All SAT Math Resources
Example Questions
Example Question #1 : How To Find The Surface Area Of A Sphere
A spherical orange fits snugly inside a small cubical box such that each of the six walls of the box just barely touches the surface of the orange. If the volume of the box is 64 cubic inches, what is the surface area of the orange in square inches?
64π
256π
128π
16π
32π
16π
The volume of a cube is found by V = s3. Since V = 64, s = 4. The side of the cube is the same as the diameter of the sphere. Since d = 4, r = 2. The surface area of a sphere is found by SA = 4π(r2) = 4π(22) = 16π.
Example Question #1 : How To Find The Surface Area Of A Sphere
A solid sphere is cut in half to form two solid hemispheres. What is the ratio of the surface area of one of the hemispheres to the surface area of the entire sphere before it was cut?
1/2
3/4
2/3
3/2
1
3/4
The surface area of the sphere before it was cut is equal to the following:
surface area of solid sphere = 4πr2, where r is the length of the radius.
Each hemisphere will have the following shape:
In order to determine the surface area of the hemisphere, we must find the surface area of the flat region and the curved region. The flat region will have a surface area equal to the area of a circle with radius r.
area of flat part of hemisphere = πr2
The surface area of the curved portion of the hemisphere will equal one-half of the surface area of the uncut sphere, which we established to be 4πr2.
area of curved part of hemisphere = (1/2)4πr2 = 2πr2
The total surface area of the hemisphere will be equal to the sum of the surface areas of the flat part and curved part of the hemisphere.
total surface area of hemisphere = πr2 + 2πr2 = 3πr2
Finally, we must find the ratio of the surface area of the hemisphere to the surface area of the uncut sphere.
ratio = (3πr2)/(4πr2) = 3/4
The answer is 3/4.
Example Question #2 : Spheres
The volume of a sphere is 2304π in3. What is the surface area of this sphere in square inches?
None of the other answers
144π
576π
216π
36π
576π
To solve this, we must first begin by finding the radius of the sphere. To do this, recall that the volume of a sphere is:
V = (4/3)πr3
For our data, we can say:
2304π = (4/3)πr3; 2304 = (4/3)r3; 6912 = 4r3; 1728 = r3; 12 * 12 * 12 = r3; r = 12
Now, based on this, we can ascertain the surface area using the equation:
A = 4πr2
For our data, this is:
A = 4π*122 = 576π
Example Question #5 : Spheres
A sphere has its center at the origin. A point on its surface is found on the x-y axis at (6,8). In square units, what is the surface area of this sphere?
200π
(400/3)π
400π
None of the other answers
40π
400π
To find the surface area, we must first find the radius. Based on our description, this passes from (0,0) to (6,8). This can be found using the distance formula:
62 + 82 = r2; r2 = 36 + 64; r2 = 100; r = 10
It should be noted that you could have quickly figured this out by seeing that (6,8) is the hypotenuse of a 6-8-10 triangle (which is a multiple of the "easy" 3-4-5).
The rest is easy. The surface area of the sphere is defined by:
A = 4πr2 = 4 * 100 * π = 400π
Example Question #2 : How To Find The Surface Area Of A Sphere
A sphere is perfectly contained within a cube that has a surface area of 726 square units. In square units, what is the surface area of the sphere?
484π
None of the other answers
30.25π
11π
121π
121π
To begin, we must determine the dimensions of the cube. To do this, recall that the surface area of a cube is made up of six squares and is thus defined as: A = 6s2, where s is one of the sides of the cube. For our data, this gives us:
726 = 6s2; 121 = s2; s = 11
Now, if the sphere is contained within the cube, that means that 11 represents the diameter of the sphere. Therefore, the radius of the sphere is 5.5 units. The surface area of a sphere is defined as: A = 4πr2. For our data, that would be:
A = 4π * 5.52 = 30.25 * 4 * π = 121π
Example Question #3 : How To Find The Surface Area Of A Sphere
The area of a circle with radius 4 divided by the surface area of a sphere with radius 2 is equal to:
3
2
0.5
π
1
1
The surface area of a sphere is 4πr2. The area of a circle is πr2. 16/16 is equal to 1.
Example Question #13 : Spheres
What is the ratio of the surface area of a cube to the surface area of a sphere inscribed within it?
6/π
2π
π/3
3/π
4/π
6/π
Let's call the radius of the sphere r. The formula for the surface area of a sphere (A) is given below:
A = 4πr2
Because the sphere is inscribed inside the cube, the diameter of the sphere is equal to the side length of the cube. Because the diameter is twice the length of the radius, the diameter of the sphere is 2r. This means that the side length of the cube is also 2r.
The surface area for a cube is given by the following formula, where s represents the length of each side of the cube:
surface area of cube = 6s2
The formula for surface area of a cube comes from the fact that each face of the cube has an area of s2, and there are 6 faces total on a cube.
Since we already determined that the side length of the cube is the same as 2r, we can replace s with 2r.
surface area of cube = 6(2r)2 = 6(2r)(2r) = 24r2.
We are asked to find the ratio of the surface area of the cube to the surface area of the sphere. This means we must divide the surface area of the cube by the surface area of the sphere.
ratio = (24r2)/(4πr2)
The r2 term cancels in the numerator and denominator. Also, 24/4 simplifes to 6.
ratio = (24r2)/(4πr2) = 6/π
The answer is 6/π.
Example Question #1 : How To Find The Surface Area Of A Sphere
What is the surface area of a hemisphere with a diameter of ?
A hemisphere is half of a sphere. The surface area is broken into two parts: the spherical part and the circular base.
The surface area of a sphere is given by .
So the surface area of the spherical part of a hemisphere is .
The area of the circular base is given by . The radius to use is half the diameter, or 2 cm.
Example Question #9 : How To Find The Surface Area Of A Sphere
Six spheres have surface areas that form an arithmetic sequence. The two smallest spheres have radii 4 and 6. Give the surface area of the largest sphere.
The surface area of a sphere with radius can be determined using the formula
.
The smallest sphere, with radius , has surface area
The second-smallest sphere, with radius , has surface area
The surface areas are in an arithmetic sequence; their common difference is the difference of these two surface areas, or
Since the six surface areas are in an arithmetic sequence, the surface area of the largest of the six spheres - that is, the sixth-smallest sphere - is
Example Question #2 : How To Find The Surface Area Of A Sphere
The radii of six spheres form an arithmetic sequence. The smallest and largest spheres have radii 10 and 30, respectively. Give the surface area of the second-smallest sphere.
None of the other responses gives a correct answer.
The radii of the spheres form an arithmetic sequence, with
and
The common difference can be computed as follows:
The second-smallest sphere has radius
The surface area of a sphere with radius can be determined using the formula
.
Setting , we get
.