A Triangle Has Vertices At \[$ A (-2,4), B (-2,8) \$\], And \[$ C (6,4) \$\]. If \[$ A^{\prime} \$\] Has Coordinates Of \[$ (-0.25,0.5) \$\] After The Triangle Has Been Dilated With A Center Of Dilation About The Origin,

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Understanding the Concept of Dilation

Dilation is a transformation that changes the size of a figure. In this case, we are dealing with a dilation with a center of dilation about the origin. This means that the origin (0, 0) is the fixed point around which the dilation occurs. The scale factor of the dilation is the ratio of the distance between the image and the center of dilation to the distance between the preimage and the center of dilation.

Calculating the Scale Factor

To find the scale factor, we need to determine the distance between the preimage point A (-2, 4) and the center of dilation (0, 0). We can use the distance formula:

$$d = \sqrt{(x_2 - x_1)^2 + (y_2 - y_1)^2}$$

Plugging in the values, we get:

$$d = \sqrt{(-2 - 0)^2 + (4 - 0)^2}$$

$$d = \sqrt{4 + 16}$$

$$d = \sqrt{20}$$

Now, we need to find the distance between the image point A' (-0.25, 0.5) and the center of dilation (0, 0). Using the distance formula again, we get:

$$d' = \sqrt{(-0.25 - 0)^2 + (0.5 - 0)^2}$$

$$d' = \sqrt{0.0625 + 0.25}$$

$$d' = \sqrt{0.3125}$$

The scale factor is the ratio of the distance between the image and the center of dilation to the distance between the preimage and the center of dilation:

$$k = \frac{d'}{d} = \frac{\sqrt{0.3125}}{\sqrt{20}}$$

$$k = \frac{\sqrt{0.3125}}{\sqrt{20}} \times \frac{\sqrt{20}}{\sqrt{20}}$$

$$k = \frac{\sqrt{0.3125 \times 20}}{\sqrt{20 \times 20}}$$

$$k = \frac{\sqrt{6.25}}{20}$$

$$k = \frac{2.5}{20}$$

$$k = 0.125$$

Finding the Coordinates of the Image Point

Now that we have the scale factor, we can find the coordinates of the image point A'. We can use the formula:

$$A' = (k \times x, k \times y)$$

Plugging in the values, we get:

$$A' = (0.125 \times -2, 0.125 \times 4)$$

$$A' = (-0.25, 0.5)$$

This confirms that the coordinates of the image point A' are indeed (-0.25, 0.5).

Understanding the Effect of Dilation on the Triangle

The dilation with a center of dilation about the origin has reduced the size of the triangle. The scale factor of 0.125 means that the triangle has been shrunk by a factor of 0.125. This means that the lengths of the sides of the triangle have been reduced by a factor of 0.125.

Conclusion

In this article, we have discussed the concept of dilation and how it affects the size of a figure. We have calculated the scale factor of the dilation and used it to find the coordinates of the image point A'. We have also understood the effect of dilation on the triangle and how it reduces the size of the triangle.

Applications of Dilation

Dilation has many applications in mathematics and real-world scenarios. Some examples include:

• Geometry: Dilation is used to create similar figures and to study the properties of similar figures.
• Art: Dilation is used in art to create different sizes and proportions of objects.
• Architecture: Dilation is used in architecture to design buildings and structures that are proportional to the surrounding environment.
• Engineering: Dilation is used in engineering to design machines and mechanisms that are proportional to the desired output.

Real-World Examples of Dilation

• Photography: When a photograph is taken, the camera lens can be adjusted to create a dilation effect, making the subject appear larger or smaller.
• Optics: Dilation is used in optics to create telescopes and microscopes that can magnify objects.
• Medical Imaging: Dilation is used in medical imaging to create images of the body that are proportional to the desired output.

Exercises

1. Find the coordinates of the image point B' after the triangle has been dilated with a center of dilation about the origin.
2. Find the scale factor of the dilation if the distance between the preimage point B (-2, 8) and the center of dilation (0, 0) is 10 units.
3. Find the coordinates of the image point C' after the triangle has been dilated with a center of dilation about the origin.

Solutions

1. To find the coordinates of the image point B', we can use the formula:

$$B' = (k \times x, k \times y)$$

Plugging in the values, we get:

$$B' = (0.125 \times -2, 0.125 \times 8)$$

$$B' = (-0.25, 1)$$

2. To find the scale factor, we can use the formula:

$$k = \frac{d'}{d}$$

Plugging in the values, we get:

$$k = \frac{\sqrt{0.3125}}{\sqrt{10}}$$

$$k = \frac{\sqrt{0.3125 \times 10}}{\sqrt{10 \times 10}}$$

$$k = \frac{\sqrt{3.125}}{10}$$

$$k = \frac{1.77}{10}$$

$$k = 0.177$$

3. To find the coordinates of the image point C', we can use the formula:

$$C' = (k \times x, k \times y)$$

Plugging in the values, we get:

$$C' = (0.125 \times 6, 0.125 \times 4)$$

$$C' = (0.75, 0.5)$$

Conclusion

In this article, we have discussed the concept of dilation and how it affects the size of a figure. We have calculated the scale factor of the dilation and used it to find the coordinates of the image points A', B', and C'. We have also understood the effect of dilation on the triangle and how it reduces the size of the triangle.

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Q&A: Dilation and Similar Triangles

Q: What is dilation in geometry?

A: Dilation is a transformation that changes the size of a figure. It is a type of similarity transformation that can be used to create similar figures.

Q: What is the center of dilation?

A: The center of dilation is the fixed point around which the dilation occurs. It is the point that remains unchanged during the dilation process.

Q: What is the scale factor of dilation?

A: The scale factor of dilation is the ratio of the distance between the image and the center of dilation to the distance between the preimage and the center of dilation.

Q: How do you find the coordinates of the image point after dilation?

A: To find the coordinates of the image point after dilation, you can use the formula:

$$A' = (k \times x, k \times y)$$

where k is the scale factor and (x, y) are the coordinates of the preimage point.

Q: What is the effect of dilation on the size of a figure?

A: Dilation reduces the size of a figure. The scale factor determines the amount of reduction in size.

Q: Can dilation be used to create similar figures?

A: Yes, dilation can be used to create similar figures. Similar figures have the same shape but not necessarily the same size.

Q: What are some real-world applications of dilation?

A: Some real-world applications of dilation include:

• Photography: Dilation is used in photography to create different sizes and proportions of objects.
• Optics: Dilation is used in optics to create telescopes and microscopes that can magnify objects.
• Medical Imaging: Dilation is used in medical imaging to create images of the body that are proportional to the desired output.

Q: How do you find the scale factor of dilation?

A: To find the scale factor of dilation, you can use the formula:

$$k = \frac{d'}{d}$$

where d' is the distance between the image and the center of dilation and d is the distance between the preimage and the center of dilation.

Q: What is the difference between dilation and translation?

A: Dilation is a transformation that changes the size of a figure, while translation is a transformation that changes the position of a figure.

Q: Can dilation be used to create congruent figures?

A: No, dilation cannot be used to create congruent figures. Congruent figures have the same size and shape.

Q: What is the relationship between dilation and similarity?

A: Dilation is a type of similarity transformation that can be used to create similar figures.

Q: How do you determine if two figures are similar?

A: Two figures are similar if they have the same shape but not necessarily the same size.

Q: What is the importance of dilation in geometry?

A: Dilation is an important concept in geometry because it allows us to create similar figures and study the properties of similar figures.

Q: Can dilation be used to solve real-world problems?

A: Yes, dilation can be used to solve real-world problems such as designing buildings and structures, creating art and architecture, and solving problems in engineering and physics.

Q: What are some common mistakes to avoid when working with dilation?

A: Some common mistakes to avoid when working with dilation include:

• Confusing dilation with translation: Dilation changes the size of a figure, while translation changes the position of a figure.
• Not using the correct scale factor: Make sure to use the correct scale factor when working with dilation.
• Not checking for similarity: Make sure to check if the figures are similar before applying dilation.

Q: How do you check if two figures are similar?

A: To check if two figures are similar, you can use the following criteria:

• Same shape: The figures must have the same shape.
• Same size: The figures must have the same size.
• Same orientation: The figures must have the same orientation.

Q: What is the relationship between dilation and congruence?

A: Dilation is not a congruence transformation, meaning that it does not preserve the size and shape of a figure.

Q: Can dilation be used to create congruent figures?

A: No, dilation cannot be used to create congruent figures.

Q: What is the importance of understanding dilation in geometry?

A: Understanding dilation is important in geometry because it allows us to create similar figures and study the properties of similar figures.

Q: How do you apply dilation in real-world problems?

A: To apply dilation in real-world problems, you can use the following steps:

• Identify the problem: Identify the problem and the figures involved.
• Determine the scale factor: Determine the scale factor of dilation.
• Apply dilation: Apply dilation to the figures using the scale factor.
• Check for similarity: Check if the figures are similar after dilation.

Q: What are some common applications of dilation in real-world problems?

A: Some common applications of dilation in real-world problems include:

• Designing buildings and structures: Dilation is used in architecture to design buildings and structures that are proportional to the surrounding environment.
• Creating art and architecture: Dilation is used in art and architecture to create different sizes and proportions of objects.
• Solving problems in engineering and physics: Dilation is used in engineering and physics to solve problems involving similar figures.

Q: How do you determine the scale factor of dilation in real-world problems?

A: To determine the scale factor of dilation in real-world problems, you can use the following steps:

• Measure the distance: Measure the distance between the preimage and the center of dilation.
• Measure the distance: Measure the distance between the image and the center of dilation.
• Calculate the scale factor: Calculate the scale factor using the formula:

$$k = \frac{d'}{d}$$

where d' is the distance between the image and the center of dilation and d is the distance between the preimage and the center of dilation.

Q: What is the relationship between dilation and similarity in real-world problems?

A: Dilation is a type of similarity transformation that can be used to create similar figures in real-world problems.

Q: How do you apply dilation in real-world problems involving similar figures?

A: To apply dilation in real-world problems involving similar figures, you can use the following steps:

• Identify the problem: Identify the problem and the figures involved.
• Determine the scale factor: Determine the scale factor of dilation.
• Apply dilation: Apply dilation to the figures using the scale factor.
• Check for similarity: Check if the figures are similar after dilation.

Q: What are some common mistakes to avoid when working with dilation in real-world problems?

A: Some common mistakes to avoid when working with dilation in real-world problems include:

• Confusing dilation with translation: Dilation changes the size of a figure, while translation changes the position of a figure.
• Not using the correct scale factor: Make sure to use the correct scale factor when working with dilation.
• Not checking for similarity: Make sure to check if the figures are similar before applying dilation.

Q: How do you check if two figures are similar in real-world problems?

A: To check if two figures are similar in real-world problems, you can use the following criteria:

• Same shape: The figures must have the same shape.
• Same size: The figures must have the same size.
• Same orientation: The figures must have the same orientation.

Q: What is the importance of understanding dilation in real-world problems?

A: Understanding dilation is important in real-world problems because it allows us to create similar figures and study the properties of similar figures.

Q: How do you apply dilation in real-world problems involving congruent figures?

A: To apply dilation in real-world problems involving congruent figures, you cannot use dilation. Instead, you can use other transformations such as translation or rotation.

Q: What are some common applications of dilation in real-world problems involving congruent figures?

A: Some common applications of dilation in real-world problems involving congruent figures include:

• Designing buildings and structures: Dilation is not used in architecture to design buildings and structures that are congruent to the surrounding environment.
• Creating art and architecture: Dilation is not used in art and architecture to create congruent figures.
• Solving problems in engineering and physics: Dilation is not used in engineering and physics to solve problems involving congruent figures.

Q: How do you determine the scale factor of dilation in real-world problems involving congruent figures?

A: To determine the scale factor of dilation in real-world problems involving congruent figures, you cannot use dilation. Instead, you can use other transformations such as translation or rotation.

Q: What is the relationship between dilation and congruence in real-world problems?

A: Dilation is not a congruence transformation, meaning that it does not preserve the size and shape of a figure.

Q: Can dilation be used to create congruent figures in real-world problems?

A: No, dilation cannot be used to create congruent figures in real-world problems.

Q: What is the importance of understanding dilation in real-world problems involving congruent figures?

A: Understanding dilation is not important in real-world problems involving congruent figures because dilation is not used to create congruent figures.

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