Lesson 5
Building Quadratic Functions to Describe Situations (Part 1)
Problem 1
A rocket is launched in the air and its height, in feet, is modeled by the function \(h\). Here is a graph representing \(h\).
Select all true statements about the situation.
The rocket is launched from a height less than 20 feet above the ground.
The rocket is launched from about 20 feet above the ground.
The rocket reaches its maximum height after about 3 seconds.
The rocket reaches its maximum height after about 160 seconds.
The maximum height of the rocket is about 160 feet.
Solution
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Problem 2
A baseball travels \(d\) meters \(t\) seconds after being dropped from the top of a building. The distance traveled by the baseball can be modeled by the equation \(d = 5t^2\).
- Complete the table and plot the data on the coordinate plane.
\(t\) (seconds) \(d\) (meters) 0 0.5 1 1.5 2 - Is the baseball traveling at a constant speed? Explain how you know.
Solution
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Problem 3
A rock is dropped from a bridge over a river. Which table could represent the distance in feet fallen as a function of time in seconds?
Table A
time (seconds) | distance fallen (feet) |
---|---|
0 | 0 |
1 | 48 |
2 | 96 |
3 | 144 |
Table B
time (seconds) | distance fallen (feet) |
---|---|
0 | 0 |
1 | 16 |
2 | 64 |
3 | 144 |
Table C
time (seconds) | distance fallen (feet) |
---|---|
0 | 180 |
1 | 132 |
2 | 84 |
3 | 36 |
Table D
time (seconds) | distance fallen (feet) |
---|---|
0 | 180 |
1 | 164 |
2 | 116 |
3 | 36 |
Table A
Table B
Table C
Table D
Solution
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Problem 4
Determine whether \(5n^2\) or \(3^n\) will have the greater value when:
- \(n=1\)
- \(n=3\)
- \(n=5\)
Solution
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(From Unit 6, Lesson 4.)Problem 5
Select all of the expressions that give the number of small squares in Step \(n\).
\(2n\)
\(n^2\)
\(n+1\)
\(n^2+1\)
\(n(n+1)\)
\(n^2+n\)
\(n+n+1\)
Solution
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(From Unit 6, Lesson 3.)Problem 6
A small ball is dropped from a tall building. Which equation could represent the ball’s height, \(h\), in feet, relative to the ground, as a function of time, \(t\), in seconds?
\(h=100-16t\)
\(h=100-16t^2\)
\(h=100-16^t\)
\(h=100-\frac{16}{t}\)
Solution
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Problem 7
Use the rule for function \(f\) to draw its graph.
\(f(x)=\begin{cases} 2,& \text- 5\leq x< \text- 2 \\ 6,& \text- 2\leq x<4 \\ x, & 4\leq x<8\\ \end{cases}\)
Solution
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(From Unit 4, Lesson 12.)Problem 8
Diego claimed that \(10+x^2\) is always greater than \(2^x\) and used this table as evidence.
Do you agree with Diego?
\(x\) | \(10+x^2\) | \(2^x\) |
---|---|---|
1 | 11 | 2 |
2 | 14 | 4 |
3 | 19 | 8 |
4 | 26 | 16 |
Solution
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(From Unit 6, Lesson 4.)Problem 9
The table shows the height, in centimeters, of the water in a swimming pool at different times since the pool started to be filled.
- Does the height of the water increase by the same amount each minute? Explain how you know.
- Does the height of the water increase by the same factor each minute? Explain how you know.
minutes | height |
---|---|
0 | 150 |
1 | 150.5 |
2 | 151 |
3 | 151.5 |
Solution
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