How to Calculate Center of Gravity

The center of gravity (CG) is the center to an object's weight distribution, where the force of gravity can be considered to act. This is the point where the object is in perfect balance, no matter how turned or rotated around that point.^{[1]XResearch source} If you want to know how to calculate the center of gravity of an object, then you have to find the weight of the object: and any objects on it, locate the datum, and plug the known quantities into the equation for calculating the center of gravity. If you want to know how to calculate the center of gravity, just follow these steps.

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Method 1

Method 1 of 4:

Identify the Weight

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When you're calculating the center of gravity, the first thing you should do is to find the weight of the object. Let's say that you're calculating the weight of a see-saw that has a weight of 30 lbs. Since it's a symmetrical object, its center of gravity will be exactly in its center if it's empty. But if the see-saw has people of different weights sitting on it, then the problem is a bit more complicated.^{[2]XResearch source}
To find the center of gravity of the see-saw with two children on it, you'll need to individually find the weight of the children on it.^{[3]XResearch source} The first child has a weight of 40 lbs. and the second child's is 60 lbs.

Method 2

Method 2 of 4:

Determine the Datum

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The datum is an arbitrary starting point placed on one end of the see-saw.^{[4]XResearch source} You can place the datum on one end of the see-saw or the other. Let's say the see-saw is 16 feet long. Let's place the datum on the left side of the see-saw, close to the first child.
2
Measure the datum's distance from the center of the main object as well as from the two additional weights. Let's say the children are each sitting 1 foot away from each end of the see-saw. The center of the see-saw is the midpoint of the see-saw, or at 8 feet, since 16 feet divided by 2 is 8. Here are the distances from the center of the main object and the two additional weights form the datum:
- Center of see-saw = 8 feet away from datum.
- Child 1 = 1 foot away from datum
- Child 2 = 15 feet away from datum

Method 3

Method 3 of 4:

Find the Center of Gravity

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1
Multiply each object's distance from the datum by its weight to find its moment. This gives you the moment for each object. Here's how to multiply each object's distance from the datum by its weight:
- The see-saw: 30 lb. x 8 ft. = 240 ft. x lb.
- Child 1 = 40 lb. x 1 ft. = 40 ft. x lb.
- Child 2 = 60 lb. x 15 ft. = 900 ft. x lb.
Simply do the math: 240 ft. x lb. + 40 ft. x lb. + 900 ft. x lb = 1180 ft. x lb. The total moment is 1180 ft. x lb.
Find the sum of the weights of the seesaw, the first child, and the second child. To do this, add up the weights: 30 lbs. + 40 lbs. + 60 lbs. = 130 lbs.
4
Divide the total moment by the total weight. This will give you the distance from the datum to the center of gravity of the object. To do this, simply divide 1180 ft. x lb. by 130 lbs.
- 1180 ft. x lb. ÷ 130 lbs = 9.08 ft.
- The center of gravity is 9.08 feet from the datum, or measured 9.08 feet from the end of the left side of the see-saw, which is where the datum was placed.

Method 4

Method 4 of 4:

Checking Your Answer

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1
Find the center of gravity in the diagram. If the center of gravity you found is outside of the system of objects, you have the wrong answer.^{[5]XResearch source} You may have measured the distances from more than one point. Try again with just one datum.
- For example, for people sitting on a seesaw, the center of gravity has to be somewhere on the seesaw, not to the left or right of the seesaw. It does not have to be directly on a person.
- This is still true with problems in two dimensions. Draw a square just large enough to fit all of the objects in your problem. The center of gravity must be inside this square.
If you picked one end of the system as your datum, a tiny answer puts the center of gravity right next to one end. This can be the right answer, but it's often the sign of a mistake. When you calculated the moment, did you multiply the weight and distance together? That's the correct way to find the moment. If you accidentally added them together instead, you'll usually get a much smaller answer.
Every system only has a single center of gravity. If you find more than one, you might have skipped the step where you add all the moments together. The center of gravity is the total moment divided by total weight. You do not need to divide each moment by each weight, which only tells you the position of each object.
4
Check your datum if your answer is off by a whole number. The answer to our example is 9.08 ft. Let's say you try it and get the answer 1.08 ft., 7.08 ft, or another number ending in ".08." This most likely happened because we chose the left end of the seesaw as the datum, while you chose the right end or some other point an integer distance from our datum. Your answer is actually correct no matter which datum you choose! You just need to remember that the datum is always at x = 0. Here's an example:
- The way we solved it, the datum is at the left end of the seesaw. Our answer was 9.08 ft, so our center of mass is 9.08 ft from the datum at the left end.
- If you pick a new datum 1 ft from the left end, you get the answer 8.08 ft for the center of mass. The center of mass is 8.08 ft from the new datum, which is 1 ft from the left end. The center of mass is 8.08 + 1 = 9.08 ft from the left end, the same answer we got before.
- (Note: When measuring distance, remember that distances to the left of the datum are negative, while distances to the right are positive.)
5
Make sure all your measurements are in straight lines. Let's say you see another "kids on the seesaw" example, but one kid is much taller than the other, or one kid is hanging underneath the seesaw instead of sitting on top. Ignore the difference and take all your measurements along the straight line of the seesaw. Measuring distances at angles will lead to answers that are close but slightly off.
- For seesaw problems, all you care about is where the center of gravity is along the left-right line of the seesaw. Later, you might learn more advanced ways to calculate the center of gravity in two dimensions.

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Why do we calculate centers of gravity?
Danoyachtcapt
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Center of gravity (CG) is very important, especially in aircraft and other vehicles like cars and trains. The Vehicle has to be designed so the CG is within certain limits so the vehicle will be well-balanced while in motion.
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I have to find the center of gravity for a 1310 mm length MS Steel. How can I go about doing that?
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Balance it on a knife edge and record the position by marking the edge. Then, turn the object approx. 30 degrees and re-balance it on the knife edge. Record the position by marking the edge -- you should now have 2 intersecting lines, and the intersection point will give you the center of gravity.
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Why is the determination of the center of gravity necessary, and where might I apply it in real life?
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It's more useful in certain sports and careers. If you are an engineer, you don't want whatever you're building to be off center. In sports such as gymnastics, it's easier to do harder moves if you know where your center of balance is.
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The definition for center of gravity of a general mass distribution is (∫ r dW/∫ dW) where dW is the differential of weight, r the position vector and the integrals are to be interpreted as Stieltjes integrals over the entire body. They can however be expressed as more conventional Riemann or Lebesgue volume integrals for distributions that admit a density function. Starting with this definition all properties of CG including the ones used in this article may be derived from properties of Stieltjes integrals.
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To find the CG of a two dimensional object, use the formula Xcg = ∑xW/∑W to find the CG along the x-axis and Ycg = ∑yW/∑W to find the CG along the y-axis. The point at which they intersect is the center of gravity.
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To find the distance a person needs to move to balance the see-saw over the fulcrum, use the formula: (weight moved) / (total weight) = (distance CG moves) / (distance weight is moved). This formula can be rewritten to show that the distance the weight (person) needs to move equals the distance between the CG and the fulcrum times the weight of the person divided by the total weight. So the first kid needs to move -1.08ft * 40lb / 130lbs = -.33ft or -4in. (toward the edge of the see-saw). Or, the second kid needs to move -1.08ft * 130lb / 60lbs = -2.33ft or -28in. (toward the center of the see-saw).
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Warnings

Trying to blindly apply this mechanical technique without understanding the theory may result in errors. Understand the laws/theories behind it first.
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