# 1.7: A Problem-Solving Plan

**At Grade**Created by: CK-12

Much of mathematics apply to real-world situations. To think critically and to problem solve are mathematical abilities. Although these capabilities may be the most challenging, they are also the most rewarding.

To be successful in applying mathematics in real-life situations, you must have a “toolbox” of strategies to assist you. The last few lessons of many chapters in this FlexBook are devoted to filling this toolbox so you to become a better problem solver and tackle mathematics in the real world.

## Step #1: Read and Understand the Given Problem

Every problem you encounter gives you clues needed to solve it successfully. Here is a checklist you can use to help you understand the problem.

*sum, difference, product,* and mathematical verbs such as *equal, more than, less than, is.* Key words also include the nouns the situation is describing such as *time, distance, people,* etc.

Visit the Wylie Intermediate Website (http://wylie.region14.net/webs/shamilton/math_clue_words.htm) for more clue words.

Once you have discovered what the problem is about, the next step is to declare what variables will represent the nouns in the problem. Remember to use letters that make sense!

## Step #2: Make a Plan to Solve the Problem

The next step in the problem-solving plan is to **make a plan** or **develop a strategy.** How can the information you know assist you in figuring out the unknown quantities?

Here are some common strategies that you will learn.

- Drawing a diagram
- Making a table
- Looking for a pattern
- Using guess and check
- Working backwards
- Using a formula
- Reading and making graphs
- Writing equations
- Using linear models
- Using dimensional analysis
- Using the right type of function for the situation

In most problems, you will use a combination of strategies. For example, drawing a diagram and looking for patterns are good strategies for most problems. Also, making a table and drawing a graph are often used together. The “writing an equation” strategy is the one you will work with the most frequently in your study of algebra.

## Step #3: Solve the Problem and Check the Results

Once you develop a plan, you can use it to **solve the problem.**

The last step in solving any problem should always be to **check and interpret** the answer. Here are some questions to help you to do that.

- Does the answer make sense?
- If you substitute the solution into the original problem, does it make the sentence true?
- Can you use another method to arrive at the same answer?

## Step #4: Compare Alternative Approaches

Sometimes a certain problem is best solved by using a specific method. Most of the time, however, it can be solved by using several different strategies. When you are familiar with all of the problem-solving strategies, it is up to you to choose the methods that you are most comfortable with and that make sense to you. In this book, we will often use more than one method to solve a problem. This way we can demonstrate the strengths and weaknesses of different strategies when applied to different types of problems.

Regardless of the strategy you are using, you should always implement the problem-solving plan when you are solving word problems. Here is a summary of the problem-solving plan.

**Step 1:** Understand the problem.

**Step 2:** Devise a plan – Translate. Come up with a way to solve the problem. Set up an equation, draw a diagram, make a chart, or construct a table as a start to begin your problem-solving plan.

**Step 3:** Carry out the plan – Solve.

**Step 4:** Check and Interpret: Check to see if you have used all your information. Then look to see if the answer makes sense.

## Solve Real-World Problems Using a Plan

**Example 1:** Jeff is 10 years old. His younger brother, Ben, is 4 years old. How old will Jeff be when he is twice as old as Ben?

**Solution:** Begin by understanding the problem. Highlight the key words.

**Jeff** is **10** years old. His younger brother, **Ben**, is **4** years old. **How old** will Jeff be **when he is twice as old as Ben**?

The question we need to answer is. “What is Jeff’s age when he is twice as old as Ben?”

You could guess and check, use a formula, make a table, or look for a pattern.

The key is “twice as old.” This clue means two times, or double Ben’s age. Begin by doubling possible ages. Let’s look for a pattern.

Jeff will be 12 years old.

**Example 2:** Matthew is planning to harvest his corn crop this fall. The field has 660 rows of corn with 300 ears per row. Matthew estimates his crew will have the crop harvested in 20 hours. How many ears of corn will his crew harvest per hour?

**Solution:** Begin by highlighting the key information.

Matthew is planning to harvest his corn crop this fall. The field has **660 rows** of corn with **300 ears per row**. Matthew estimates his crew will have the **crop harvested in 20 hours. How many ears of corn** will his crew **harvest per hour**?

You could draw a picture (it may take a while), write an equation, look for a pattern, or make a table. Let’s try to use reasoning.

We need to figure out how many ears of corn are in the field.

The crew can harvest 9,900 ears per hour.

## Practice Set

Sample explanations for some of the practice exercises below are available by viewing the following video. Note that there is not always a match between the number of the practice exercise in the video and the number of the practice exercise listed in the following exercise set. However, the practice exercise is the same in both. CK-12 Basic Algebra: Word Problem-Solving Plan 1 (10:12)

- What are the four steps to solving a problem?
- Name three strategies you can use to help make a plan. Which one(s) are you most familiar with already?
- Which types of strategies work well together? Why?
- Suppose Matthew’s crew takes 36 hours to harvest the field. How many ears per hour will they harvest?
- Why is it difficult to solve Ben and Jeff’s age problem by drawing a diagram?
- How do you check a solution to a problem? What is the purpose of checking the solution?
- There were 12 people on a jury, with four more women than men. How many women were there?
- A rope 14 feet long is cut into two pieces. One piece is 2.25 feet longer than the other. What are the lengths of the two pieces?
- A sweatshirt costs $35. Find the total cost if the sales tax is 7.75%.
- This year you got a 5% raise. If your new salary is $45,000, what was your salary before the raise?
- It costs $250 to carpet a room that is
14 ft×18 ft . How much does it cost to carpet a room that is9 ft×10 ft ? - A department store has a 15% discount for employees. Suppose an employee has a coupon worth $10 off any item and she wants to buy a $65 purse. What is the final cost of the purse if the employee discount is applied before the coupon is subtracted?
- To host a dance at a hotel, you must pay $250 plus $20 per guest. How much money would you have to pay for 25 guests?
- It costs $12 to get into the San Diego County Fair and $1.50 per ride. If Rena spent $24 in total, how many rides did she go on?
- An ice cream shop sells a small cone for $2.92, a medium cone for $3.50, and a large cone for $4.25. Last Saturday, the shop sold 22 small cones, 26 medium cones, and 15 large cones. How much money did the store earn?
- The sum of angles in a triangle is 180 degrees. If the second angle is twice the size of the first angle and the third angle is three times the size of the first angle, what are the measures of the angles in the triangle?

**Mixed Review**

- Choose an appropriate variable for the following situation:
*It takes Lily 45 minutes to bathe and groom a dog. How many dogs can she groom in an 9-hour day?* - Translate the following into an algebraic inequality:
*Fourteen less than twice a number is greater than or equal to 16.* - Write the pattern of the table below in words and using an algebraic equation.

&&y && -8 && -4 && 0 && 4

- Check that
m=4 is a solution to3y−11≥−3 . - What is the domain and range of the graph below?