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Gravity and Gravitation

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Horizontal Motion Unaffected by Gravity

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Thrown downward

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Thrown upward

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Velocity Equations for Objects Projected Upward

Distance Equations for Objects Projected Upward

Time Equations for Objects Projected Upward

Gravity applications

Effect of Gravity on Sideways Motion

Effect of Gravity on an Artillery Projectile

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SfC Home > Physical Science > Physics > Gravity >

Explanation of the Effect of Gravity on Sideways Motion - Succeed in Understanding Physics. Also refer to physical science, Earth, parallel, propel, throw, ball, gun, shoot, bullet, rate, acceleration, fall, Ron Kurtus, School for Champions. Copyright © Restrictions

Effect of Gravity on Sideways Motion

by Ron Kurtus (revised 15 May 2010)

When an object is moving sideways or parallel to the Earth's surface at a constant velocity, the effect of gravity on the object is independent of the object's lateral movement.

In other words, an object moving sideways will fall at the same rate as one that is simply dropped. You can derive the equation for the distance the object would travel before it hit the ground from the gravity equations for falling objects. An exception is if the object moves so far that the curvature of the Earth comes into play during its fall to the ground.

Questions you may have include:

• What is the pull of gravity for a moving object?
• At what rate do objects moving sideways and stationary fall?
• When happens when you shoot a gun parallel to the ground?

This lesson will answer those questions. There is a mini-quiz near the end of the lesson.

Useful tools: Metric-English Conversion | Scientific Calculator.

Pull of gravity same for moving object

Since the Earth is a sphere with a circumference of approximately 40,000 km or 25,000 mi, the ground can be considered level or flat—not counting hills and valleys—for short distances of several kilometers or several miles.

Gravity acts on objects in a direction that is perpendicular to level ground. This means that, if an object is moving parallel to the ground, the force of gravity is only pulling on the object in a downward direction. The force is not affected by sideways motion and simply pulls the object down at the same rate as if it was stationary.

This rule is explained in detail in Horizontal Motion Unaffected by Gravity.

Pull of gravity downward is the same for moving and stationary objects

Hits ground at same time

If you would project or throw an object exactly parallel to the Earth's surface, the sideways motion of the object would have no effect on how gravity acts on it. In other words, the object would drop at the same rate as an object dropped from the identical height. The time it would take either object to hit the ground would be the same.

Ball thrown sideways falls at the same rate as dropped ball

Simple experiment

You can try a simple experiment to verify this phenomenon. Place a coin on the edge of a table or desk and hold another coin at the same height. With one hand flick the coin on the table across the room. At the same time, drop the other coin. You will hear that they hit the floor at just about the same time.

Derivation of equation for distance traveled

You can find the distance an object projected sideways from the following derivation. First, consider the standard distance-velocity equation:

x = v_ht

where

• x is the horizontal distance traveled in feet (ft) or meters (m)
• v_h is the initial sideways or horizontal velocity in ft/s or m/s
• t is the time until the object hits the ground in seconds (s)

The equation for the time a falling object takes is:

t = √(2y/g)

where

• y is the distance the object has fallen from its starting point in
  m or ft
• g is the acceleration due to gravity (32 ft/s² or 9.8 m/s²)

(See Gravity Time Equations for Falling Objects for information on the equation.)

Thus, the distance the object travels, as a function of the initial velocity and the height is:

x = v_h√(2y/g)

Travels in parabolic curve

You can see that object travels in a parabolic path by squaring both sides of the equation, with x as the vertical axis and y as the horizontal axis:

x² = (2v_h²/g)y

This results in the equation of a parabola, where the constant k = 2v_h²/g:

x² = ky

Shooting a bullet

If you would shoot a bullet from a gun exactly parallel to the Earth's surface, the motion of the bullet would have no effect on how gravity acts on the bullet. In other words, the bullet would drop at the same rate as a stationary object.

Dropped bullet and shot bullet hit the ground at the same time

Many people don't believe that if you held a rifle or handgun parallel to the ground and at the same time you shot the bullet, you dropped another bullet from the same height, both bullets would both hit the ground at the same time. However, it is a fact.

Exception

An exception to this phenomenon would be if the bullet or object was able to travel so many miles or kilometers that the curvature of the Earth came into play. In such a situation, the bullet would take slightly longer to hit the ground, because the distance to the ground was greater due to the Earth's curvature.

Example

If you shot a bullet at 900 m/s from a rifle that was 1.5 m above the ground, how far would the bullet fly until it hit the ground? Discount air resistance and assume the rifle is parallel to the ground.

Solution

x = v_ix√(2y/g)

x = (900 m/s)√[2*(1.5 m)/(9.8 m/s²)]

x = (900 m/s)√(0.306 s²)

x = (900 m/s)(0.553 s)

x = 498 m or 1634 ft

Summary

An object moving sideways or parallel to the Earth's surface will fall at the same rate as one that is simply dropped. The equation for the distance the object travels before it hits the ground can be derived from the gravity equations for falling objects. An exception is if the object moves so fast or far that the curvature of the Earth comes into play during its fall to the ground.

See the Side Menu for more Gravity and Gravitation topics

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Be curious about the world around you

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Resources

The following resources provide information on this subject:

Websites

Acceleration due to Gravity Calculations - from Western Washington University

Gravity and Gravitation Resources

Books

Top-rated books on Simple Gravity Science

Top-rated books on Advanced Gravity Physics

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Mini-quiz to check your understanding

1. Why doesn't gravity affect an object moving sideways differently?

Gravity pulls perpendicular to the ground, so sideways motion is not affected

Sideways motion is too fast for gravity to affect it

Gravity pulls sideways motion faster than stationary motion

2. After 2 seconds, which object is falling downward faster?

The stationary object falls faster because gravity affects it more

The object moving sideways falls downward faster because of less friction

They both are moving at the same downward velocity after 2 seconds

3. If two balls are thrown sideways at different velocities, will they hit the ground at the same time?

Yes, because sideways velocities do not affect the rate the balls fall

No, because the harder you throw a ball, the less gravity affects it

It depends whether the balls are the same weight or not

If you got all three correct, you are on your way to becoming a Champion in Physics. If you had problems, you had better look over the material again.

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Effect of Gravity on Sideways Motion