SAT Area & Volume Question 33 | Free SAT Prep | Aniko

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Question 33·Hard·Area and Volume

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A right square pyramid has a base with side length $10$ units. Each of the four slant edges (the edges from the apex to the base vertices) is $13$ units long. What is the volume of the pyramid, in cubic units?

For right pyramids on the SAT, start by writing the volume formula $V=\frac{1}{3}Bh$ and quickly find the base area from the given dimensions. Then focus on the height: draw or visualize a cross-section through the apex and a diagonal of the base so that the height, a known base segment (often half a diagonal), and a given slant edge form a right triangle. Use the Pythagorean theorem with the correct leg (center-to-vertex or center-to-side-midpoint, depending on whether they give slant edges or slant heights), solve for $h$ , and plug back into the formula, being careful not to confuse base side length, diagonal, and vertical height.

Hints

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Recall the basic volume formula

For a pyramid, the volume is one-third the product of the base area and the vertical height. What do you still need to find to use this formula?

Understand what the slant edge tells you

The $13$ -unit edges go from the apex to the vertices of the square base. In a right square pyramid, the apex is directly above the center of the base. How can these facts form a right triangle involving the height?

Find a key distance in the base

You need the distance from the center of the square base to a vertex. Use the fact that the base is a square of side $10$ ; what is the length of its diagonal, and then half of that diagonal?

Apply the Pythagorean theorem carefully

Set up a right triangle where the hypotenuse is $13$ , one leg is the distance from the center of the base to a vertex, and the other leg is the unknown height. Use the Pythagorean theorem to solve for the height, then plug it into the volume formula.

Desmos Guide

Compute the distance from the center to a vertex and the height

In Desmos, first enter the expression for the height using the Pythagorean theorem:

Type: sqrt(13^2 - (5*sqrt(2))^2)

Desmos will display the numeric value of the pyramid's vertical height.

Compute the volume using the height

Now use the volume formula with base area $100$ :

In a new line, type: (1/3)*100*sqrt(13^2 - (5*sqrt(2))^2)

The resulting value is the volume of the pyramid; if you wish, you can compare this decimal to the simplified radical form in the answer choices.

Step-by-step Explanation

Use the volume formula for a pyramid

For any pyramid,

V = \frac{1}{3}Bh,

where $B$ is the area of the base and $h$ is the vertical height (altitude) from the apex to the base.

The base is a square with side $10$ , so its area is

B = 10^2 = 100.

So the volume will be

V = \frac{1}{3} \cdot 100 \cdot h,

once we find the height $h$ .

Locate the height using the center of the square base

Because it is a right square pyramid, the apex is directly above the center of the square base. The vertical height $h$ drops straight down to the center of the base.

To use the given slant edge (length $13$ from apex to a vertex), consider the right triangle formed by:

the apex,
the center of the base,
and a vertex of the base.

In this triangle:

one leg is the vertical height $h$ ,
the other leg is the distance from the center of the square to a vertex,
the hypotenuse is the slant edge of length $13$ .

So we need the distance from the center of the square to a vertex.

Find the distance from the center of the square to a vertex

The segment from one vertex of the square to the opposite vertex is a diagonal of the square. For a square with side $s$ , the diagonal has length $s\sqrt{2}$ .

Here, $s=10$ , so the full diagonal is

10\sqrt{2}.

The center of the square is the midpoint of this diagonal, so the distance from the center to any vertex is half the diagonal:

\text{center-to-vertex distance} = \frac{10\sqrt{2}}{2} = 5\sqrt{2}.

This $5\sqrt{2}$ is the horizontal leg in our right triangle with hypotenuse $13$ and vertical leg $h$ .

Use the Pythagorean theorem to find the height

In the right triangle with legs $h$ and $5\sqrt{2}$ and hypotenuse $13$ , apply the Pythagorean theorem:

h^2 + (5\sqrt{2})^2 = 13^2.

Compute each term:

(5\sqrt{2})^2 = 25 \cdot 2 = 50, \\[0.7em] 13^2 = 169.

h^2 + 50 = 169 \\[0.7em] h^2 = 169 - 50 = 119 \\[0.7em] h = \sqrt{119}.

Now we know the vertical height of the pyramid.

Compute the volume of the pyramid

Substitute $B=100$ and $h=\sqrt{119}$ into the volume formula $V=\frac{1}{3}Bh$ :

V = \frac{1}{3} \cdot 100 \cdot \sqrt{119} = \frac{100\sqrt{119}}{3}.

So the volume of the pyramid is

\boxed{\dfrac{100\sqrt{119}}{3}},

which corresponds to choice D.

Strategy

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Desmos Guide

Step-by-step Explanation

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Strategy

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Desmos Guide

Step-by-step Explanation