Difference between revisions of "Find the Area of a Kite"
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| − | A kite is a type of a quadrilateral that has two pairs of equal, adjacent sides.<ref>http://www.mathopenref.com/kite.html</ref> Kites can take the traditional look of a flying kite, but a kite can also be a rhombus or a square.<ref>https://www.mathsisfun.com/geometry/kite.html/</ref> No matter what a kite looks like, the methods for finding the area will be the same. If you know the length of the diagonals, you can find the area through simple algebra. You can also use trigonometry to find the area, if you know the side and angle measurements of the figure. | + | A kite is a type of a quadrilateral that has two pairs of equal, adjacent sides.<ref name="rf1">http://www.mathopenref.com/kite.html</ref> Kites can take the traditional look of a flying kite, but a kite can also be a rhombus or a square.<ref name="rf2">https://www.mathsisfun.com/geometry/kite.html/</ref> No matter what a kite looks like, the methods for finding the area will be the same. If you know the length of the diagonals, you can find the area through simple algebra. You can also use trigonometry to find the area, if you know the side and angle measurements of the figure. |
[[Category:Calculating Volume and Area]] | [[Category:Calculating Volume and Area]] | ||
==Steps== | ==Steps== | ||
===Using the Diagonals to Find the Area=== | ===Using the Diagonals to Find the Area=== | ||
| − | #Set up the formula for the area of a kite, given two diagonals. The formula is <math>A = \frac{xy}{2}</math>, where <math>A</math> equals the area of the kite, and <math>x</math> and <math>y</math> equal the lengths of the diagonals of the kite.<ref>https://www.mathsisfun.com/geometry/kite.html</ref> | + | #Set up the formula for the area of a kite, given two diagonals. The formula is <math>A = \frac{xy}{2}</math>, where <math>A</math> equals the area of the kite, and <math>x</math> and <math>y</math> equal the lengths of the diagonals of the kite.<ref name="rf3">https://www.mathsisfun.com/geometry/kite.html</ref> |
| − | #Plug the lengths of the diagonals into the formula. A diagonal is a straight line that runs from one vertex to the vertex on the opposite side.<ref>http://www.mathopenref.com/diagonal.html</ref> You should either be given the length of the diagonals, or be able to measure them. If you don’t know the length of the diagonals, you cannot use this method. | + | #Plug the lengths of the diagonals into the formula. A diagonal is a straight line that runs from one vertex to the vertex on the opposite side.<ref name="rf4">http://www.mathopenref.com/diagonal.html</ref> You should either be given the length of the diagonals, or be able to measure them. If you don’t know the length of the diagonals, you cannot use this method. |
#*For example, if a kite has two diagonals measuring 7 inches and 10 inches, your formula will look like this:<math>A = \frac{7 \times 10}{2}</math>. | #*For example, if a kite has two diagonals measuring 7 inches and 10 inches, your formula will look like this:<math>A = \frac{7 \times 10}{2}</math>. | ||
#Multiply the lengths of the diagonals. The product becomes the new numerator in the area equation. | #Multiply the lengths of the diagonals. The product becomes the new numerator in the area equation. | ||
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===Using an Angle and Two Sides to Find the Area=== | ===Using an Angle and Two Sides to Find the Area=== | ||
| − | #Set up the formula for the area of a kite. This formula works if you are given two non-congruent side lengths and the size of the angle between those two sides. The formula is <math>A = ab \sin C</math>, where <math>A</math> equals the area of the kite, <math>a</math> and <math>b</math> equal the non-congruent side lengths of the kite, and <math>C</math> equals the size of the angle between sides <math>a</math> and <math>b</math>.<ref>http://www.mathopenref.com/kitearea.html</ref> | + | #Set up the formula for the area of a kite. This formula works if you are given two non-congruent side lengths and the size of the angle between those two sides. The formula is <math>A = ab \sin C</math>, where <math>A</math> equals the area of the kite, <math>a</math> and <math>b</math> equal the non-congruent side lengths of the kite, and <math>C</math> equals the size of the angle between sides <math>a</math> and <math>b</math>.<ref name="rf5">http://www.mathopenref.com/kitearea.html</ref> |
#*Make sure you are using two non-congruent side lengths. A kite has two pairs of congruent sides. You need to use one side from each pair. Make sure the angle measurement you use is the angle between these two sides. If you do not have all of this information, you cannot use this method. | #*Make sure you are using two non-congruent side lengths. A kite has two pairs of congruent sides. You need to use one side from each pair. Make sure the angle measurement you use is the angle between these two sides. If you do not have all of this information, you cannot use this method. | ||
#Plug the length of the sides into the formula. This information should be given, or you should be able to measure them. Remember that you are using non-congruent sides, so each side should have a different length. | #Plug the length of the sides into the formula. This information should be given, or you should be able to measure them. Remember that you are using non-congruent sides, so each side should have a different length. | ||
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#Plug the angle measurement into the formula. Make sure you are using the angle between the two non-congruent sides. | #Plug the angle measurement into the formula. Make sure you are using the angle between the two non-congruent sides. | ||
#*For example, if the angle measurement is <math>150^\circ</math>, your formula will look like this: <math>A = 300 \sin (150)</math>. | #*For example, if the angle measurement is <math>150^\circ</math>, your formula will look like this: <math>A = 300 \sin (150)</math>. | ||
| − | #Find the sine of the angle. To do this, you can use a calculator, or use a trigonometry chart.<ref>http://www.mathmistakes.info/facts/TrigFacts/learn/vals/sum.html</ref> | + | #Find the sine of the angle. To do this, you can use a calculator, or use a trigonometry chart.<ref name="rf6">http://www.mathmistakes.info/facts/TrigFacts/learn/vals/sum.html</ref> |
#*For example, the sine of a 150 degree angle is .5, so your formula will look like this: <math>A = 300 (.5)</math>. | #*For example, the sine of a 150 degree angle is .5, so your formula will look like this: <math>A = 300 (.5)</math>. | ||
#Multiply the product of the sides by the sine of the angle. This result will be the area of the kite, in square units. | #Multiply the product of the sides by the sine of the angle. This result will be the area of the kite, in square units. | ||
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===Using the Area to Find a Missing Diagonal=== | ===Using the Area to Find a Missing Diagonal=== | ||
| − | #Set up the formula for the area of a kite, given two diagonals. The formula is <math>A = \frac{xy}{2}</math>, where <math>A</math> equals the area of the kite, and <math>x</math> and <math>y</math> equal the lengths of the diagonals of the kite.<ref | + | #Set up the formula for the area of a kite, given two diagonals. The formula is <math>A = \frac{xy}{2}</math>, where <math>A</math> equals the area of the kite, and <math>x</math> and <math>y</math> equal the lengths of the diagonals of the kite.<ref name="rf3" /> |
#Plug the area of the kite into the formula. This information should be given to you. Make sure you are substituting for <math>A</math>. | #Plug the area of the kite into the formula. This information should be given to you. Make sure you are substituting for <math>A</math>. | ||
#*For example, if your kite has an area of 35 square inches, your formula will look like this: <math>35 = \frac{xy}{2}</math>. | #*For example, if your kite has an area of 35 square inches, your formula will look like this: <math>35 = \frac{xy}{2}</math>. | ||
