Asked by jena loves culyss

To approximate the value of \( \sqrt{19} \) using a number line, we can check the squares of numbers around it.

We know:
- \( 4^2 = 16 \)
- \( 5^2 = 25 \)

This tells us that \( 4 < \sqrt{19} < 5 \).

Next, we can narrow it down further by checking more numbers:
- \( 4.3^2 = 18.49 \)
- \( 4.4^2 = 19.36 \)

Since \( 18.49 < 19 < 19.36 \), we can see that:
- \( 4.3 < \sqrt{19} < 4.4 \)

For more precision, we can try \( 4.35 \):
- \( 4.35^2 = 18.9225 \)

Since \( 18.9225 < 19 \), we have:
- \( 4.35 < \sqrt{19} < 4.4 \)

Estimating more closely, we find that \( \sqrt{19} \) is approximately \( 4.36 \).

Among the given options, the closest approximate value to \( \sqrt{19} \) would be **4.38**.

To find the approximate value of \( \sqrt{105} \) using a number line, we first identify the square numbers around it.

- \( 10^2 = 100 \)
- \( 11^2 = 121 \)

From this, we know that:
\[
10 < \sqrt{105} < 11
\]

Next, we can narrow it down further:

Calculating \( 10.5^2 \):
\[
10.5^2 = 110.25
\]

Since \( 110.25 > 105 \), we can see that:
\[
\sqrt{105} < 10.5
\]

Now calculating \( 10.25^2 \):
\[
10.25^2 = 105.0625
\]

Since \( 105.0625 > 105 \), this shows that:
\[
\sqrt{105} < 10.25 < 10.5
\]

Calculating \( 10.2^2 \):
\[
10.2^2 = 104.04
\]

Since \( 104.04 < 105 \), we have:
\[
10.2 < \sqrt{105} < 10.25
\]

Thus, \( \sqrt{105} \) is approximately between 10.2 and 10.25.

This places \( \sqrt{105} \) between the whole number 10 and the rational number 10.5.

Therefore, the answer is: **between 10 and 10.5**.

Let’s analyze each of the statements one by one to determine which one is true.

1. **\( \sqrt{48} > \sqrt{36} \)**:
- \( \sqrt{36} = 6 \)
- \( \sqrt{48} \) is approximately \( 6.928 \) (since \( 6.928^2 \) is close to 48).
- Thus, \( \sqrt{48} > \sqrt{36} \) is **true**.

2. **\( \sqrt{48} < \sqrt{36} \)**:
- Since we've established \( \sqrt{48} > \sqrt{36} \), this statement is **false**.

3. **\( \sqrt{49} < 7 \)**:
- \( \sqrt{49} = 7 \).
- Therefore, this statement is **false** because \( \sqrt{49} \) is equal to 7, not less than it.

4. **\( \sqrt{49} > 7 \)**:
- Again, since \( \sqrt{49} = 7 \), this statement is **false**.

Given these evaluations, the true statement is:
**\( \sqrt{48} > \sqrt{36} \)**.

Let's evaluate each statement one by one:

1. **\( \sqrt{81} > 9 \)**:
- \( \sqrt{81} = 9 \).
- Therefore, this statement is **false** because \( \sqrt{81} \) is equal to 9, not greater than it.

2. **\( \sqrt{71} > \sqrt{61} \)**:
- To compare, we can find approximate values:
- \( \sqrt{71} \) is approximately \( 8.43 \) (since \( 8.43^2 \) is around 71).
- \( \sqrt{61} \) is approximately \( 7.81 \) (since \( 7.81^2 \) is around 61).
- Thus, \( \sqrt{71} > \sqrt{61} \) is **true**.

3. **\( \sqrt{81} < 9 \)**:
- As noted before, \( \sqrt{81} = 9 \).
- Therefore, this statement is **false**.

4. **\( \sqrt{71} < \sqrt{61} \)**:
- Since we've established that \( \sqrt{71} > \sqrt{61} \), this statement is **false**.

Among the options, the true statement is:
**\( \sqrt{71} > \sqrt{61} \)**.

To accurately order the ornaments from tallest to shortest, we would need the actual heights of the square, diamond, and triangle ornaments. Since these heights are not provided in your message, I cannot determine the correct order.

If you have the heights of the ornaments, please provide that information, and I'd be happy to assist in ordering them. If you're looking for assistance with understanding how to approach this task, here’s a general method:

1. List the heights of each ornament.
2. Compare the heights.
3. Order them from tallest to shortest based on their measured values.

If you provide the heights, I can help further!