Vertical Motion under Gravity for KS4

The Earth attracts us with a force, which we call gravity or gravitational force. If we stand on the ground, we feel the weight with which we act on the ground and the force with which the ground acts on us.

What if we jump off a plane?

In this case, however, we do not have a floor under our feet to hold us, so we move because of the weight. This movement, as long as the air resistance is negligible, is called a free fall.

What if two differently heavy friends jump out at the same time? Will they fall just as fast? We wonder if the speed of fall depends on mass. Let's do a simple experiment.

Due to the speed of fall, it is not possible to determine with the naked eyes what this motion is. At times, even measurements to investigate the laws of free fall were also very difficult. The problem was inaccurate instruments for measuring short times.

As a result, many believed that free fall was a steady movement. Today we know that this is uniformly accelerated motion with the acceleration we will determine below.

In this chapter, we will learn how to calculate the speed, distance, and time of a body’s fall. In doing so, we will neglect the influence of air resistance.

Today, observing falling bodies is much easier than in older times. We have fast and accurate instruments for measuring time and speed. We can also help ourselves with a camera or camcorder. Thus, a free fall can be observed during slow-motion playback.

Let’s experiment with a tennis ball and calculate its acceleration at free fall.

The resulting acceleration is the free fall acceleration or gravitational acceleration. Let us denote it by . The more accurate value of gravitational acceleration is:

The value of the free fall acceleration above applies only to the fall on the surface of the Earth planet. Accurate measurements would show that this acceleration varies even slightly in different parts of the Earth. If we rise above the Earth's surface with a spacecraft, the acceleration of free fall will be smaller.

Each celestial body has a different gravitational acceleration. However, the following applies:

The free fall is therefore uniformly accelerated motion with an initial velocity of zero. We assumed that we were just dropping the object to fall freely. However, if we throw it down, we must also consider the initial speed.

In the tasks we will take an approximation for acceleration due to gravity:

In the calculations, we will use a velocity-time graph.

The speed increases uniformly with time. It increases by every second. The instantaneous speed is calculated by the equation:

The object falls to the ground during time . Just before it falls to the ground, its speed is at its highest. We call it final velocity and denote it by :

In the chapter Uniformly Accelerated Motion, we learned that the distance (height of fall ) is equal to the area of the figure below the velocity-time graph. In our case, this is the shaded part of the graph above. However, it can also be calculated with a known average speed of fall.

From the given height , we can calculate the fall time . We start from the equation for the distance (height):

Let's obtain the expression for the fall time from the formula above:

Using the obtained equation, we could also calculate the final velocity at a given height of fall:

Let's look at an example where we calculate the time of fall from a given height.