Application Problems with Rational Expressions, Lecture notes of Algebra

Worksheet. Application Problems with Rational Expressions. The applications will involve situations with work rate, variations, water current and speed of.

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Math 51
Worksheet
Application Problems with Rational Expressions
The applications will involve situations with work rate, variations, water current and speed of
wind.
Work rate
Work rate problems usually involve two people that are trying to help each other finish a single
job.
Fran can clean the garage in 3 hours, but it takes Angie 4 hours to do the same job. How long
would it take them to clean the garage if they worked together?
It takes Fran 3 hours to do the work. So, she does
3
1
of the work each hour.
It takes Angie 4 hours to do the work. So, she does
4
1
of the work each hour.
How long will it take if the help each other is not know so;
Let x = The number of hours it takes them to do the work together.
Together, they do
x
1
of the work each hour.
Since, they are working together the sum of the two people individually equals the total.
x
1
4
1
3
1=+
Solve by clearing fractions with the LCD = 12x
=
+ x
x
x12
1
4
1
3
1
12
=
+
1234 xx
=
127x
7.1
7
12 =x
Answer: Together it takes about 1.7 hours to finish the job together.
Variation problems
Variation problems should be done in steps. The starting equations will be direct or inverse
variations.
Direct variation
kxy
=
means x and y are directly across from each other.
Inverse variation
x
k
y=
means that x is inverted on the other side of y.
In both cases k is always in the same position.
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Math 51 Worksheet

Application Problems with Rational Expressions

The applications will involve situations with work rate, variations, water current and speed of wind. Work rate Work rate problems usually involve two people that are trying to help each other finish a single job.

Fran can clean the garage in 3 hours, but it takes Angie 4 hours to do the same job. How long would it take them to clean the garage if they worked together?

♦ It takes Fran 3 hours to do the work. So, she does 3

(^1) of the work each hour.

♦ It takes Angie 4 hours to do the work. So, she does 4

(^1) of the work each hour.

♦ How long will it take if the help each other is not know so;

♦ Let x = The number of hours it takes them to do the work together. ♦ Together, they do x

(^1) of the work each hour.

Since, they are working together the sum of the two people individually equals the total.

x

(^1) + = Solve by clearing fractions with the LCD = 12x

⋅ ^ + x x

x^112 4

12 1 4 x + 3 x = 12 ⇒ 7 x = 12 ⇒ 1. 7 7

x =^12 ≈

Answer: Together it takes about 1.7 hours to finish the job together.

Variation problems Variation problems should be done in steps. The starting equations will be direct or inverse variations.

  • Direct variation y = kx means x and y are directly across from each other.
  • Inverse variation x

y =^ k means that x is inverted on the other side of y.

In both cases k is always in the same position.

Example: If m varies inversely as p, and m = 30 when p = 5, find m when p is 7.

Step 1 Write the equation, “m varies inversely as p” p

m = k

Step 2 m = 30 when p = 5 5

⇒ 30 = kk = 150 ←Use this value of k to solve

the final step

Step 3 find m when p is 6 6

m =^150 ⇒ m = 25 Done!

With or Against (wind or current) Once the equation is set up then the next step will require clearing fractions using the LCD. All solutions must be checked to avoid division by zero.

 Use a table to help organize all the information in the problem. Usually only two columns of the table need to be filled in. The goal is to create the equation using the table.

Example: Garth can row 5 miles per hour in still water. It takes him as long to row 4 miles upstream as 16 miles downstream. How fast is the current?

The equations for rate (r), distance (d), and time (t) are r

t^ d t

d = rt , r =^ d , =

 Let x = speed in still water  Let c = speed of the current

The main difference with these problems is rate needs to be expressed using two variables because moving upstream the current is against you and downstream it moves with you.

Distance Rate Time Upstream xc Downstream (^) x + c

Fill in the distance column with the numbers from the problem above and the value for speed in still water for x.

Distance Rate Time Upstream 4 5 − c Downstream (^16 5) + c

Fill in the column for time using the other two columns knowing that rate

⇒ time =^ distance

  1. A person swims 11 miles downriver in the same time they can swim 7 miles upriver. The speed of the current is 4 miles per hour. Find the speed of the person in still water.

  2. Kent can paint a certain room in 6 hours, but Kendra needs 4 hours to paint the same room. How long does it take them to paint the room if they work together?

  3. Marco can build a lap top twice as fast as Cliff. Working together, it takes them 5 hours. How long would it have taken Marco working alone?

  4. If s varies inversely as t^2 , and s = 10 when t = 2, find s when t is 10.

  5. The time (t) traveled by Delmar in a car varies inversely as rate (r). If Delmar drives at a speed of 80 mph in 12 hours, what will be the time to travel if he drives at 60 mph?

  6. For a given area of a triangle, the base varies inversely as its height. When the height is 10 in the base is 5 in. Find the base if the height is increased to 20 in.

Answer Key

  1. The speed of the boat in still water is 25 mph. 2)The speed of the wind is about 48.6 mph.
  2. The person can swim 18 mph in still water. 4) I will take 2.4 hours working together.
  3. It takes Marco 7.5 hours. 6) s equals 0.
  4. It will take 16 hours to drive. 8) The base would be reduced to 2.5 in.

Distance Rate Time Upstream xc Downstream (^) x + c