All ACT Math Resources
Example Questions
Example Question #81 : Solid Geometry
The length of a box is 3 times the width. Which of the following gives the length (L inches) in terms of the width (W inches) of the box?
L = 3/W
L = ½ (3W)
L = 3W
L = W + 3
L = 3W
When reading word problems, there are certain clues that help interpret what is going on. The word “is” generally means “=” and the word “times” means it will be multiplied by something. Therefore, “the length of a box is 3 times the width” gives you the answer: L = 3 x W, or L = 3W.
Example Question #1 : Prisms
The width of a box, in inches, is 5 inches less than three times its length. Which of the following equations gives the width, W inches, in terms of the length, L inches, of the box?
W=5-3L
W=5L-3
W=3-5L
W=3L-5
W=3L-5
We notice the width is “5 inches less than three times its width,” so we express W as being three times its width (3L) and 5 inches less than that is 3L minus 5. In this case, W is the dependent and L is the independent variable.
W = 3L - 5
Example Question #972 : Act Math
Sturgis is in charge of designing a new exhibit in the shape of a rectangular prism for a local aquarium. The exhibit will hold alligator snapping turtles and needs to have a volume of . Sturgis knows that the exhibit will be long and go back into the wall.
What will the height of the new exhibit be?
This sounds like a geometry problem, so start by drawing a picture so that you know exactly what you are dealing with.
Because we are dealing with rectangular prisms and volume, we will need the following formula:
Or
We are solving for height, so you can begin by rearranging the equation to get by itself:
Then, plug in our knowns (, and )
Here is the problem worked out with a corresponding picture:
Example Question #2 : How To Find The Length Of An Edge Of A Prism
Sturgis is in charge of designing a new exhibit in the shape of a rectangular prism for a local aquarium. The exhibit will hold alligator snapping turtles and needs to have a volume of . Sturgis knows that the exhibit will be long and go back into the wall.
If three-quarters of the exhibit's volume will be water, how high up the wall will the water come?
Cannot be determined with the information provided
The trickiest part of this question is the wording. This problem is asking for the height of the water in the exhibit if the exhibit is three-quarters full. We can find this at least two different ways.
1) The longer way requires that we begin by finding three quarters of the total volume:
Now we go back to our volume equation, and since we are again looking for height, we want it solved for :
Becomes
2) The easier way requires that we recognize a key detail. If we take three-quarters of the volume without changing our length or width, our new height will just be three-quarters of the total height. We can solve for the total height of the exhibit by using the volume equation and rearranging it to solve for :
At this point, we can substitute in our given values and solve for :
So, the total height of the exhibit is . We can now easily solve for three-quarters of the total height:
Example Question #1 : How To Find The Diagonal Of A Prism
A right, rectangular prism has has a length of , a width of , and a height of . What is the length of the diagonal of the prism?
First we must find the diagonal of the prism's base (). This can be done by using the Pythagorean Theorem with the length () and width ():
Therefore, the diagonal of the prism's base is . We can then use this again in the Pythagorean Theorem, along with the height of the prism (), to find the diagonal of the prism ():
Therefore, the length of the prism's diagonal is .
Example Question #2 : How To Find The Diagonal Of A Prism
What is the diagonal of a rectangular prism with a height of 4, width of 4 and height of 6?
Cannot be determined
In order to solve this problem, it's helpful to visualize where the diagonal is within the prism.
In this image, the diagonal is the pink line. By noting how it relates to the blue and green lines, we can observe how the pink line is connected and creates a right triangle. This very quickly becomes a problem that employs the Pythagorean theorem.
The goal is essentially to find the hypotenuse of this sketched-in right triangle; however, only one of the legs is given: the green line, the height of the prism. The blue line can be solved for by understanding that it is the measurement of the diagonal of a 4x4 square.
Either using trig functions or the rules for a special 45/45/90 triangle, the blue line measures out to be .
The rules for a 45/45/90 triangle: both legs are "" and the hypotenuse is "". Keep in mind, this is is only for isosceles right triangles.
Now that both legs are known, we can solve for the hypotenuse (diagonal).
Example Question #2 : Prisms
Find the diagonal of a right rectangular prism if the length, width, and height are 3,4, and 5, respectively.
Write the diagonal formula for a rectangular prism.
Substitute and solve for the diagonal.
Example Question #977 : Act Math
If the dimensions of a right rectangular prism are 1 yard by 1 foot by 1 inch, what is the diagonal in feet?
Convert the dimensions into feet.
The new dimensions of rectangular prism in feet are:
Write the formula for the diagonal of a right rectangular prism and substitute.
Example Question #2 : Non Cubic Prisms
David wants to paint the walls in his bedroom. The floor is covered by a carpet. The ceiling is tall. He selects a paint that will cover per quart and per gallon. How much paint should he buy?
1 gallon and 2 quarts
1 gallon and 1 quart
2 gallons and 1 quart
1 gallon
3 quarts
1 gallon and 2 quarts
Find the surface area of the walls: SAwalls = 2lh + 2wh, where the height is 8 ft, the width is 10 ft, and the length is 16 ft.
This gives a total surface area of 416 ft2. One gallon covers 300 ft2, and each quart covers 75 ft2, so we need 1 gallon and 2 quarts of paint to cover the walls.
Example Question #1 : How To Find The Surface Area Of A Prism
A box is 5 inches long, 5 inches wide, and 4 inches tall. What is the surface area of the box?
The box will have six total faces: an identical "top and bottom," and identical "left and right," and an identical "front and back." The total surface area will be the sum of these faces.
Since the six faces consider of three sets of pairs, we can set up the equation as:
Each of these faces will correspond to one pair of dimensions. Multiply the pair to get the area of the face.
Substitute the values from the question to solve.
Certified Tutor
Certified Tutor