Asked by Yayy

The formula for the lateral surface area \( A \) of a cylinder is given by:

\[
A = 2 \pi r h
\]

where:
- \( r \) is the radius,
- \( h \) is the height,
- \( \pi \) is approximately 3.14.

Given:
- \( r = 2.5 \) meters,
- \( h = 7 \) meters,
- \( \pi \approx 3.14 \).

Now, substituting the values into the formula:

\[
A = 2 \times 3.14 \times 2.5 \times 7
\]

Calculating step by step:

1. Calculate \( 2.5 \times 7 \):

\[
2.5 \times 7 = 17.5
\]

2. Now multiply by \( 3.14 \):

\[
3.14 \times 17.5 = 54.95
\]

3. Finally, multiply by 2:

\[
A = 2 \times 54.95 = 109.9
\]

So, the lateral surface area of the cylinder is \( 109.9 \) square meters.

Rounded to the nearest tenth, the answer is:

\[
\boxed{109.9} \text{ square meters}
\]

To find the total surface area \( A_t \) of a cylinder, we use the formula:

\[
A_t = 2\pi r h + 2\pi r^2
\]

This formula includes the lateral surface area (which we calculated previously) and the areas of the two circular bases.

We already know:
- The lateral surface area \( A_l = 109.9 \) square meters (from the previous calculation).
- The radius \( r = 2.5 \) meters.
- The height \( h = 7 \) meters.
- We will continue using \( \pi \approx 3.14 \).

Now we need to calculate the area of the two circular bases:

1. Area of one base:

\[
\text{Area of one base} = \pi r^2 = 3.14 \times (2.5)^2
\]

Calculating \( (2.5)^2 \):

\[
(2.5)^2 = 6.25
\]

Now calculating the area of one base:

\[
\text{Area of one base} = 3.14 \times 6.25 = 19.625
\]

2. Since there are two bases, multiply by 2:

\[
\text{Total area of the bases} = 2 \times 19.625 = 39.25
\]

3. Now add the lateral surface area and the total area of the bases to find the total surface area:

\[
A_t = A_l + \text{Total area of the bases} = 109.9 + 39.25 = 149.15
\]

Rounding to the nearest tenth, we get \( 149.2 \) square meters.

Comparing this value to the choices given:
1. 149.5
2. 515.0
3. 129.52
4. 266.9

The closest answer is **149.5**.

Thus, the correct answer is:

\[
\boxed{149.5}
\]