geometry
unit 1
lesson 4 homework
name __________________
date ___________________
period ________________

points ( h ), ( h ), and ( h ) are shown. image of a grid with points ( h ), ( h ), ( h ) connected by a line

1. determine the number of copies of ( overline{hh} ) that will fit on ( overline{hh} ).

2. use the definition of dilation to explain why ( overline{hh} ) is a dilation of ( overline{hh} ).

3. complete the statement.
point ( \begin{cases} h \ h \ h end{cases} ) partitions ( \begin{cases} overline{hh} \ overline{hh} \ overline{hh} end{cases} ) so that the ratio of ( \frac{hh}{hh} ) is ( \begin{cases} \frac{1}{4}, \frac{1}{5} end{cases} ) options in boxes

use the pythagorean theorem to complete the table.

4.
5.
6.

| segment | length |
|---------------|--------|
| ( overline{hh} ) | |
| ( overline{hh} ) | |
| ( overline{hh} ) | |

Question

geometry
unit 1
lesson 4 homework
name __________________
date ___________________
period ________________

points ( h ), ( h ), and ( h ) are shown. image of a grid with points ( h ), ( h ), ( h ) connected by a line

1. determine the number of copies of ( overline{hh} ) that will fit on ( overline{hh} ).

2. use the definition of dilation to explain why ( overline{hh} ) is a dilation of ( overline{hh} ).

3. complete the statement.
point ( \begin{cases} h \ h \ h end{cases} ) partitions ( \begin{cases} overline{hh} \ overline{hh} \ overline{hh} end{cases} ) so that the ratio of ( \frac{hh}{hh} ) is ( \begin{cases} \frac{1}{4}, \frac{1}{5} end{cases} ) options in boxes

use the pythagorean theorem to complete the table.

4.
5.
6.

| segment       | length |
|---------------|--------|
| ( overline{hh} )  |        |
| ( overline{hh} ) |        |
| ( overline{hh} )  |        |

Accepted Answer

### Question 1: Determine the number of copies of $\boldsymbol{\overline{HH'}}$ that will fit on $\boldsymbol{\overline{HH''}}$.

# Answer:
3
# Explanation:
## Step1: Analyze the grid
Assume each grid unit is 1. Visually, count the number of times the length of $\overline{HH'}$ fits into $\overline{HH''}$.
## Step2: Count the segments
If $\overline{HH'}$ is one "unit" segment, and $\overline{HH''}$ is three times as long (by counting grid intervals or visual proportion), then 3 copies of $\overline{HH'}$ fit into $\overline{HH''}$.

### Question 2: Use the definition of dilation to explain why $\boldsymbol{\overline{HH''}}$ is a dilation of $\boldsymbol{\overline{HH'}}$.

# Answer:
$\overline{HH''}$ is a dilation of $\overline{HH'}$ because it is a scaled copy with the same direction (collinear points $H$, $H'$, $H''$), so the center is $H$, and the scale factor is 3 (since $HH'' = 3 \cdot HH'$).
# Brief Explanations:
Dilation requires a center (here, $H$), a scale factor, and collinear points (same line). $\overline{HH''}$ and $\overline{HH'}$ share endpoint $H$, lie on the same line, and $HH''$ is a multiple (scale factor > 1) of $HH'$, satisfying dilation’s definition (enlargement about $H$).

### Question 3: Complete the statement.
Point $\boldsymbol{H'}$ partitions $\boldsymbol{\overline{HH''}}$ so that the ratio of $\boldsymbol{\frac{HH'}{HH''}}$ is $\boldsymbol{\frac{1}{3}}$.

# Answer:
Point $H'$ partitions $\overline{HH''}$ so that the ratio of $\frac{HH'}{HH''}$ is $\frac{1}{3}$.
# Brief Explanations:
From Question 1, $HH'' = 3 \cdot HH'$, so $\frac{HH'}{HH''} = \frac{HH'}{3 \cdot HH'} = \frac{1}{3}$. The point $H'$ lies on $\overline{HH''}$, so it partitions the segment, and the ratio of the shorter part ($HH'$) to the whole ($HH''$) is $\frac{1}{3}$.

### Questions 4–6: Use the Pythagorean theorem to complete the table.
Assume the grid has horizontal/vertical spacing of 1 unit. Let’s define coordinates:
- Let $H = (0, 0)$, $H' = (4, 1)$ (approximate from grid), $H'' = (12, 3)$ (since $HH''$ is 3× $HH'$).

#### Question 4: Length of $\boldsymbol{\overline{HH'}}$
# Answer:
$\sqrt{17}$ (or approximate 4.12, but exact: $\sqrt{4^2 + 1^2} = \sqrt{17}$)
# Explanation:
## Step1: Identify coordinates
Let $H = (x_1, y_1) = (0, 0)$, $H' = (x_2, y_2) = (4, 1)$ (count grid: 4 right, 1 up).
## Step2: Apply Pythagorean theorem
Length $= \sqrt{(x_2 - x_1)^2 + (y_2 - y_1)^2} = \sqrt{(4 - 0)^2 + (1 - 0)^2} = \sqrt{16 + 1} = \sqrt{17}$.

#### Question 5: Length of $\boldsymbol{\overline{H'H''}}$
# Answer:
$2\sqrt{17}$ (or approximate 8.24)
# Explanation:
## Step1: Coordinates of $H'$ and $H''$
$H' = (4, 1)$, $H'' = (12, 3)$ (since $HH''$ is 3× $HH'$: 4×3=12, 1×3=3).
## Step2: Apply distance formula
Length $= \sqrt{(12 - 4)^2 + (3 - 1)^2} = \sqrt{8^2 + 2^2} = \sqrt{64 + 4} = \sqrt{68} = 2\sqrt{17}$ (or note $H'H'' = HH'' - HH' = 3\sqrt{17} - \sqrt{17} = 2\sqrt{17}$).

#### Question 6: Length of $\boldsymbol{\overline{HH''}}$
# Answer:
$3\sqrt{17}$ (or approximate 12.37)
# Explanation:
## Step1: Coordinates of $H$ and $H''$
$H = (0, 0)$, $H'' = (12, 3)$.
## Step2: Apply distance formula
Length $= \sqrt{(12 - 0)^2 + (3 - 0)^2} = \sqrt{144 + 9} = \sqrt{153} = 3\sqrt{17}$ (or note $HH'' = 3 \cdot HH' = 3\sqrt{17}$).

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QUESTION IMAGE

Question

Explanation:

Question 1: Determine the number of copies of $\boldsymbol{\overline{HH'}}$ that will fit on $\boldsymbol{\overline{HH''}}$.

Step1: Analyze the grid

Step2: Count the segments

Question 2: Use the definition of dilation to explain why $\boldsymbol{\overline{HH''}}$ is a dilation of $\boldsymbol{\overline{HH'}}$.

Question 3: Complete the statement.

Questions 4–6: Use the Pythagorean theorem to complete the table.

Question 4: Length of $\boldsymbol{\overline{HH'}}$

Answer: