All Advanced Geometry Resources
Example Questions
Example Question #51 : Solid Geometry
A regular tetrahedron has surface area 1,000. Which of the following comes closest to the length of one edge?
A regular tetrahedron has six congruent edges and, as its faces, four congruent equilateral triangles. If we let be the length of one edge, each face has as its area
;
the total surface area of the tetrahedron is therefore four times this, or
Set and solve for :
Divide by :
Take the square root of both sides:
Of the given choices, 20 comes closest.
Example Question #14 : Tetrahedrons
The above figure shows a triangular pyramid, or tetrahedron, on the three-dimensional coordinate axes. The tetrahedron has volume 1,000. Which of the following is closest to the value of ?
If we take the triangle on the -plane to be the base of the pyramid, this base has legs both of length ; its area is half the product of the lengths which is
Its height is the length of the side along the -axis, which is also of length .
The volume of a pyramid is equal to one third the product of its height and the area of its base, so
Setting the volume equal to 1,000, we can solve for :
Multiply both sides by 6:
Take the cube root of both sides:
The closest choice is 20.
Example Question #11 : Tetrahedrons
Given a regular tetrahedron with an edge of , what is the height (or diagonal)? The height is the line drawn from one vertex perpendicular to the opposite face.
None of the above.
The height of a regular tetrahedron can be derived from the formula
where is the length of one edge.
Therefore, plugging in the side length of ,
.
Example Question #12 : Tetrahedrons
Given a regular tetrahedron with an edge of , what is the height (or diagonal)? The height is the line drawn from one vertex perpendicular to the opposite face.
None of the above.
The height of a regular tetrahedron can be derived from the formula where is the length of one edge.
Plugging in we can solve for .
Example Question #51 : Advanced Geometry
Find the height of this regular tetrahedron:
The height of a regular tetrahedron can be found using the formula where s is the length of the sides.
In this case, the sides have length , so we are multiplying .
We can simplify this by multiplying the numbers inside the radical:
, which simplifies to .
Example Question #1 : How To Find The Surface Area Of A Tetrahedron
What is the surface area of the following tetrahedron? Assume the figure is a regular tetrahedron.
A tetrahedron is a three-dimensonal figure where each side is an equilateral triangle. Therefore, each angle in the triangle is .
In the figure, we know the value of the side and the value of the base . Since dividing the triangle by half creates a triangle, we know the value of must be .
Therefore, the area of one side of the tetrahedron is:
Since there are four sides of a tetrahedron, the surface area is:
Example Question #51 : Advanced Geometry
A regular tetrahedron has side lengths . What is the surface area of the described solid?
The area of one face of the triangle can be found either through trigonometry or the Pythagorean Theorem.
Since all the sides of the triangle are , the height is then, so the area of each face is:
There are four faces, so the area of the tetrahedron is:
Example Question #1 : How To Find The Surface Area Of A Tetrahedron
Find the surface area of a regular tetrahedron with a side length of .
Use the following formula to find the surface area of a regular tetrahedron.
Now, substitute in the value of the side length into the equation.
Example Question #1 : How To Find The Surface Area Of A Tetrahedron
Find the surface area of a regular tetrahedron with a side length of .
Use the following formula to find the surface area of a regular tetrahedron.
Now, substitute in the value of the side length into the equation.
Example Question #1 : How To Find The Surface Area Of A Tetrahedron
In terms of , find the surface area of a regular tetrahedron that has a side length of .
Use the following formula to find the surface area of a regular tetrahedron.
Now, substitute in the value of the side length into the equation.