4.3.2: On Both of the Lines

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Illustrative Mathematics
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Lesson

Let's use lines to think about situations.

Exercise $\PageIndex{1}$: Notice and Wonder: Bugs Passing in the Night

Figure $\PageIndex{1}$: Four blank number lines. Each number line has a ladybug facing right and an ant facing left. Number line 1 is labeled ladybug start on the left end and 0 seconds. The ladybug is to the left of the number line and the ant is to the right of the number line. Number line 2 is labeled 2 seconds. The ladybug is at the 8th tick mark from the right. The ant is at the 16th tick mark from the left. Number line 3 is labeled 4 seconds. The ladybug is at the 16th tick mark from the right. The ant is at the 32nd tick mark from the left. Number line 4 is labeled 6 seconds. The ladybug is at the 24th tick mark. The ant is not shown in the number line.

Exercise $\PageIndex{2}$: Bugs Passing in the Night, Continued

A different ant and ladybug are a certain distance apart, and they start walking toward each other. The graph shows the ladybug’s distance from its starting point over time and the labeled point $(2.5,10)$ indicates when the ant and the ladybug pass each other.

Figure $\PageIndex{2}$: Graph of a line, origin O, with grid. Horizontal axis, time in seconds, scale 0 to 5, by 1’s. Vertical axis, distance in centimeters, scale 0 to 24, by 2’s. The line passes through the origin and the point 2 point 5 comma 10.

The ant is walking 2 centimeters per second.

Write an equation representing the relationship between the ant's distance from the ladybug;s starting point and the amount of time that has passed.
If you haven’t already, draw the graph of your equation on the same coordinate plane.

Exercise $\PageIndex{3}$: A Close Race

Elena and Jada were racing 100 meters on their bikes. Both racers started at the same time and rode at constant speed. Here is a table that gives information about Jada’s bike race:

Table $\PageIndex{1}$
time from start (seconds)	distance from start (meters)
$6$	$36$
$9$	$54$

1. Graph the relationship between distance and time for Jada’s bike race. Make sure to label and scale the axes appropriately.

2. Elena traveled the entire race at a steady 6 meters per second. On the same set of axes, graph the relationship between distance and time for Elena’s bike race.

3. Who won the race?

Summary

The solutions to an equation correspond to points on its graph. For example, if Car A is traveling 75 miles per hour and passes a rest area when $t=0$, then the distance in miles it has traveled from the rest area after $t$ hours is

$d=75t$

The point $(2,150)$ is on the graph of this equation because $150=75\cdot 2$: two hours after passing the rest area, the car has traveled 150 miles.

If you have two equations, you can ask whether there is an ordered pair that is a solution to both equations simultaneously. For example, if Car B is traveling towards the rest area and its distance from the rest area is

$d=14-65t$

We can ask if there is ever a time when the distance of Car A from the rest area is the same as the distance of Car B from the rest area. If the answer is “yes”, then the solution will correspond to a point that is on both lines.

Figure $\PageIndex{4}$: Graph of 2 lines, origin O, with grid. Horizontal axis, time in hours, scale 0 to point 22, by point 0 2’s. Vertical axis, distance in miles, scale 0 to 14, by 2’s. One line passes through the origin and the point 0 point 1 comma 7 point 5. Another line crosses the y axis at 14 and passes through the point 0 point 1 comma 7 point 5.

Looking at the coordinates of the intersection point, we see that Car A and Car B will both be 7.5 miles from the rest area after 0.1 hours (which is 6 minutes).

Now suppose another car, Car C, had also passed the rest stop at time $t=0$ and traveled in the same direction as Car A, also going 75 miles per hour. It's equation would also be $d=75t$. Any solution to the equation for Car A would also be a solution for Car C, and any solution to the equation for Car C would also be a solution for Car A. The line for Car C would land right on top of the line for Car A. In this case, every point on the graphed line is a solution to both equations, so that there are infinitely many solutions to the question “when are Car A and Car C the same distance from the rest stop?” This would mean that Car A and Car C were side by side for their whole journey.

When we have two linear equations that are equivalent to each other, like $y=3x+2$ and $2y=6x+4$, we will get two lines that are “right on top” of each other. Any solution to one equation is also solution to the other, so these two lines intersect at infinitely many points.

Practice

Exercise $\PageIndex{4}$

Diego has $11 and begins saving $5 each week toward buying a new phone. At the same time that Diego begins saving, Lin has $60 and begins spending $2 per week on supplies for her art class. Is there a week when they have the same amount of money? How much do they have at that time?

Exercise $\PageIndex{5}$

Use a graph to find $x$ and $y$ values that make both $y=\frac{-2}{3}x+3$ and $y=2x-5$ true.

Exercise $\PageIndex{6}$

The point where the graphs of two equations intersect has $y$-coordinate 2. One equation is $y=-3x+5$. Find the other equation if its graph has a slope of 1.

Exercise $\PageIndex{7}$

A farm has chickens and cows. All the cows have 4 legs and all the chickens have 2 legs. All together, there are 82 cow and chicken legs on the farm. Complete the table to show some possible combinations of chickens and cows to get 82 total legs.

Table $\PageIndex{2}$
number of chickens ($x$)	number of cows ($y$)
$35$
$7$
	$10$
$19$
	$5$

Here is a graph that shows possible combinations of chickens and cows that add up to 30 animals:

Figure $\PageIndex{6}$: Graph of points in the x y plane, origin O, with grid. Horizontal axis, number of chickens, scale 0 to 30 by 1s. Vertical axis, number of cows, scale 0 to 30 by 1s. Points plotted are 0 comma 30, 1 comma 29, 2 comma 28, 3 comma 27, 4 comma 26, 5 comma 25, 6 comma 24, 7 comma 23, 8 comma 22, 9 comma 21, 10 comma 20, 11 comma 19, 12 comma 18, 13 comma 17, 14 comma 16, 15 comma 15, 16 comma 14, 17 comma 13, 18 comma 12, 19 comma 11, 20 comma 10, 21 comma 9, 22 comma 8, 23 comma 7, 24 comma 6, 25 comma 5, 26 comma 4, 27 comma 3, 28 comma 2, 29 comma 1, 30 comma 0.

If the farm has 30 chickens and cows, and there are 82 chicken and cow legs all together, then how many chickens and how many cows could the farm have?

(From Unit 4.3.2)

time from start (seconds)	distance from start (meters)
\(6\)	\(36\)
\(9\)	\(54\)

number of chickens (\(x\))	number of cows (\(y\))
\(35\)
\(7\)
	\(10\)
\(19\)
	\(5\)

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