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Learn the equation to find the terminal velocity of a falling object
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Ever wonder why skydivers eventually reach a maximum speed when falling, even though the force of gravity in a vacuum will cause an object to continually accelerate? A falling object will reach a constant speed when there is a restraining force, such as drag from the air. The force applied by gravity near to a massive body is mostly constant, but forces like air resistance increase the faster the falling object goes. If allowed to free fall for long enough, a falling object will reach a speed where the force of the drag will become equal the force of gravity, and the two will cancel each other out, causing the object to fall at that same speed until it hits the ground. This is called terminal velocity.

Terminal Velocity Formula

Use the terminal velocity formula, v = the square root of ((2*m*g)/(ρ*A*C)).

  1. m = mass of the falling object
  2. g = the acceleration due to gravity
  3. ρ = the density of the fluid the object is falling through
  4. A = the projected area of the object
  5. C = the drag coefficient
Method 1
Method 1 of 3:

Solving for Terminal Velocity

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  1. Plug the following values into that formula to solve for v, terminal velocity. [1]
    • m = mass of the falling object
    • g = the acceleration due to gravity. On Earth this is approximately 9.8 meters per second squared.
    • ρ = the density of the fluid the object is falling through.
    • A = the projected area of the object. This means the area of the object if you projected it onto a plane that was perpendicular to the direction the object is moving.
    • C = the drag coefficient. This number depends on the shape of the object. The more streamlined the shape, the lower the coefficient. You can look up some approximate drag coefficients.
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Method 2
Method 2 of 3:

Finding the Gravitational Force

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  1. This should be measured in grams or kilograms, in the metric system. [2]
    • If you are using the imperial system, remember that pounds is not actually a unit of mass, but of force. The unit of mass in the imperial system is the pound-mass (lbm), which under the gravitational force on the surface of the earth would experience a force of 32 pound-force (lbf). For example, if a person weighs 160 pounds on earth, that person is actually feeling 160 lbf, but their mass is 5 lbm.
  2. [3] Close enough to the earth to encounter air resistance, this acceleration is 9.8 meters per second squared, or 32 feet per second squared. [4]
  3. The force with which the falling object is being pulled down equals the object's mass times acceleration due to gravity, or F = MA. This number, multiplied by two, goes in the top of the terminal velocity formula. [5]
    • In the imperial system, this is the lbf of the object, the number that is commonly called weight. It is more properly the mass in lbm times 32 feet per second squared. In the metric system, the force is the mass in grams times 9.8 meters per second squared.
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Method 3
Method 3 of 3:

Determining the Drag Force

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  1. For an object falling through the Earth's atmosphere, the density is going to change based on the altitude and the temperature of the air. This makes calculating terminal velocity of a falling object especially difficult, as the density of the air will change as the object loses altitude. However, you can look up approximate air densities in textbooks and other references. [6]
    • As a rough guide, the density of air at sea level when the temperature is 15 °C is 1.225 kg/m3.
  2. This number is based on how streamlined the object is. Unfortunately it is a very complex number to compute, and involves making certain scientific assumptions. Do not attempt to calculate drag coefficient yourself without the help of a wind tunnel and some serious aerodynamic math. Instead look up an approximation based on a similarly shaped object. [7]
  3. The last variable you need to know is the sectional area being presented by the object to the medium. Imagine the silhouette of the falling object seeing when looking up from directly beneath it. That shape, projected onto a plane, is the projected area. Again, this is a difficult value to calculate with anything but simple geometric objects. [8]
  4. If you know the velocity of the object, but not the drag force, you can use the formula to calculate the drag force. [9] This is (C*ρ*A*(v^2))/2.
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Community Q&A

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  • Question
    If the drop is falling freely with the terminal velocity, then what will happen?
    Community Answer
    It will continue to fall at that speed without accelerating until it hits something.
  • Question
    What is base jumping?
    Community Answer
    B.A.S.E is an acronym for Buildings, Antennas, Spans, and Earth. BASE jumping is an extreme sport in which you jump off these various forms and deploy a small parachute.
  • Question
    What speed is terminal velocity?
    Ben Halford
    Community Answer
    Depends on the weight, shape, and density of the air. Hence, you have a way to calculate it, as it is not a constant.
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      Tips

      • Without an open parachute, a skydiver would strike the ground at about 130 mph (210 km/h).
      • Terminal velocity will actually change slightly during the free fall. Gravity goes up slightly as the object gets closer to the center of the earth, but the amount is negligible. Density of the medium will rise as the object gets down deeper into the medium. This is a much more noticeable effect. A skydiver will actually slow down as the fall proceeds because the atmosphere gets increasingly thick as altitude drops.
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      About This Article

      Article Summary X

      To calculate terminal velocity, start by multiplying the mass of the object by 2. Then, multiply that number by the acceleration of the object due to gravity and write your answer down. Next, multiply the density of the fluid the object is falling through by the projected area of the object. Then, multiply that number by the drag coefficient. Finally, divide your first answer by your second answer and take the square root of that number to find the terminal velocity. To learn how to find gravitational force and drag force, keep reading!

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