### All GMAT Math Resources

## Example Questions

### Example Question #721 : Gmat Quantitative Reasoning

What is the volume of a right pyramid whose height is 20 and whose base is an equilateral triangle with sidelength 10?

**Possible Answers:**

**Correct answer:**

The volume of a pyramid can be calculated using the formula

where is the height and is the area of the base.

Since the base is an equilateral triangle, its area can be calculated using the formula

Therefore, the volume can be rewritten as

Substitute :

### Example Question #2 : Calculating The Volume Of A Tetrahedron

A right pyramid has height ; its base is a square with four sides of length each. What is the volume of this pyramid?

**Possible Answers:**

**Correct answer:**

The volume of a pyramid can be calculated using the formula

,

where is the area of the base and is the height. The base of the pyramid in question is a square; if we let its sidelength be , this base will be , and the volume formula will be

Setting and :

or

.

### Example Question #11 : Rectangular Solids & Cylinders

The slant height of a pyramid is one and one-half times the perimeter of its square base. The base has sides of length 15 inches. What is the surface area of the pyramid?

**Possible Answers:**

**Correct answer:**

The square base of the pyramid has four sides with length 15 inches, making its perimeter four times that, or 60 inches. The slant height is

inches.

Therefore, the area of the base is square inches.

Each of the four lateral triangles has area square inches.

The total surface area is square inches.

### Example Question #11 : Rectangular Solids & Cylinders

In three-dimensional space, the four vertices of a tetrahedron - a solid with four faces - have Cartesian coordinates .

Give the surface area of the tetrahedron.

**Possible Answers:**

**Correct answer:**

The tetrahedron looks like this:

is the origin and are the other three points, which are 60 units away from the origin on each of the three (perpendicular) axes.

The bottom, front, and left faces are each right triangles whose legs each measure 60. Each face has area

.

The remaining face has three edges each a hypotenuse of one of three congruent right triangles, so its sides are congruent, and it is an equilateral triangle. Its sidelength can be found via the 45-45-90 Theorem to be , so its area is

The total area is

### Example Question #3 : Calculating The Surface Area Of A Tetrahedron

A regular tetrahedron comprises four faces, each of which is an equilateral triangle. If the sum of the lengths of its edges is 120, what is its surface area?

**Possible Answers:**

**Correct answer:**

As shown in the diagram below, a regular tetrahedron has six congruent edges, so each has length :

The area of one face is the area of an equilateral triangle with sidelength 20, which is

The total surface area is four times this, or .

### Example Question #4 : Calculating The Surface Area Of A Tetrahedron

A regular tetrahedron is a solid with four faces, each of which is an equilateral triangle.

Each edge of a regular tetrahedron has length . What is the surface area of the tetrahedron?

**Possible Answers:**

**Correct answer:**

The area of one face of the tetrahedron, it being an equilateral triangle, can be calulated using the formula

There are four congruent faces, so the total surface area is

Since , the surface area of the tetrahedron is

### Example Question #1 : Calculating The Surface Area Of A Tetrahedron

A regular tetrahedron is a solid with four faces, each of which is an equilateral triangle.

If the lengths of all of the edges of a regular tetrahedron are added, the total length is 120. What is the surface area of the tetrahedron?

**Possible Answers:**

**Correct answer:**

A tetrahedron looks like this:

The tetrahedron has six edges, and in a regular tetrahedron, they are congruent, so each edge has length .

The area of one face of the tetrahedron, it being an equilateral triangle, can be calulated using the formula

There are four congruent faces, so the total surface area is

Since , the surface area of the tetrahedron is

### Example Question #1 : Calculating The Surface Area Of A Tetrahedron

Evaluate the surface area of the above tetrahedron.

**Possible Answers:**

**Correct answer:**

Three of the faces of the tetrahedron are isosceles right triangles with legs of length 8, and, subsequently, by the 45-45-90 Theorem, hypotenuses of length . The fourth face, consequently, is an equilateral triangle with three sides of length .

Each of the three right triangle faces has area equal to half the product of its legs , which is

.

The equilateral face has as its area

The sum of the areas of the faces is

### Example Question #1 : Calculating The Surface Area Of A Tetrahedron

Refer to the above diagram, which shows a tetrahedron.

, and . Give the surface area of the tetrahedron.

**Possible Answers:**

**Correct answer:**

Three of the surfaces of the tetrahedron - , , and - are isosceles right triangles with hypotenuse 30, so by the 45-45-90 Theorem, each leg measures this length divided by , or

.

The area of each of these triangles is half the product of its legs, so each area is

Also, the legs are of the same measure among the triangles, the hypotenuses are as well, so the fourth surface is an equilateral triangle. Its sidelength is , so we use the equilateral triangle area formula to calculate its area:

Add the areas of the faces:

### Example Question #8 : Calculating The Surface Area Of A Tetrahedron

The above diagram shows a regular right triangular pyramid. Its base is an equilateral triangle; the other three faces are congruent isosceles triangles, with an altitude of . Give the surface area of the pyramid.

**Possible Answers:**

**Correct answer:**

The base is an equilateral triangle with sidelength 12, so its area can be calculated as follows:

.

Each of the three other faces is congruent, with base 12. The area of each is the product of its base and its height. To find the common height, we examine , which, since is an altitude of isosceles , is a right triangle with hypotenuse of length 18 and one leg of length . We can find using the Pythagorean Theorem:

The area of is half the product of this height and the base:

All three lateral faces have this area.

Now add the areas of the four faces:

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