How to find if hexagons are similar - ACT Math

Card 0 of 18

Question

Two hexagons are similar. If they have the ratio of 4:5, and the side of the first hexagon is 16, what is the side of the second hexagon?

Answer

This type of problem can be solved through using the formula:

$\frac{A_1}{A_2}=\frac{X_1^{2}}{X_2^{2}}$

If the ratio of the hexagons is 4:5, then and . denotes area. The side length of the first hexagon is 16.

Substituting in the numbers, the formula looks like:

$\frac{4}{5}=\frac{16^2}{X_2^2}$

This quickly begins a problem where the second area can be solved for by rearranging all the given information.

$(X_2)^2= 16^2\cdot \frac{5}{4}= 256 \cdot \frac{5}{4}$

$(X_2)^2= \sqrt{320}$

The radical can then by simplified with or without a calculator.

Without a calculator, the 320 can be factored out and simplified:

$X_2= \sqrt {{\color{Red} 16} \cdot {\color{Red} 4} \cdot 5}$

$X_2=8\sqrt{5}$

Compare your answer with the correct one above

Question

The ratio between two similar hexagons is . The side length of the first hexagon is 12 and the second is 17. What must be?

Answer

This kind of problem can be solved for by using the formula:

$\frac{A_1}{A_2}=\frac{X_1^2}{X_2^2}$

where the values are the similarity ratio and the values are the side lengths.

In this case, the problem provides , but not . is denoted as in the question.

There are four variables in this formula, and three of them are provided in the problem. This means that we can solve for () by substituting in all known values and rearranging the formula so it's in terms of .

$\frac{4}{A_2}=\frac{12^2}{17^2}$

$A_2=4 \cdot \frac{17^2}{12^2} = 4\cdot \frac{289}{144}$

$A_2={\color{Blue} 8.0}$

Compare your answer with the correct one above

Question

Two hexagons are similar. If they have the ratio of 4:5, and the side of the first hexagon is 16, what is the side of the second hexagon?

Answer

This type of problem can be solved through using the formula:

$\frac{A_1}{A_2}=\frac{X_1^{2}}{X_2^{2}}$

If the ratio of the hexagons is 4:5, then and . denotes area. The side length of the first hexagon is 16.

Substituting in the numbers, the formula looks like:

$\frac{4}{5}=\frac{16^2}{X_2^2}$

This quickly begins a problem where the second area can be solved for by rearranging all the given information.

$(X_2)^2= 16^2\cdot \frac{5}{4}= 256 \cdot \frac{5}{4}$

$(X_2)^2= \sqrt{320}$

The radical can then by simplified with or without a calculator.

Without a calculator, the 320 can be factored out and simplified:

$X_2= \sqrt {{\color{Red} 16} \cdot {\color{Red} 4} \cdot 5}$

$X_2=8\sqrt{5}$

Compare your answer with the correct one above

Question

The ratio between two similar hexagons is . The side length of the first hexagon is 12 and the second is 17. What must be?

Answer

This kind of problem can be solved for by using the formula:

$\frac{A_1}{A_2}=\frac{X_1^2}{X_2^2}$

where the values are the similarity ratio and the values are the side lengths.

In this case, the problem provides , but not . is denoted as in the question.

There are four variables in this formula, and three of them are provided in the problem. This means that we can solve for () by substituting in all known values and rearranging the formula so it's in terms of .

$\frac{4}{A_2}=\frac{12^2}{17^2}$

$A_2=4 \cdot \frac{17^2}{12^2} = 4\cdot \frac{289}{144}$

$A_2={\color{Blue} 8.0}$

Compare your answer with the correct one above

Question

Two hexagons are similar. If they have the ratio of 4:5, and the side of the first hexagon is 16, what is the side of the second hexagon?

Answer

This type of problem can be solved through using the formula:

$\frac{A_1}{A_2}=\frac{X_1^{2}}{X_2^{2}}$

If the ratio of the hexagons is 4:5, then and . denotes area. The side length of the first hexagon is 16.

Substituting in the numbers, the formula looks like:

$\frac{4}{5}=\frac{16^2}{X_2^2}$

This quickly begins a problem where the second area can be solved for by rearranging all the given information.

$(X_2)^2= 16^2\cdot \frac{5}{4}= 256 \cdot \frac{5}{4}$

$(X_2)^2= \sqrt{320}$

The radical can then by simplified with or without a calculator.

Without a calculator, the 320 can be factored out and simplified:

$X_2= \sqrt {{\color{Red} 16} \cdot {\color{Red} 4} \cdot 5}$

$X_2=8\sqrt{5}$

Compare your answer with the correct one above

Question

The ratio between two similar hexagons is . The side length of the first hexagon is 12 and the second is 17. What must be?

Answer

This kind of problem can be solved for by using the formula:

$\frac{A_1}{A_2}=\frac{X_1^2}{X_2^2}$

where the values are the similarity ratio and the values are the side lengths.

In this case, the problem provides , but not . is denoted as in the question.

There are four variables in this formula, and three of them are provided in the problem. This means that we can solve for () by substituting in all known values and rearranging the formula so it's in terms of .

$\frac{4}{A_2}=\frac{12^2}{17^2}$

$A_2=4 \cdot \frac{17^2}{12^2} = 4\cdot \frac{289}{144}$

$A_2={\color{Blue} 8.0}$

Compare your answer with the correct one above

Question

Two hexagons are similar. If they have the ratio of 4:5, and the side of the first hexagon is 16, what is the side of the second hexagon?

Answer

This type of problem can be solved through using the formula:

$\frac{A_1}{A_2}=\frac{X_1^{2}}{X_2^{2}}$

If the ratio of the hexagons is 4:5, then and . denotes area. The side length of the first hexagon is 16.

Substituting in the numbers, the formula looks like:

$\frac{4}{5}=\frac{16^2}{X_2^2}$

This quickly begins a problem where the second area can be solved for by rearranging all the given information.

$(X_2)^2= 16^2\cdot \frac{5}{4}= 256 \cdot \frac{5}{4}$

$(X_2)^2= \sqrt{320}$

The radical can then by simplified with or without a calculator.

Without a calculator, the 320 can be factored out and simplified:

$X_2= \sqrt {{\color{Red} 16} \cdot {\color{Red} 4} \cdot 5}$

$X_2=8\sqrt{5}$

Compare your answer with the correct one above

Question

The ratio between two similar hexagons is . The side length of the first hexagon is 12 and the second is 17. What must be?

Answer

This kind of problem can be solved for by using the formula:

$\frac{A_1}{A_2}=\frac{X_1^2}{X_2^2}$

where the values are the similarity ratio and the values are the side lengths.

In this case, the problem provides , but not . is denoted as in the question.

There are four variables in this formula, and three of them are provided in the problem. This means that we can solve for () by substituting in all known values and rearranging the formula so it's in terms of .

$\frac{4}{A_2}=\frac{12^2}{17^2}$

$A_2=4 \cdot \frac{17^2}{12^2} = 4\cdot \frac{289}{144}$

$A_2={\color{Blue} 8.0}$

Compare your answer with the correct one above

Question

Two hexagons are similar. If they have the ratio of 4:5, and the side of the first hexagon is 16, what is the side of the second hexagon?

Answer

This type of problem can be solved through using the formula:

$\frac{A_1}{A_2}=\frac{X_1^{2}}{X_2^{2}}$

If the ratio of the hexagons is 4:5, then and . denotes area. The side length of the first hexagon is 16.

Substituting in the numbers, the formula looks like:

$\frac{4}{5}=\frac{16^2}{X_2^2}$

This quickly begins a problem where the second area can be solved for by rearranging all the given information.

$(X_2)^2= 16^2\cdot \frac{5}{4}= 256 \cdot \frac{5}{4}$

$(X_2)^2= \sqrt{320}$

The radical can then by simplified with or without a calculator.

Without a calculator, the 320 can be factored out and simplified:

$X_2= \sqrt {{\color{Red} 16} \cdot {\color{Red} 4} \cdot 5}$

$X_2=8\sqrt{5}$

Compare your answer with the correct one above

Question

The ratio between two similar hexagons is . The side length of the first hexagon is 12 and the second is 17. What must be?

Answer

This kind of problem can be solved for by using the formula:

$\frac{A_1}{A_2}=\frac{X_1^2}{X_2^2}$

where the values are the similarity ratio and the values are the side lengths.

In this case, the problem provides , but not . is denoted as in the question.

There are four variables in this formula, and three of them are provided in the problem. This means that we can solve for () by substituting in all known values and rearranging the formula so it's in terms of .

$\frac{4}{A_2}=\frac{12^2}{17^2}$

$A_2=4 \cdot \frac{17^2}{12^2} = 4\cdot \frac{289}{144}$

$A_2={\color{Blue} 8.0}$

Compare your answer with the correct one above

Question

Two hexagons are similar. If they have the ratio of 4:5, and the side of the first hexagon is 16, what is the side of the second hexagon?

Answer

This type of problem can be solved through using the formula:

$\frac{A_1}{A_2}=\frac{X_1^{2}}{X_2^{2}}$

If the ratio of the hexagons is 4:5, then and . denotes area. The side length of the first hexagon is 16.

Substituting in the numbers, the formula looks like:

$\frac{4}{5}=\frac{16^2}{X_2^2}$

This quickly begins a problem where the second area can be solved for by rearranging all the given information.

$(X_2)^2= 16^2\cdot \frac{5}{4}= 256 \cdot \frac{5}{4}$

$(X_2)^2= \sqrt{320}$

The radical can then by simplified with or without a calculator.

Without a calculator, the 320 can be factored out and simplified:

$X_2= \sqrt {{\color{Red} 16} \cdot {\color{Red} 4} \cdot 5}$

$X_2=8\sqrt{5}$

Compare your answer with the correct one above

Question

The ratio between two similar hexagons is . The side length of the first hexagon is 12 and the second is 17. What must be?

Answer

This kind of problem can be solved for by using the formula:

$\frac{A_1}{A_2}=\frac{X_1^2}{X_2^2}$

where the values are the similarity ratio and the values are the side lengths.

In this case, the problem provides , but not . is denoted as in the question.

There are four variables in this formula, and three of them are provided in the problem. This means that we can solve for () by substituting in all known values and rearranging the formula so it's in terms of .

$\frac{4}{A_2}=\frac{12^2}{17^2}$

$A_2=4 \cdot \frac{17^2}{12^2} = 4\cdot \frac{289}{144}$

$A_2={\color{Blue} 8.0}$

Compare your answer with the correct one above

Question

Two hexagons are similar. If they have the ratio of 4:5, and the side of the first hexagon is 16, what is the side of the second hexagon?

Answer

This type of problem can be solved through using the formula:

$\frac{A_1}{A_2}=\frac{X_1^{2}}{X_2^{2}}$

If the ratio of the hexagons is 4:5, then and . denotes area. The side length of the first hexagon is 16.

Substituting in the numbers, the formula looks like:

$\frac{4}{5}=\frac{16^2}{X_2^2}$

This quickly begins a problem where the second area can be solved for by rearranging all the given information.

$(X_2)^2= 16^2\cdot \frac{5}{4}= 256 \cdot \frac{5}{4}$

$(X_2)^2= \sqrt{320}$

The radical can then by simplified with or without a calculator.

Without a calculator, the 320 can be factored out and simplified:

$X_2= \sqrt {{\color{Red} 16} \cdot {\color{Red} 4} \cdot 5}$

$X_2=8\sqrt{5}$

Compare your answer with the correct one above

Question

The ratio between two similar hexagons is . The side length of the first hexagon is 12 and the second is 17. What must be?

Answer

This kind of problem can be solved for by using the formula:

$\frac{A_1}{A_2}=\frac{X_1^2}{X_2^2}$

where the values are the similarity ratio and the values are the side lengths.

In this case, the problem provides , but not . is denoted as in the question.

There are four variables in this formula, and three of them are provided in the problem. This means that we can solve for () by substituting in all known values and rearranging the formula so it's in terms of .

$\frac{4}{A_2}=\frac{12^2}{17^2}$

$A_2=4 \cdot \frac{17^2}{12^2} = 4\cdot \frac{289}{144}$

$A_2={\color{Blue} 8.0}$

Compare your answer with the correct one above

Question

Two hexagons are similar. If they have the ratio of 4:5, and the side of the first hexagon is 16, what is the side of the second hexagon?

Answer

This type of problem can be solved through using the formula:

$\frac{A_1}{A_2}=\frac{X_1^{2}}{X_2^{2}}$

If the ratio of the hexagons is 4:5, then and . denotes area. The side length of the first hexagon is 16.

Substituting in the numbers, the formula looks like:

$\frac{4}{5}=\frac{16^2}{X_2^2}$

This quickly begins a problem where the second area can be solved for by rearranging all the given information.

$(X_2)^2= 16^2\cdot \frac{5}{4}= 256 \cdot \frac{5}{4}$

$(X_2)^2= \sqrt{320}$

The radical can then by simplified with or without a calculator.

Without a calculator, the 320 can be factored out and simplified:

$X_2= \sqrt {{\color{Red} 16} \cdot {\color{Red} 4} \cdot 5}$

$X_2=8\sqrt{5}$

Compare your answer with the correct one above

Question

The ratio between two similar hexagons is . The side length of the first hexagon is 12 and the second is 17. What must be?

Answer

This kind of problem can be solved for by using the formula:

$\frac{A_1}{A_2}=\frac{X_1^2}{X_2^2}$

where the values are the similarity ratio and the values are the side lengths.

In this case, the problem provides , but not . is denoted as in the question.

There are four variables in this formula, and three of them are provided in the problem. This means that we can solve for () by substituting in all known values and rearranging the formula so it's in terms of .

$\frac{4}{A_2}=\frac{12^2}{17^2}$

$A_2=4 \cdot \frac{17^2}{12^2} = 4\cdot \frac{289}{144}$

$A_2={\color{Blue} 8.0}$

Compare your answer with the correct one above

Question

Two hexagons are similar. If they have the ratio of 4:5, and the side of the first hexagon is 16, what is the side of the second hexagon?

Answer

This type of problem can be solved through using the formula:

$\frac{A_1}{A_2}=\frac{X_1^{2}}{X_2^{2}}$

If the ratio of the hexagons is 4:5, then and . denotes area. The side length of the first hexagon is 16.

Substituting in the numbers, the formula looks like:

$\frac{4}{5}=\frac{16^2}{X_2^2}$

This quickly begins a problem where the second area can be solved for by rearranging all the given information.

$(X_2)^2= 16^2\cdot \frac{5}{4}= 256 \cdot \frac{5}{4}$

$(X_2)^2= \sqrt{320}$

The radical can then by simplified with or without a calculator.

Without a calculator, the 320 can be factored out and simplified:

$X_2= \sqrt {{\color{Red} 16} \cdot {\color{Red} 4} \cdot 5}$

$X_2=8\sqrt{5}$

Compare your answer with the correct one above

Question

The ratio between two similar hexagons is . The side length of the first hexagon is 12 and the second is 17. What must be?

Answer

This kind of problem can be solved for by using the formula:

$\frac{A_1}{A_2}=\frac{X_1^2}{X_2^2}$

where the values are the similarity ratio and the values are the side lengths.

In this case, the problem provides , but not . is denoted as in the question.

There are four variables in this formula, and three of them are provided in the problem. This means that we can solve for () by substituting in all known values and rearranging the formula so it's in terms of .

$\frac{4}{A_2}=\frac{12^2}{17^2}$

$A_2=4 \cdot \frac{17^2}{12^2} = 4\cdot \frac{289}{144}$

$A_2={\color{Blue} 8.0}$

Compare your answer with the correct one above

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