we assume that the particle remains close to the surface of the earth). The path of such a particle is called a projectile and the motion is called projectile motion.

In a Projectile Motion, there are two simultaneous independent rectilinear motions:

1. Along the x-axis: uniform velocity, responsible for the horizontal (forward) motion of the particle.
2. Along y-axis: uniform acceleration, responsible for the vertical (downwards) motion of the particle.

Acceleration in the horizontal projectile motion and vertical projectile motion of a particle: When a particle is projected in the air with some speed, the only force acting on it during its time in the air is the acceleration due to gravity (g). This acceleration acts vertically downward. There is no acceleration in the horizontal direction, which means that the velocity of the particle in the horizontal direction remains constant.

### Parabolic Motion of Projectiles

Let us consider a ball projected at an angle θ with respect to the horizontal x-axis with the initial velocity u as shown below:

The point O is called the point of projection; θ is the angle of projection and OB = Horizontal Range or Simply Range. The total time taken by the particle from reaching O to B is called the time of flight.

For finding different parameters related to projectile motion, we can make use of differential equations of motions:

### Total Time of Flight

Resultant displacement (s) = 0 in Vertical direction. Therefore, the time of flight formula is given by using the Equation of motion:

gt2 = 2(uyt – sy) [Here, uy = u sin θ and sy = 0]

i.e. gt2 = 2t × u sin θ

Therefore, the time of flight formula (t) is given by:

$$Total\,Time\,of\,Flight\,(t)=\frac{2u\sin\Theta}{g}$$

### Horizontal Range

Horizontal Range (OA) = Horizontal component of velocity (ux) × Total Flight Time (t)

R = u cos θ × 2u×sinθg

Therefore, in a projectile motion the Horizontal Range is given by (R):

$$Horizontal\,Range\,(R)=\frac{u^2\sin 2\Theta }{g}$$

### Maximum Height of Projectile

After understanding what is projectile and what is projectile motion, let us know the maximum height of projectile. The maximum height of the object is the highest vertical position along its trajectory. The horizontal displacement of the projectile is called the range of the projectile. The range of the projectile is dependent on the initial velocity of the object.

If v is the initial velocity, g = acceleration due to gravity and H = maximum height in meters, θ = angle of the initial velocity from the horizontal plane (radians or degrees).

The maximum height of projectile is given by the formula:

$$H=\frac{v_{0}^{2}sin^{2}\theta}{2g}$$

### The Equation of Trajectory

$$Equation\,of\,Trajectory = x\tan \Theta -\frac{gx^2}{2u^2cos^{2}\Theta }$$

This is the equation of trajectory in projectile motion, and it proves that the projectile motion is always parabolic in nature.

We know that projectile motion is a type of two-dimensional motion or motion in a plane. It is assumed that the only force acting on a projectile (the object experiencing projectile motion) is the force due to gravity. But how can we define projectile motion in the real world? How are the concepts of projectile motion applicable to daily life? Let us see some real-life examples of projectile motion in two dimensions.

All of us know about basketball. To score a basket, the player jumps a little and throws the ball in the basket. The motion of the ball is in the form of a projectile. Hence, it is referred to as projectile motion. What advantage does jumping give to their chances of scoring a basket? Now apart from basketballs, if we throw a cricket ball, a stone in a river, a javelin throw, an angry bird, a football or a bullet, all these motions have one thing in common. They all show a projectile motion. And that is, the moment they are released, there is only one force acting on them- gravity. It pulls them downwards, thus giving all of them an equal impartial acceleration.

It implies that if something is being thrown in the air, it can easily be predicted how long the projectile will be in the air and at what distance from the initial point it will hit the ground. If the air resistance is neglected, there would be no acceleration in the horizontal direction. This implies that as long as a body is thrown near the surface, the motion of the body can be considered as a two-dimensional motion, with acceleration only in one direction. But how can it be concluded that a body thrown in the air follows a two-dimensional path? To understand this, let us assume a ball that is rolling as shown below:

Figure 1 Motion in one dimension
Now, if the ball is rolled along the path shown, what can we say about the dimension of motion? The most common answer would be that it has an x-component and a y-component, it is moving on a plane, so it must be an example of motion in two dimensions. But it is not correct, as it can be noticed that there exists a line which can completely define the motion of the basketball. Thus, it is an example of motion in one dimension. Therefore, the choice of axis does not alter the nature of the motion itself.

Figure 2 Motion in Plane
Now, if the ball is thrown at some angle as shown, the velocity of the ball has an x-component and a y-component and also a z-component. So, does it mean that it is a three-dimensional motion? It can be seen here that a line cannot define such a motion, but a plane can. Therefore, for a body thrown at any angle, there exists a plane that entirely contains the motion of that body. Thus, it can be concluded that as long as a body is near the surface of the Earth and the air resistance can be neglected, then irrespective of the angle of projection, it will be a two-dimensional motion, no matter how the axes are chosen. If the axes here are rotated in such a way that, then and can completely define the motion of the ball as shown below:

Thus, it can be concluded that the minimum number of coordinates required to completely define the motion of a body determines the dimension of its motion.

## Solved Example For You

### An object is launched at a velocity of 40 m/s in a direction making an angle of 50° upward with the horizontal.

Q1. What is the maximum height reached by the object?

Q2. What is the total flight time (between launch and touching the ground) of the object?

Q3. What is the horizontal range (maximum x above ground) of the object?

Solution:

The velocity components $$V_{x}$$ and $$V_{y}$$ are given by the formula:

In the given problem, $$V_{0} = 40m/s$$, ? = 50° and g is $$9.8\,m^{2}$$

The height of the projectile is given by the component y, and it reaches its maximum value when the component $$V_{y}$$ is equal to zero. That is when the projectile changes from moving upward to moving downward.

Substituting and solving for t, we get

$$t=\frac{V_{0}\sin(?)}{g} = \frac{40\sin (50^{\circ})}{9.8}=3.12\,seconds$$

To find the maximum height, substitute t in the equation y, we get

$$y=\frac{V_0\sin ?}{3.12}-\frac{1}{2}(9.8)(3.12^2)$$

Solving, we get

$$y=\frac{40\sin50^{\circ}}{3.12}-\frac{1}{2}(9.8)(3.12^2)=47.9\,meters$$

The maximum height reached by the object is 47.9 meters

The time of flight is the interval between when the projectile is launched (t1) and when the projectile touches the ground (t2).

Hence,

$$V_0\sin(?)t-\frac{1}{2}gt^2$$

Solve for t

$$t(V_0\sin(?)-(\frac{1}{2}gt)=0$$

Solving, we get two solutions as follows:

$$t=t_1=0$$ and $$t=t_2=2V_0sin(?)/g$$

Time of flight can be calculated as follows:

$$Time\,of\,Flight=2(20)\sin (?)/g=6.25\,seconds$$

Horizontal Range is the horizontal distance given by x at t = t2.

$$Range=x(t_2)=(V_0\cos(?)V_0\sin (?))/g=(V_0)^2\sin(2?)/g=40^2\sin(2(50^{\circ}))/9.8=6.25\,meters$$

Suggested Videos for Projectile Motion

### Projectile Motion in an Inclined Plane

Hope you learned projectile motion, time of flight formula, horizontal range, maximum-height, and the equation of trajectory. Stay tuned with BYJU’S to learn more about projectile motion and its applications.

## Frequently Asked Questions – FAQs

### What is a projectile?

A projectile is any object thrown into space upon which the only acting force is gravity.

### What is a trajectory?

The curved path through which the projectile travels is known as a trajectory.

### Define time of flight.

Time of flight is the measurement of the time taken by an object, particle or wave to travel a distance through a medium.

### Give the time of flight formula?

$$Total time of flight = \frac{2usin\Theta}{g}$$

### State true or false: the minimum number of coordinates required to completely define the motion of a body determines the dimension of its motion.

True.

Test your knowledge on Projectile Motion

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