• Our Mission

6 Tips for Teaching Math Problem-Solving Skills

Solving word problems is tougher than computing with numbers, but elementary teachers can guide students to do the deep thinking involved.

Photo of elementary school teacher with students

A growing concern with students is the ability to problem-solve, especially with complex, multistep problems. Data shows that students struggle more when solving word problems than they do with computation , and so problem-solving should be considered separately from computation. Why?

Consider this. When we’re on the way to a new destination and we plug in our location to a map on our phone, it tells us what lane to be in and takes us around any detours or collisions, sometimes even buzzing our watch to remind us to turn. When I experience this as a driver, I don’t have to do the thinking. I can think about what I’m going to cook for dinner, not paying much attention to my surroundings other than to follow those directions. If I were to be asked to go there again, I wouldn’t be able to remember, and I would again seek help.

If we can switch to giving students strategies that require them to think instead of giving them too much support throughout the journey to the answer, we may be able to give them the ability to learn the skills to read a map and have several ways to get there.

Here are six ways we can start letting students do this thinking so that they can go through rigorous problem-solving again and again, paving their own way to the solution. 

1. Link problem-solving to reading

When we can remind students that they already have many comprehension skills and strategies they can easily use in math problem-solving, it can ease the anxiety surrounding the math problem. For example, providing them with strategies to practice, such as visualizing, acting out the problem with math tools like counters or base 10 blocks, drawing a quick sketch of the problem, retelling the story in their own words, etc., can really help them to utilize the skills they already have to make the task less daunting.

We can break these skills into specific short lessons so students have a bank of strategies to try on their own. Here's an example of an anchor chart that they can use for visualizing . Breaking up comprehension into specific skills can increase student independence and help teachers to be much more targeted in their problem-solving instruction. This allows students to build confidence and break down the barriers between reading and math to see they already have so many strengths that are transferable to all problems.

2. Avoid boxing students into choosing a specific operation

It can be so tempting to tell students to look for certain words that might mean a certain operation. This might even be thoroughly successful in kindergarten and first grade, but just like when our map tells us where to go, that limits students from becoming deep thinkers. It also expires once they get into the upper grades, where those words could be in a problem multiple times, creating more confusion when students are trying to follow a rule that may not exist in every problem.

We can encourage a variety of ways to solve problems instead of choosing the operation first. In first grade, a problem might say, “Joceline has 13 stuffed animals and Jordan has 17. How many more does Jordan have?” Some students might choose to subtract, but a lot of students might just count to find the amount in between. If we tell them that “how many more” means to subtract, we’re taking the thinking out of the problem altogether, allowing them to go on autopilot without truly solving the problem or using their comprehension skills to visualize it. 

3. Revisit ‘representation’

The word “representation” can be misleading. It seems like something to do after the process of solving. When students think they have to go straight to solving, they may not realize that they need a step in between to be able to support their understanding of what’s actually happening in the problem first.

Using an anchor chart like one of these ( lower grade , upper grade ) can help students to choose a representation that most closely matches what they’re visualizing in their mind. Once they sketch it out, it can give them a clearer picture of different ways they could solve the problem.

Think about this problem: “Varush went on a trip with his family to his grandmother’s house. It was 710 miles away. On the way there, three people took turns driving. His mom drove 214 miles. His dad drove 358 miles. His older sister drove the rest. How many miles did his sister drive?”

If we were to show this student the anchor chart, they would probably choose a number line or a strip diagram to help them understand what’s happening.

If we tell students they must always draw base 10 blocks in a place value chart, that doesn’t necessarily match the concept of this problem. When we ask students to match our way of thinking, we rob them of critical thinking practice and sometimes confuse them in the process. 

4. Give time to process

Sometimes as educators, we can feel rushed to get to everyone and everything that’s required. When solving a complex problem, students need time to just sit with a problem and wrestle with it, maybe even leaving it and coming back to it after a period of time.

This might mean we need to give them fewer problems but go deeper with those problems we give them. We can also speed up processing time when we allow for collaboration and talk time with peers on problem-solving tasks. 

5. Ask questions that let Students do the thinking

Questions or prompts during problem-solving should be very open-ended to promote thinking. Telling a student to reread the problem or to think about what tools or resources would help them solve it is a way to get them to try something new but not take over their thinking.

These skills are also transferable across content, and students will be reminded, “Good readers and mathematicians reread.” 

6. Spiral concepts so students frequently use problem-solving skills

When students don’t have to switch gears in between concepts, they’re not truly using deep problem-solving skills. They already kind of know what operation it might be or that it’s something they have at the forefront of their mind from recent learning. Being intentional within their learning stations and assessments about having a variety of rigorous problem-solving skills will refine their critical thinking abilities while building more and more resilience throughout the school year as they retain content learning in the process. 

Problem-solving skills are so abstract, and it can be tough to pinpoint exactly what students need. Sometimes we have to go slow to go fast. Slowing down and helping students have tools when they get stuck and enabling them to be critical thinkers will prepare them for life and allow them multiple ways to get to their own destination.

Problem Solving in Mathematics

  • Math Tutorials
  • Pre Algebra & Algebra
  • Exponential Decay
  • Worksheets By Grade

The main reason for learning about math is to become a better problem solver in all aspects of life. Many problems are multistep and require some type of systematic approach. There are a couple of things you need to do when solving problems. Ask yourself exactly what type of information is being asked for: Is it one of addition, subtraction, multiplication , or division? Then determine all the information that is being given to you in the question.

Mathematician George Pólya’s book, “ How to Solve It: A New Aspect of Mathematical Method ,” written in 1957, is a great guide to have on hand. The ideas below, which provide you with general steps or strategies to solve math problems, are similar to those expressed in Pólya’s book and should help you untangle even the most complicated math problem.

Use Established Procedures

Learning how to solve problems in mathematics is knowing what to look for. Math problems often require established procedures and knowing what procedure to apply. To create procedures, you have to be familiar with the problem situation and be able to collect the appropriate information, identify a strategy or strategies, and use the strategy appropriately.

Problem-solving requires practice. When deciding on methods or procedures to use to solve problems, the first thing you will do is look for clues, which is one of the most important skills in solving problems in mathematics. If you begin to solve problems by looking for clue words, you will find that these words often indicate an operation.

Look for Clue Words

Think of yourself as a math detective. The first thing to do when you encounter a math problem is to look for clue words. This is one of the most important skills you can develop. If you begin to solve problems by looking for clue words, you will find that those words often indicate an operation.

Common clue words for addition  problems:

Common clue words for  subtraction  problems:

  • How much more

Common clue words for multiplication problems:

Common clue words for division problems:

Although clue words will vary a bit from problem to problem, you'll soon learn to recognize which words mean what in order to perform the correct operation.

Read the Problem Carefully

This, of course, means looking for clue words as outlined in the previous section. Once you’ve identified your clue words, highlight or underline them. This will let you know what kind of problem you’re dealing with. Then do the following:

  • Ask yourself if you've seen a problem similar to this one. If so, what is similar about it?
  • What did you need to do in that instance?
  • What facts are you given about this problem?
  • What facts do you still need to find out about this problem?

Develop a Plan and Review Your Work

Based on what you discovered by reading the problem carefully and identifying similar problems you’ve encountered before, you can then:

  • Define your problem-solving strategy or strategies. This might mean identifying patterns, using known formulas, using sketches, and even guessing and checking.
  • If your strategy doesn't work, it may lead you to an ah-ha moment and to a strategy that does work.

If it seems like you’ve solved the problem, ask yourself the following:

  • Does your solution seem probable?
  • Does it answer the initial question?
  • Did you answer using the language in the question?
  • Did you answer using the same units?

If you feel confident that the answer is “yes” to all questions, consider your problem solved.

Tips and Hints

Some key questions to consider as you approach the problem may be:

  • What are the keywords in the problem?
  • Do I need a data visual, such as a diagram, list, table, chart, or graph?
  • Is there a formula or equation that I'll need? If so, which one?
  • Will I need to use a calculator? Is there a pattern I can use or follow?

Read the problem carefully, and decide on a method to solve the problem. Once you've finished working the problem, check your work and ensure that your answer makes sense and that you've used the same terms and or units in your answer.

  • 2nd Grade Math Word Problems
  • The Horse Problem: A Math Challenge
  • 2020-21 Common Application Essay Option 4—Solving a Problem
  • How to Use Math Journals in Class
  • The Frayer Model for Math
  • Algorithms in Mathematics and Beyond
  • "Grandpa's Rubik's Cube"—Sample Common Application Essay, Option #4
  • Math Stumper: Use Two Squares to Make Separate Pens for Nine Pigs
  • Critical Thinking Definition, Skills, and Examples
  • Graphic Organizers in Math
  • College Interview Tips: "Tell Me About a Challenge You Overcame"
  • Christmas Word Problem Worksheets
  • Solving Problems Involving Distance, Rate, and Time
  • Innovative Ways to Teach Math
  • Study Tips for Math Homework and Math Tests
  • 7 Steps to Math Success

Problem Solving Skills: Meaning, Examples & Techniques

Table of Contents

26 January 2021

Reading Time: 2 minutes

Do your children have trouble solving their Maths homework?

Or, do they struggle to maintain friendships at school?

If your answer is ‘Yes,’ the issue might be related to your child’s problem-solving abilities. Whether your child often forgets his/her lunch at school or is lagging in his/her class, good problem-solving skills can be a major tool to help them manage their lives better.

Children need to learn to solve problems on their own. Whether it is about dealing with academic difficulties or peer issues when children are equipped with necessary problem-solving skills they gain confidence and learn to make healthy decisions for themselves. So let us look at what is problem-solving, its benefits, and how to encourage your child to inculcate problem-solving abilities

Problem-solving skills can be defined as the ability to identify a problem, determine its cause, and figure out all possible solutions to solve the problem.

  • Trigonometric Problems

What is problem-solving, then? Problem-solving is the ability to use appropriate methods to tackle unexpected challenges in an organized manner. The ability to solve problems is considered a soft skill, meaning that it’s more of a personality trait than a skill you’ve learned at school, on-the-job, or through technical training. While your natural ability to tackle problems and solve them is something you were born with or began to hone early on, it doesn’t mean that you can’t work on it. This is a skill that can be cultivated and nurtured so you can become better at dealing with problems over time.

Problem Solving Skills: Meaning, Examples & Techniques are mentioned below in the Downloadable PDF. 

Benefits of learning problem-solving skills  

Promotes creative thinking and thinking outside the box.

Improves decision-making abilities.

Builds solid communication skills.

Develop the ability to learn from mistakes and avoid the repetition of mistakes.

Problem Solving as an ability is a life skill desired by everyone, as it is essential to manage our day-to-day lives. Whether you are at home, school, or work, life throws us curve balls at every single step of the way. And how do we resolve those? You guessed it right – Problem Solving.

Strengthening and nurturing problem-solving skills helps children cope with challenges and obstacles as they come. They can face and resolve a wide variety of problems efficiently and effectively without having a breakdown. Nurturing good problem-solving skills develop your child’s independence, allowing them to grow into confident, responsible adults. 

Children enjoy experimenting with a wide variety of situations as they develop their problem-solving skills through trial and error. A child’s action of sprinkling and pouring sand on their hands while playing in the ground, then finally mixing it all to eliminate the stickiness shows how fast their little minds work.

Sometimes children become frustrated when an idea doesn't work according to their expectations, they may even walk away from their project. They often become focused on one particular solution, which may or may not work.

However, they can be encouraged to try other methods of problem-solving when given support by an adult. The adult may give hints or ask questions in ways that help the kids to formulate their solutions. 

Encouraging Problem-Solving Skills in Kids

Practice problem solving through games.

Exposing kids to various riddles, mysteries, and treasure hunts, puzzles, and games not only enhances their critical thinking but is also an excellent bonding experience to create a lifetime of memories.

Create a safe environment for brainstorming

Welcome, all the ideas your child brings up to you. Children learn how to work together to solve a problem collectively when given the freedom and flexibility to come up with their solutions. This bout of encouragement instills in them the confidence to face obstacles bravely.

Invite children to expand their Learning capabilities

 Whenever children experiment with an idea or problem, they test out their solutions in different settings. They apply their teachings to new situations and effectively receive and communicate ideas. They learn the ability to think abstractly and can learn to tackle any obstacle whether it is finding solutions to a math problem or navigating social interactions.

Problem-solving is the act of finding answers and solutions to complicated problems. 

Developing problem-solving skills from an early age helps kids to navigate their life problems, whether academic or social more effectively and avoid mental and emotional turmoil.

Children learn to develop a future-oriented approach and view problems as challenges that can be easily overcome by exploring solutions. 

About Cuemath

Cuemath, a student-friendly mathematics and coding platform, conducts regular  Online Classes  for academics and skill-development, and their Mental Math App, on both  iOS  and  Android , is a one-stop solution for kids to develop multiple skills. Understand the Cuemath Fee structure and sign up for a free trial.

Frequently Asked Questions (FAQs)

How do you teach problem-solving skills.

Model a useful problem-solving method. Problem solving can be difficult and sometimes tedious. ... 1. Teach within a specific context. ... 2. Help students understand the problem. ... 3. Take enough time. ... 4. Ask questions and make suggestions. ... 5. Link errors to misconceptions.

What makes a good problem solver?

Excellent problem solvers build networks and know how to collaborate with other people and teams. They are skilled in bringing people together and sharing knowledge and information. A key skill for great problem solvers is that they are trusted by others.

Logo for FHSU Digital Press

Want to create or adapt books like this? Learn more about how Pressbooks supports open publishing practices.

5 Teaching Mathematics Through Problem Solving

Janet Stramel

Problem Solving

In his book “How to Solve It,” George Pólya (1945) said, “One of the most important tasks of the teacher is to help his students. This task is not quite easy; it demands time, practice, devotion, and sound principles. The student should acquire as much experience of independent work as possible. But if he is left alone with his problem without any help, he may make no progress at all. If the teacher helps too much, nothing is left to the student. The teacher should help, but not too much and not too little, so that the student shall have a reasonable share of the work.” (page 1)

What is a problem  in mathematics? A problem is “any task or activity for which the students have no prescribed or memorized rules or methods, nor is there a perception by students that there is a specific ‘correct’ solution method” (Hiebert, et. al., 1997). Problem solving in mathematics is one of the most important topics to teach; learning to problem solve helps students develop a sense of solving real-life problems and apply mathematics to real world situations. It is also used for a deeper understanding of mathematical concepts. Learning “math facts” is not enough; students must also learn how to use these facts to develop their thinking skills.

According to NCTM (2010), the term “problem solving” refers to mathematical tasks that have the potential to provide intellectual challenges for enhancing students’ mathematical understanding and development. When you first hear “problem solving,” what do you think about? Story problems or word problems? Story problems may be limited to and not “problematic” enough. For example, you may ask students to find the area of a rectangle, given the length and width. This type of problem is an exercise in computation and can be completed mindlessly without understanding the concept of area. Worthwhile problems  includes problems that are truly problematic and have the potential to provide contexts for students’ mathematical development.

There are three ways to solve problems: teaching for problem solving, teaching about problem solving, and teaching through problem solving.

Teaching for problem solving begins with learning a skill. For example, students are learning how to multiply a two-digit number by a one-digit number, and the story problems you select are multiplication problems. Be sure when you are teaching for problem solving, you select or develop tasks that can promote the development of mathematical understanding.

Teaching about problem solving begins with suggested strategies to solve a problem. For example, “draw a picture,” “make a table,” etc. You may see posters in teachers’ classrooms of the “Problem Solving Method” such as: 1) Read the problem, 2) Devise a plan, 3) Solve the problem, and 4) Check your work. There is little or no evidence that students’ problem-solving abilities are improved when teaching about problem solving. Students will see a word problem as a separate endeavor and focus on the steps to follow rather than the mathematics. In addition, students will tend to use trial and error instead of focusing on sense making.

Teaching through problem solving  focuses students’ attention on ideas and sense making and develops mathematical practices. Teaching through problem solving also develops a student’s confidence and builds on their strengths. It allows for collaboration among students and engages students in their own learning.

Consider the following worthwhile-problem criteria developed by Lappan and Phillips (1998):

  • The problem has important, useful mathematics embedded in it.
  • The problem requires high-level thinking and problem solving.
  • The problem contributes to the conceptual development of students.
  • The problem creates an opportunity for the teacher to assess what his or her students are learning and where they are experiencing difficulty.
  • The problem can be approached by students in multiple ways using different solution strategies.
  • The problem has various solutions or allows different decisions or positions to be taken and defended.
  • The problem encourages student engagement and discourse.
  • The problem connects to other important mathematical ideas.
  • The problem promotes the skillful use of mathematics.
  • The problem provides an opportunity to practice important skills.

Of course, not every problem will include all of the above. Sometimes, you will choose a problem because your students need an opportunity to practice a certain skill.

Key features of a good mathematics problem includes:

  • It must begin where the students are mathematically.
  • The feature of the problem must be the mathematics that students are to learn.
  • It must require justifications and explanations for both answers and methods of solving.

Needlepoint of cats

Problem solving is not a  neat and orderly process. Think about needlework. On the front side, it is neat and perfect and pretty.

Back of a needlepoint

But look at the b ack.

It is messy and full of knots and loops. Problem solving in mathematics is also like this and we need to help our students be “messy” with problem solving; they need to go through those knots and loops and learn how to solve problems with the teacher’s guidance.

When you teach through problem solving , your students are focused on ideas and sense-making and they develop confidence in mathematics!

Mathematics Tasks and Activities that Promote Teaching through Problem Solving

Teacher teaching a math lesson

Choosing the Right Task

Selecting activities and/or tasks is the most significant decision teachers make that will affect students’ learning. Consider the following questions:

  • Teachers must do the activity first. What is problematic about the activity? What will you need to do BEFORE the activity and AFTER the activity? Additionally, think how your students would do the activity.
  • What mathematical ideas will the activity develop? Are there connections to other related mathematics topics, or other content areas?
  • Can the activity accomplish your learning objective/goals?

what are the problem solving skills in mathematics

Low Floor High Ceiling Tasks

By definition, a “ low floor/high ceiling task ” is a mathematical activity where everyone in the group can begin and then work on at their own level of engagement. Low Floor High Ceiling Tasks are activities that everyone can begin and work on based on their own level, and have many possibilities for students to do more challenging mathematics. One gauge of knowing whether an activity is a Low Floor High Ceiling Task is when the work on the problems becomes more important than the answer itself, and leads to rich mathematical discourse [Hover: ways of representing, thinking, talking, agreeing, and disagreeing; the way ideas are exchanged and what the ideas entail; and as being shaped by the tasks in which students engage as well as by the nature of the learning environment].

The strengths of using Low Floor High Ceiling Tasks:

  • Allows students to show what they can do, not what they can’t.
  • Provides differentiation to all students.
  • Promotes a positive classroom environment.
  • Advances a growth mindset in students
  • Aligns with the Standards for Mathematical Practice

Examples of some Low Floor High Ceiling Tasks can be found at the following sites:

  • YouCubed – under grades choose Low Floor High Ceiling
  • NRICH Creating a Low Threshold High Ceiling Classroom
  • Inside Mathematics Problems of the Month

Math in 3-Acts

Math in 3-Acts was developed by Dan Meyer to spark an interest in and engage students in thought-provoking mathematical inquiry. Math in 3-Acts is a whole-group mathematics task consisting of three distinct parts:

Act One is about noticing and wondering. The teacher shares with students an image, video, or other situation that is engaging and perplexing. Students then generate questions about the situation.

In Act Two , the teacher offers some information for the students to use as they find the solutions to the problem.

Act Three is the “reveal.” Students share their thinking as well as their solutions.

“Math in 3 Acts” is a fun way to engage your students, there is a low entry point that gives students confidence, there are multiple paths to a solution, and it encourages students to work in groups to solve the problem. Some examples of Math in 3-Acts can be found at the following websites:

  • Dan Meyer’s Three-Act Math Tasks
  • Graham Fletcher3-Act Tasks ]
  • Math in 3-Acts: Real World Math Problems to Make Math Contextual, Visual and Concrete

Number Talks

Number talks are brief, 5-15 minute discussions that focus on student solutions for a mental math computation problem. Students share their different mental math processes aloud while the teacher records their thinking visually on a chart or board. In addition, students learn from each other’s strategies as they question, critique, or build on the strategies that are shared.. To use a “number talk,” you would include the following steps:

  • The teacher presents a problem for students to solve mentally.
  • Provide adequate “ wait time .”
  • The teacher calls on a students and asks, “What were you thinking?” and “Explain your thinking.”
  • For each student who volunteers to share their strategy, write their thinking on the board. Make sure to accurately record their thinking; do not correct their responses.
  • Invite students to question each other about their strategies, compare and contrast the strategies, and ask for clarification about strategies that are confusing.

“Number Talks” can be used as an introduction, a warm up to a lesson, or an extension. Some examples of Number Talks can be found at the following websites:

  • Inside Mathematics Number Talks
  • Number Talks Build Numerical Reasoning

Light bulb

Saying “This is Easy”

“This is easy.” Three little words that can have a big impact on students. What may be “easy” for one person, may be more “difficult” for someone else. And saying “this is easy” defeats the purpose of a growth mindset classroom, where students are comfortable making mistakes.

When the teacher says, “this is easy,” students may think,

  • “Everyone else understands and I don’t. I can’t do this!”
  • Students may just give up and surrender the mathematics to their classmates.
  • Students may shut down.

Instead, you and your students could say the following:

  • “I think I can do this.”
  • “I have an idea I want to try.”
  • “I’ve seen this kind of problem before.”

Tracy Zager wrote a short article, “This is easy”: The Little Phrase That Causes Big Problems” that can give you more information. Read Tracy Zager’s article here.

Using “Worksheets”

Do you want your students to memorize concepts, or do you want them to understand and apply the mathematics for different situations?

What is a “worksheet” in mathematics? It is a paper and pencil assignment when no other materials are used. A worksheet does not allow your students to use hands-on materials/manipulatives [Hover: physical objects that are used as teaching tools to engage students in the hands-on learning of mathematics]; and worksheets are many times “naked number” with no context. And a worksheet should not be used to enhance a hands-on activity.

Students need time to explore and manipulate materials in order to learn the mathematics concept. Worksheets are just a test of rote memory. Students need to develop those higher-order thinking skills, and worksheets will not allow them to do that.

One productive belief from the NCTM publication, Principles to Action (2014), states, “Students at all grade levels can benefit from the use of physical and virtual manipulative materials to provide visual models of a range of mathematical ideas.”

You may need an “activity sheet,” a “graphic organizer,” etc. as you plan your mathematics activities/lessons, but be sure to include hands-on manipulatives. Using manipulatives can

  • Provide your students a bridge between the concrete and abstract
  • Serve as models that support students’ thinking
  • Provide another representation
  • Support student engagement
  • Give students ownership of their own learning.

Adapted from “ The Top 5 Reasons for Using Manipulatives in the Classroom ”.

any task or activity for which the students have no prescribed or memorized rules or methods, nor is there a perception by students that there is a specific ‘correct’ solution method

should be intriguing and contain a level of challenge that invites speculation and hard work, and directs students to investigate important mathematical ideas and ways of thinking toward the learning

involves teaching a skill so that a student can later solve a story problem

when we teach students how to problem solve

teaching mathematics content through real contexts, problems, situations, and models

a mathematical activity where everyone in the group can begin and then work on at their own level of engagement

20 seconds to 2 minutes for students to make sense of questions

Mathematics Methods for Early Childhood Copyright © 2021 by Janet Stramel is licensed under a Creative Commons Attribution 4.0 International License , except where otherwise noted.

Share This Book

Library homepage

  • school Campus Bookshelves
  • menu_book Bookshelves
  • perm_media Learning Objects
  • login Login
  • how_to_reg Request Instructor Account
  • hub Instructor Commons
  • Download Page (PDF)
  • Download Full Book (PDF)
  • Periodic Table
  • Physics Constants
  • Scientific Calculator
  • Reference & Cite
  • Tools expand_more
  • Readability

selected template will load here

This action is not available.

Mathematics LibreTexts

Module 1: Problem Solving Strategies

  • Last updated
  • Save as PDF
  • Page ID 10352

Unlike exercises, there is never a simple recipe for solving a problem. You can get better and better at solving problems, both by building up your background knowledge and by simply practicing. As you solve more problems (and learn how other people solved them), you learn strategies and techniques that can be useful. But no single strategy works every time.

Pólya’s How to Solve It

George Pólya was a great champion in the field of teaching effective problem solving skills. He was born in Hungary in 1887, received his Ph.D. at the University of Budapest, and was a professor at Stanford University (among other universities). He wrote many mathematical papers along with three books, most famously, “How to Solve it.” Pólya died at the age 98 in 1985.1

1. Image of Pólya by Thane Plambeck from Palo Alto, California (Flickr) [CC BY

Screen Shot 2018-08-30 at 4.43.05 PM.png

In 1945, Pólya published the short book How to Solve It , which gave a four-step method for solving mathematical problems:

First, you have to understand the problem.

After understanding, then make a plan.

Carry out the plan.

Look back on your work. How could it be better?

This is all well and good, but how do you actually do these steps?!?! Steps 1. and 2. are particularly mysterious! How do you “make a plan?” That is where you need some tools in your toolbox, and some experience to draw upon.

Much has been written since 1945 to explain these steps in more detail, but the truth is that they are more art than science. This is where math becomes a creative endeavor (and where it becomes so much fun). We will articulate some useful problem solving strategies, but no such list will ever be complete. This is really just a start to help you on your way. The best way to become a skilled problem solver is to learn the background material well, and then to solve a lot of problems!

Problem Solving Strategy 1 (Guess and Test)

Make a guess and test to see if it satisfies the demands of the problem. If it doesn't, alter the guess appropriately and check again. Keep doing this until you find a solution.

Mr. Jones has a total of 25 chickens and cows on his farm. How many of each does he have if all together there are 76 feet?

Step 1: Understanding the problem

We are given in the problem that there are 25 chickens and cows.

All together there are 76 feet.

Chickens have 2 feet and cows have 4 feet.

We are trying to determine how many cows and how many chickens Mr. Jones has on his farm.

Step 2: Devise a plan

Going to use Guess and test along with making a tab

Many times the strategy below is used with guess and test.

Make a table and look for a pattern:

Procedure: Make a table reflecting the data in the problem. If done in an orderly way, such a table will often reveal patterns and relationships that suggest how the problem can be solved.

Step 3: Carry out the plan:

Notice we are going in the wrong direction! The total number of feet is decreasing!

Better! The total number of feet are increasing!

Step 4: Looking back:

Check: 12 + 13 = 25 heads

24 + 52 = 76 feet.

We have found the solution to this problem. I could use this strategy when there are a limited number of possible answers and when two items are the same but they have one characteristic that is different.

Videos to watch:

1. Click on this link to see an example of “Guess and Test”

http://www.mathstories.com/strategies.htm

2. Click on this link to see another example of Guess and Test.

http://www.mathinaction.org/problem-solving-strategies.html

Check in question 1:

clipboard_e6298bbd7c7f66d9eb9affcd33892ef0d.png

Place the digits 8, 10, 11, 12, and 13 in the circles to make the sums across and vertically equal 31. (5 points)

Check in question 2:

Old McDonald has 250 chickens and goats in the barnyard. Altogether there are 760 feet . How many of each animal does he have? Make sure you use Polya’s 4 problem solving steps. (12 points)

Problem Solving Strategy 2 (Draw a Picture). Some problems are obviously about a geometric situation, and it is clear you want to draw a picture and mark down all of the given information before you try to solve it. But even for a problem that is not geometric thinking visually can help!

Videos to watch demonstrating how to use "Draw a Picture".

1. Click on this link to see an example of “Draw a Picture”

2. Click on this link to see another example of Draw a Picture.

Problem Solving Strategy 3 ( Using a variable to find the sum of a sequence.)

Gauss's strategy for sequences.

last term = fixed number ( n -1) + first term

The fix number is the the amount each term is increasing or decreasing by. "n" is the number of terms you have. You can use this formula to find the last term in the sequence or the number of terms you have in a sequence.

Ex: 2, 5, 8, ... Find the 200th term.

Last term = 3(200-1) +2

Last term is 599.

To find the sum of a sequence: sum = [(first term + last term) (number of terms)]/ 2

Sum = (2 + 599) (200) then divide by 2

Sum = 60,100

Check in question 3: (10 points)

Find the 320 th term of 7, 10, 13, 16 …

Then find the sum of the first 320 terms.

Problem Solving Strategy 4 (Working Backwards)

This is considered a strategy in many schools. If you are given an answer, and the steps that were taken to arrive at that answer, you should be able to determine the starting point.

Videos to watch demonstrating of “Working Backwards”

https://www.youtube.com/watch?v=5FFWTsMEeJw

Karen is thinking of a number. If you double it, and subtract 7, you obtain 11. What is Karen’s number?

1. We start with 11 and work backwards.

2. The opposite of subtraction is addition. We will add 7 to 11. We are now at 18.

3. The opposite of doubling something is dividing by 2. 18/2 = 9

4. This should be our answer. Looking back:

9 x 2 = 18 -7 = 11

5. We have the right answer.

Check in question 4:

Christina is thinking of a number.

If you multiply her number by 93, add 6, and divide by 3, you obtain 436. What is her number? Solve this problem by working backwards. (5 points)

Problem Solving Strategy 5 (Looking for a Pattern)

Definition: A sequence is a pattern involving an ordered arrangement of numbers.

We first need to find a pattern.

Ask yourself as you search for a pattern – are the numbers growing steadily larger? Steadily smaller? How is each number related?

Example 1: 1, 4, 7, 10, 13…

Find the next 2 numbers. The pattern is each number is increasing by 3. The next two numbers would be 16 and 19.

Example 2: 1, 4, 9, 16 … find the next 2 numbers. It looks like each successive number is increase by the next odd number. 1 + 3 = 4.

So the next number would be

25 + 11 = 36

Example 3: 10, 7, 4, 1, -2… find the next 2 numbers.

In this sequence, the numbers are decreasing by 3. So the next 2 numbers would be -2 -3 = -5

-5 – 3 = -8

Example 4: 1, 2, 4, 8 … find the next two numbers.

This example is a little bit harder. The numbers are increasing but not by a constant. Maybe a factor?

So each number is being multiplied by 2.

16 x 2 = 32

1. Click on this link to see an example of “Looking for a Pattern”

2. Click on this link to see another example of Looking for a Pattern.

Problem Solving Strategy 6 (Make a List)

Example 1 : Can perfect squares end in a 2 or a 3?

List all the squares of the numbers 1 to 20.

1 4 9 16 25 36 49 64 81 100 121 144 169 196 225 256 289 324 361 400.

Now look at the number in the ones digits. Notice they are 0, 1, 4, 5, 6, or 9. Notice none of the perfect squares end in 2, 3, 7, or 8. This list suggests that perfect squares cannot end in a 2, 3, 7 or 8.

How many different amounts of money can you have in your pocket if you have only three coins including only dimes and quarters?

Quarter’s dimes

0 3 30 cents

1 2 45 cents

2 1 60 cents

3 0 75 cents

Videos demonstrating "Make a List"

Check in question 5:

How many ways can you make change for 23 cents using only pennies, nickels, and dimes? (10 points)

Problem Solving Strategy 7 (Solve a Simpler Problem)

Geometric Sequences:

How would we find the nth term?

Solve a simpler problem:

1, 3, 9, 27.

1. To get from 1 to 3 what did we do?

2. To get from 3 to 9 what did we do?

Let’s set up a table:

Term Number what did we do

what are the problem solving skills in mathematics

Looking back: How would you find the nth term?

what are the problem solving skills in mathematics

Find the 10 th term of the above sequence.

Let L = the tenth term

what are the problem solving skills in mathematics

Problem Solving Strategy 8 (Process of Elimination)

This strategy can be used when there is only one possible solution.

I’m thinking of a number.

The number is odd.

It is more than 1 but less than 100.

It is greater than 20.

It is less than 5 times 7.

The sum of the digits is 7.

It is evenly divisible by 5.

a. We know it is an odd number between 1 and 100.

b. It is greater than 20 but less than 35

21, 23, 25, 27, 29, 31, 33, 35. These are the possibilities.

c. The sum of the digits is 7

21 (2+1=3) No 23 (2+3 = 5) No 25 (2 + 5= 7) Yes Using the same process we see there are no other numbers that meet this criteria. Also we notice 25 is divisible by 5. By using the strategy elimination, we have found our answer.

Check in question 6: (8 points)

Jose is thinking of a number.

The number is not odd.

The sum of the digits is divisible by 2.

The number is a multiple of 11.

It is greater than 5 times 4.

It is a multiple of 6

It is less than 7 times 8 +23

What is the number?

Click on this link for a quick review of the problem solving strategies.

https://garyhall.org.uk/maths-problem-solving-strategies.html

Cambridge University Faculty of Mathematics

Or search by topic

Number and algebra

  • The Number System and Place Value
  • Calculations and Numerical Methods
  • Fractions, Decimals, Percentages, Ratio and Proportion
  • Properties of Numbers
  • Patterns, Sequences and Structure
  • Algebraic expressions, equations and formulae
  • Coordinates, Functions and Graphs

Geometry and measure

  • Angles, Polygons, and Geometrical Proof
  • 3D Geometry, Shape and Space
  • Measuring and calculating with units
  • Transformations and constructions
  • Pythagoras and Trigonometry
  • Vectors and Matrices

Probability and statistics

  • Handling, Processing and Representing Data
  • Probability

Working mathematically

  • Thinking mathematically
  • Mathematical mindsets
  • Cross-curricular contexts
  • Physical and digital manipulatives

For younger learners

  • Early Years Foundation Stage

Advanced mathematics

  • Decision Mathematics and Combinatorics
  • Advanced Probability and Statistics

Published 2018

The Problem-solving Classroom

  • Visualising
  • Working backwards
  • Reasoning logically
  • Conjecturing
  • Working systematically
  • Looking for patterns
  • Trial and improvement.

what are the problem solving skills in mathematics

  • stage of the lesson 
  • level of thinking
  • mathematical skill.
  • The length of student response increases (300-700%)
  • More responses are supported by logical argument.
  • An increased number of speculative responses.
  • The number of questions asked by students increases.
  • Student - student exchanges increase (volleyball).
  • Failures to respond decrease.
  • 'Disciplinary moves' decrease.
  • The variety of students participating increases.  As does the number of unsolicited, but appropriate contributions.
  • Student confidence increases.
  • conceptual understanding
  • procedural fluency
  • strategic competence
  • adaptive reasoning
  • productive disposition

what are the problem solving skills in mathematics

Wonder Math

How to Improve Problem-Solving Skills: Mathematics and Critical Thinking

how-to-improve-problem-solving-skills

In today’s rapidly changing world, problem-solving has become a quintessential skill. When we discuss the topic, it’s natural to ask, “What is problem-solving?” and “How can we enhance this skill, particularly in children?” The discipline of mathematics offers a rich platform to explore these questions. Through math, not only do we delve into numbers and equations, but we also explore how to improve problem-solving skills and how to develop critical thinking skills in math. Let’s embark on this enlightening journey together.

What is Problem-Solving?

At its core, problem-solving involves identifying a challenge and finding a solution. But it’s not always as straightforward as it sounds. So, what is problem-solving? True problem-solving requires a combination of creative thinking and logical reasoning. Mathematics, in many ways, embodies this blend. When a student approaches a math problem, they must discern the issue at hand, consider various methods to tackle it, and then systematically execute their chosen strategy.

But what is problem-solving in a broader context? It’s a life skill. Whether we’re deciding the best route to a destination, determining how to save for a big purchase, or even figuring out how to fix a broken appliance, we’re using problem-solving.

How to Develop Critical Thinking Skills in Math

Critical thinking goes hand in hand with problem-solving. But exactly how to develop critical thinking skills in math might not be immediately obvious. Here are a few strategies:

  • Contextual Learning: Teaching math within a story or real-life scenario makes it relevant. When students see math as a tool to navigate the world around them, they naturally begin to think critically about solutions.
  • Open-ended Questions: Instead of merely seeking the “right” answer, encourage students to explain their thought processes. This nudges them to think deeply about their approach.
  • Group Discussions: Collaborative learning can foster different perspectives, prompting students to consider multiple ways to solve a problem.
  • Challenging Problems: Occasionally introducing problems that are a bit beyond a student’s current skill level can stimulate critical thinking. They will have to stretch their understanding and think outside the box.

What are the Six Basic Steps of the Problem-Solving Process?

Understanding how to improve problem-solving skills often comes down to familiarizing oneself with the systematic approach to challenges. So, what are the six basic steps of the problem-solving process?

  • Identification: Recognize and define the problem.
  • Analysis: Understand the problem’s intricacies and nuances.
  • Generation of Alternatives: Think of different ways to approach the challenge.
  • Decision Making: Choose the most suitable method to address the problem.
  • Implementation: Put the chosen solution into action.
  • Evaluation: Reflect on the solution’s effectiveness and learn from the outcome.

By embedding these steps into mathematical education, we provide students with a structured framework. When they wonder about how to improve problem-solving skills or how to develop critical thinking skills in math, they can revert to this process, refining their approach with each new challenge.

Making Math Fun and Relevant

At Wonder Math, we believe that the key to developing robust problem-solving skills lies in making math enjoyable and pertinent. When students see math not just as numbers on a page but as a captivating story or a real-world problem to be solved, their engagement skyrockets. And with heightened engagement comes enhanced understanding.

As educators and parents, it’s crucial to continuously ask ourselves: how can we demonstrate to our children what problem-solving is? How can we best teach them how to develop critical thinking skills in math? And how can we instill in them an understanding of the six basic steps of the problem-solving process?

The answer, we believe, lies in active learning, contextual teaching, and a genuine passion for the beauty of mathematics.

The Underlying Beauty of Mathematics

Often, people perceive mathematics as a rigid discipline confined to numbers and formulas. However, this is a limited view. Math, in essence, is a language that describes patterns, relationships, and structures. It’s a medium through which we can communicate complex ideas, describe our universe, and solve intricate problems. Understanding this deeper beauty of math can further emphasize how to develop critical thinking skills in math.

Why Mathematics is the Ideal Playground for Problem-Solving

Math provides endless opportunities for problem-solving. From basic arithmetic puzzles to advanced calculus challenges, every math problem offers a chance to hone our problem-solving skills. But why is mathematics so effective in this regard?

  • Structured Challenges: Mathematics presents problems in a structured manner, allowing learners to systematically break them down. This format mimics real-world scenarios where understanding the structure of a challenge can be half the battle.
  • Multiple Approaches: Most math problems can be approached in various ways . This teaches learners flexibility in thinking and the ability to view a single issue from multiple angles.
  • Immediate Feedback: Unlike many real-world problems where solutions might take time to show results, in math, students often get immediate feedback. They can quickly gauge if their approach works or if they need to rethink their strategy.

Enhancing the Learning Environment

To genuinely harness the power of mathematics in developing problem-solving skills, the learning environment plays a crucial role. A student who is afraid of making mistakes will hesitate to try out different approaches, stunting their critical thinking growth.

However, in a nurturing, supportive environment where mistakes are seen as learning opportunities, students thrive. They become more willing to take risks, try unconventional solutions, and learn from missteps. This mindset, where failure is not feared but embraced as a part of the learning journey, is pivotal for developing robust problem-solving skills.

Incorporating Technology

In our digital age, technology offers innovative ways to explore math. Interactive apps and online platforms can provide dynamic problem-solving scenarios, making the process even more engaging. These tools can simulate real-world challenges, allowing students to apply their math skills in diverse contexts, further answering the question of how to improve problem-solving skills.

More than Numbers 

In summary, mathematics is more than just numbers and formulas—it’s a world filled with challenges, patterns, and beauty. By understanding its depth and leveraging its structured nature, we can provide learners with the perfect platform to develop critical thinking and problem-solving skills. The key lies in blending traditional techniques with modern tools, creating a holistic learning environment that fosters growth, curiosity, and a lifelong love for learning.

Join us on this transformative journey at Wonder Math. Let’s make math an adventure, teaching our children not just numbers and equations, but also how to improve problem-solving skills and navigate the world with confidence. Enroll your child today and witness the magic of mathematics unfold before your eyes!

FAQ: Mathematics and Critical Thinking

1. what is problem-solving in the context of mathematics.

Problem-solving in mathematics refers to the process of identifying a mathematical challenge and systematically working through methods and strategies to find a solution.

2. Why is math considered a good avenue for developing problem-solving skills?

Mathematics provides structured challenges and allows for multiple approaches to find solutions. This promotes flexibility in thinking and encourages learners to view problems from various angles.

3. How does contextual learning enhance problem-solving abilities?

By teaching math within a story or real-life scenario, it becomes more relevant for the learner. This helps them see math as a tool to navigate real-world challenges , thereby promoting critical thinking.

4. What are the six basic steps of the problem-solving process in math?

The six steps are: Identification, Analysis, Generation of Alternatives, Decision Making, Implementation, and Evaluation.

5. How can parents support their children in developing mathematical problem-solving skills?

Parents can provide real-life contexts for math problems , encourage open discussions about different methods, and ensure a supportive environment where mistakes are seen as learning opportunities.

6. Are there any tools or apps that can help in enhancing problem-solving skills in math?

Yes, there are various interactive apps and online platforms designed specifically for math learning. These tools provide dynamic problem-solving scenarios and simulate real-world challenges, making the learning process engaging.

7. How does group discussion foster critical thinking in math?

Group discussions allow students to hear different perspectives and approaches to a problem. This can challenge their own understanding and push them to think about alternative methods.

8. Is it necessary to always follow the six steps of the problem-solving process sequentially?

While the six steps provide a structured approach, real-life problem-solving can sometimes be more fluid. It’s beneficial to know the steps, but adaptability and responsiveness to the situation are also crucial.

9. How does Wonder Math incorporate active learning in teaching mathematics?

Wonder Math integrates mathematics within engaging stories and real-world scenarios, making it fun and relevant. This active learning approach ensures that students are not just passive recipients but active participants in the learning process.

10. What if my child finds a math problem too challenging and becomes demotivated?

It’s essential to create a supportive environment where challenges are seen as growth opportunities. Remind them that every problem is a chance to learn, and it’s okay to seek help or approach it differently.

Related posts

Internet search for math tutoring near me.

Math Tutoring Near Me: 5 Tips to Find The Best Math Tutor for Your Child

In the vibrant world of education, where the quest for knowledge knows no bounds, parents often find themselves searching for the perfect support system to enhance their child’s learning journey. This is especially true in the realm of mathematics, a subject that is crucial yet challenging for many students. Wonder Math, a pioneer in developing mathematical thinkers from second through…

Young girl student with headphones experiencing tutoring services online with her computer.

Tutoring Services Online: 10 Things All Parents Should Beware Of

As the world of education continually evolves, the realm of tutoring services, especially tutoring services online, has become an invaluable resource for parents seeking to bolster their children’s learning. Wonder Math, a pioneer in developing mathematical thinkers from second through fifth grade through story-based active learning, highlights the importance of vigilance when selecting online tutoring services. In this comprehensive guide,…

Generation Ready

Mathematics as a Complex Problem-Solving Activity

By jacob klerlein and sheena hervey, generation ready.

By the time young children enter school they are already well along the pathway to becoming problem solvers. From birth, children are learning how to learn: they respond to their environment and the reactions of others. This making sense of experience is an ongoing, recursive process. We have known for a long time that reading is a complex problem-solving activity. More recently, teachers have come to understand that becoming mathematically literate is also a complex problem-solving activity that increases in power and flexibility when practiced more often. A problem in mathematics is any situation that must be resolved using mathematical tools but for which there is no immediately obvious strategy. If the way forward is obvious, it’s not a problem—it is a straightforward application.

Mathematicians have always understood that problem-solving is central to their discipline because without a problem there is no mathematics. Problem-solving has played a central role in the thinking of educational theorists ever since the publication of Pólya’s book “How to Solve It,” in 1945. The National Council of Teachers of Mathematics (NCTM) has been consistently advocating for problem-solving for nearly 40 years, while international trends in mathematics teaching have shown an increased focus on problem-solving and mathematical modeling beginning in the early 1990s. As educators internationally became increasingly aware that providing problem-solving experiences is critical if students are to be able to use and apply mathematical knowledge in meaningful ways (Wu and Zhang 2006) little changed at the school level in the United States.

“Problem-solving is not only a goal of learning mathematics, but also a major means of doing so.”

(NCTM, 2000, p. 52)

In 2011 the Common Core State Standards incorporated the NCTM Process Standards of problem-solving, reasoning and proof, communication, representation, and connections into the Standards for Mathematical Practice. For many teachers of mathematics this was the first time they had been expected to incorporate student collaboration and discourse with problem-solving. This practice requires teaching in profoundly different ways as schools moved from a teacher-directed to a more dialogic approach to teaching and learning. The challenge for teachers is to teach students not only to solve problems but also to learn about mathematics through problem-solving. While many students may develop procedural fluency, they often lack the deep conceptual understanding necessary to solve new problems or make connections between mathematical ideas.

“A problem-solving curriculum, however, requires a different role from the teacher. Rather than directing a lesson, the teacher needs to provide time for students to grapple with problems, search for strategies and solutions on their own, and learn to evaluate their own results. Although the teacher needs to be very much present, the primary focus in the class needs to be on the students’ thinking processes.”

(Burns, 2000, p. 29)

Learning to problem solve

To understand how students become problem solvers we need to look at the theories that underpin learning in mathematics. These include recognition of the developmental aspects of learning and the essential fact that students actively engage in learning mathematics through “doing, talking, reflecting, discussing, observing, investigating, listening, and reasoning” (Copley, 2000, p. 29). The concept of co-construction of learning is the basis for the theory. Moreover, we know that each student is on their unique path of development.

Beliefs underpinning effective teaching of mathematics

  • Every student’s identity, language, and culture need to be respected and valued.
  • Every student has the right to access effective mathematics education.
  • Every student can become a successful learner of mathematics.

Children arrive at school with intuitive mathematical understandings. A teacher needs to connect with and build on those understandings through experiences that allow students to explore mathematics and to communicate their ideas in a meaningful dialogue with the teacher and their peers.

Learning takes place within social settings (Vygotsky, 1978). Students construct understandings through engagement with problems and interaction with others in these activities. Through these social interactions, students feel that they can take risks, try new strategies, and give and receive feedback. They learn cooperatively as they share a range of points of view or discuss ways of solving a problem. It is through talking about problems and discussing their ideas that children construct knowledge and acquire the language to make sense of experiences.

Students acquire their understanding of mathematics and develop problem-solving skills as a result of solving problems, rather than being taught something directly (Hiebert1997). The teacher’s role is to construct problems and present situations that provide a forum in which problem-solving can occur.

Why is problem-solving important?

Our students live in an information and technology-based society where they need to be able to think critically about complex issues, and “analyze and think logically about new situations, devise unspecified solution procedures, and communicate their solution clearly and convincingly to others” (Baroody, 1998). Mathematics education is important not only because of the “gatekeeping role that mathematics plays in students’ access to educational and economic opportunities,” but also because the problem-solving processes and the acquisition of problem-solving strategies equips students for life beyond school (Cobb, & Hodge, 2002).

The importance of problem-solving in learning mathematics comes from the belief that mathematics is primarily about reasoning, not memorization. Problem-solving allows students to develop understanding and explain the processes used to arrive at solutions, rather than remembering and applying a set of procedures. It is through problem-solving that students develop a deeper understanding of mathematical concepts, become more engaged, and appreciate the relevance and usefulness of mathematics (Wu and Zhang 2006). Problem-solving in mathematics supports the development of:

  • The ability to think creatively, critically, and logically
  • The ability to structure and organize
  • The ability to process information
  • Enjoyment of an intellectual challenge
  • The skills to solve problems that help them to investigate and understand the world

Problem-solving should underlie all aspects of mathematics teaching in order to give students the experience of the power of mathematics in the world around them. This method allows students to see problem-solving as a vehicle to construct, evaluate, and refine their theories about mathematics and the theories of others.

Problems that are “Problematic”

The teacher’s expectations of the students are essential. Students only learn to handle complex problems by being exposed to them. Students need to have opportunities to work on complex tasks rather than a series of simple tasks devolved from a complex task. This is important for stimulating the students’ mathematical reasoning and building durable mathematical knowledge (Anthony and Walshaw, 2007). The challenge for teachers is ensuring the problems they set are designed to support mathematics learning and are appropriate and challenging for all students.  The problems need to be difficult enough to provide a challenge but not so difficult that students can’t succeed. Teachers who get this right create resilient problem solvers who know that with perseverance they can succeed. Problems need to be within the students’ “Zone of Proximal Development” (Vygotsky 1968). These types of complex problems will provide opportunities for discussion and learning.

Students will have opportunities to explain their ideas, respond to the ideas of others, and challenge their thinking. Those students who think math is all about the “correct” answer will need support and encouragement to take risks. Tolerance of difficulty is essential in a problem-solving disposition because being “stuck” is an inevitable stage in resolving just about any problem. Getting unstuck typically takes time and involves trying a variety of approaches. Students need to learn this experientially. Effective problems:

  • Are accessible and extendable
  • Allow individuals to make decisions
  • Promote discussion and communication
  • Encourage originality and invention
  • Encourage “what if?” and “what if not?” questions
  • Contain an element of surprise (Adapted from Ahmed, 1987)

“Students learn to problem solve in mathematics primarily through ‘doing, talking, reflecting, discussing, observing, investigating, listening, and reasoning.”

(Copley, 2000, p. 29)

“…as learners investigate together. It becomes a mini- society – a community of learners engaged in mathematical activity, discourse and reflection. Learners must be given the opportunity to act as mathematicians by allowing, supporting and challenging their ‘mathematizing’ of particular situations. The community provides an environment in which individual mathematical ideas can be expressed and tested against others’ ideas.…This enables learners to become clearer and more confident about what they know and understand.”

(Fosnot, 2005, p. 10)

Research shows that ‘classrooms where the orientation consistently defines task outcomes in terms of the answers rather than the thinking processes entailed in reaching the answers negatively affects the thinking processes and mathematical identities of learners’ (Anthony and Walshaw, 2007, page 122).

Effective teachers model good problem-solving habits for their students. Their questions are designed to help children use a variety of strategies and materials to solve problems. Students often want to begin without a plan in mind. Through appropriate questions, the teacher gives students some structure for beginning the problem without telling them exactly what to do. In 1945 Pólya published the following four principles of problem-solving to support teachers with helping their students.

  • Understand and explore the problem
  • Find a strategy
  • Use the strategy to solve the problem
  • Look back and reflect on the solution

Problem-solving is not linear but rather a complex, interactive process. Students move backward and forward between and across Pólya’s phases. The Common Core State Standards describe the process as follows:

“Mathematically proficient students start by explaining to themselves the meaning of a problem and looking for entry points to its solution. They analyze givens, constraints, relationships, and goals. They make conjectures about the form and meaning of the solution and plan a solution pathway rather than simply jumping into a solution attempt. They consider analogous problems, and try special cases and simpler forms of the original problem in order to gain insight into its solution. They monitor and evaluate their progress and change course if necessary”. (New York State Next Generation Mathematics Learning Standards 2017).

Pólya’s Principals of Problem-Solving

Polyas principles of problem solving graphic

Students move forward and backward as they move through the problem-solving process.

The goal is for students to have a range of strategies they use to solve problems and understand that there may be more than one solution. It is important to realize that the process is just as important, if not more important, than arriving at a solution, for it is in the solution process that students uncover the mathematics. Arriving at an answer isn’t the end of the process. Reflecting on the strategies used to solve the problem provides additional learning experiences. Studying the approach used for one problem helps students become more comfortable with using that strategy in a variety of other situations.

When making sense of ideas, students need opportunities to work both independently and collaboratively. There will be times when students need to be able to work independently and other times when they will need to be able to work in small groups so that they can share ideas and learn with and from others.

Getting real

Effective teachers of mathematics create purposeful learning experiences for students through solving problems in relevant and meaningful contexts. While word problems are a way of putting mathematics into contexts, it doesn’t automatically make them real. The challenge for teachers is to provide students with problems that draw on their experience of reality, rather than asking them to suspend it. Realistic does not mean that problems necessarily involve real contexts, but rather they make students think in “real” ways.

Planning for talk

By planning for and promoting discourse, teachers can actively engage students in mathematical thinking. In discourse-rich mathematics classes, students explain and discuss the strategies and processes they use in solving mathematical problems, thereby connecting their everyday language with the specialized vocabulary of mathematics.

Students need to understand how to communicate mathematically, give sound mathematical explanations, and justify their solutions. Effective teachers encourage their students to communicate their ideas orally, in writing, and by using a variety of representations. Through listening to students, teachers can better understand what their students know and misconceptions they may have. It is the misconceptions that provide a window into the students’ learning process. Effective teachers view thinking as “the process of understanding,” they can use their students’ thinking as a resource for further learning. Such teachers are responsive both to their students and to the discipline of mathematics.

“Mathematics today requires not only computational skills but also the ability
to think and reason mathematically in order to solve the new problems and learn the new ideas that students will face in the future. Learning is enhanced in classrooms where students are required to evaluate their own ideas and those of others, are encouraged to make mathematical conjectures and test them, and are helped to develop their reasoning skills.”

(John Van De Walle)

“Equity. Excellence in mathematics education requires equity—high expectations and strong support for all students.”

How teachers organize classroom instruction is very much dependent on what they know and believe about mathematics and on what they understand about mathematics teaching and learning. Teachers need to recognize that problem-solving processes develop over time and are significantly improved by effective teaching practices. The teacher’s role begins with selecting rich problem-solving tasks that focus on the mathematics the teacher wants their students to explore. A problem-solving approach is not only a way for developing students’ thinking, but it also provides a context for learning mathematical concepts. Problem-solving allows students to transfer what they have already learned to unfamiliar situations. A problem-solving approach provides a way for students to actively construct their ideas about mathematics and to take responsibility for their learning. The challenge for mathematics teachers is to develop the students’ mathematical thinking process alongside the knowledge and to create opportunities to present even routine mathematics tasks in problem-solving contexts.

Given the efforts to date to include problem-solving as an integral component of the mathematics curriculum and the limited implementation in classrooms, it will take more than rhetoric to achieve this goal. While providing valuable professional learning, resources, and more time are essential steps, it is possible that problem-solving in mathematics will only become valued when high-stakes assessment reflects the importance of students’ solving of complex problems.

U.S. flag

An official website of the United States government

The .gov means it’s official. Federal government websites often end in .gov or .mil. Before sharing sensitive information, make sure you’re on a federal government site.

The site is secure. The https:// ensures that you are connecting to the official website and that any information you provide is encrypted and transmitted securely.

  • Publications
  • Account settings
  • Advanced Search
  • Journal List
  • v.9(5); 2023 May
  • PMC10208825

Logo of heliyon

Development and differences in mathematical problem-solving skills: A cross-sectional study of differences in demographic backgrounds

Ijtihadi kamilia amalina.

a Doctoral School of Education, University of Szeged, Hungary

Tibor Vidákovich

b Institute of Education, University of Szeged, Hungary

Associated Data

Data will be made available on request.

Problem-solving skills are the most applicable cognitive tool in mathematics, and improving the problem-solving skills of students is a primary aim of education. However, teachers need to know the best period of development and the differences among students to determine the best teaching and learning methods. This study aims to investigate the development and differences in mathematical problem-solving skills of students based on their grades, gender, and school locations. A scenario-based mathematical essay test was administered to 1067 students in grades 7–9 from schools in east Java, Indonesia, and their scores were converted into a logit scale for statistical analysis. The results of a one-way analysis of variance and an independent sample t -test showed that the students had an average level of mathematical problem-solving skills. The number of students who failed increased with the problem-solving phase. The students showed development of problem-solving skills from grade 7 to grade 8 but not in grade 9. A similar pattern of development was observed in the subsample of urban students, both male and female. The demographic background had a significant effect, as students from urban schools outperformed students from rural schools, and female students outperformed male students. The development of problem-solving skills in each phase as well as the effects of the demographic background of the participants were thoroughly examined. Further studies are needed with participants of more varied backgrounds.

1. Introduction

Problem-solving skills are a complex set of cognitive, behavioral, and attitudinal components that are situational and dependent on thorough knowledge and experience [ 1 , 2 ]. Problem-solving skills are acquired over time and are the most widely applicable cognitive tool [ 3 ]. Problem-solving skills are particularly important in mathematics education [ 3 , 4 ]. The development of mathematical problem-solving skills can differ based on age, gender stereotypes, and school locations [ [5] , [6] , [7] , [8] , [9] , [10] ]. Fostering the development of mathematical problem-solving skills is a major goal of educational systems because they provide a tool for success [ 3 , 11 ]. Mathematical problem-solving skills are developed through explicit training and enriching materials [ 12 ]. Teachers must understand how student profiles influence the development of mathematical problem-solving skills to optimize their teaching methods.

Various studies on the development of mathematical problem-solving skills have yielded mixed results. Grissom [ 13 ] concluded that problem-solving skills were fixed and immutable. Meanwhile, other researchers argued that problem-solving skills developed over time and were modifiable, providing an opportunity for their enhancement through targeted educational intervention when problem-solving skills developed quickly [ 3 , 4 , 12 ]. Tracing the development of mathematical problem-solving skills is crucial. Further, the results of previous studies are debatable, necessitating a comprehensive study in the development of students’ mathematical problem-solving skills.

Differences in mathematical problem-solving skills have been identified based on gender and school location [ [6] , [7] , [8] , [9] , [10] ]. School location affects school segregation and school quality [ 9 , 14 ]. The socioeconomic and sociocultural characteristics of a residential area where a school is located are the factors affecting academic achievement [ 14 ]. Studies in several countries have shown that students in urban schools demonstrated better performance and problem-solving skills in mathematics [ 9 , 10 , 15 ]. However, contradictory results have been obtained for other countries [ 6 , 10 ].

Studies on gender differences have shown that male students outperform female students in mathematics, which has piqued the interest of psychologists, sociologists, and educators [ 7 , 16 , 17 ]. The differences appear to be because of brain structure; however, sociologists argue that gender equality can be achieved by providing equal educational opportunities [ 8 , 16 , 18 , 19 ]. Because the results are debatable and no studies on gender differences across grades in schools have been conducted, it would be interesting to investigate gender differences in mathematical problem-solving skills.

Based on the previous explanations, teachers need to understand the best time for students to develop mathematical problem-solving skills because problem-solving is an obligatory mathematics skill to be mastered. However, no relevant studies focused on Indonesia have been conducted regarding the mathematical problem-solving skill development of students in middle school that can provide the necessary information for teachers. Further, middle school is the important first phase of developing critical thinking skills; thus relevant studies are required in this case [ 3 , 4 ]. In addition, a municipal policy-making system can raise differences in problem-solving skills based on different demographic backgrounds [ 10 ]. Moreover, the results of previous studies regarding the development and differences in mathematical problem-solving skills are debatable. Thus, the present study has been conducted to meet these gaps. This study investigated the development of mathematical problem-solving skills in students and the differences owing demographic backgrounds. Three aspects were considered: (1) student profiles of mathematical problem-solving skills, (2) development of their mathematical problem-solving skills across grades, and (3) significant differences in mathematical problem-solving skills based on gender and school location. The results of the present study will provide detailed information regarding the subsample that contributes to the development of mathematical problem-solving skills in students based on their demographic backgrounds. In addition, the description of the score is in the form of a logit scale from large-scale data providing consistent meaning and confident generalization. This study can be used to determine appropriate teaching and learning in the best period of students’ development in mathematical problem-solving skills as well as policies to achieve educational equality.

2. Theoretical background

2.1. mathematical problem-solving skills and their development.

Solving mathematical problems is a complex cognitive ability that requires students to understand the problem as well as apply mathematical concepts to them [ 20 ]. Researchers have described the phases of solving a mathematical problem as understanding the problem, devising a plan, conducting out the plan, and looking back [ [20] , [24] , [21] , [22] , [23] ]. Because mathematical problems are complex, students may struggle with several phases, including applying mathematical knowledge, determining the concepts to use, and stating mathematical sentences (e.g., arithmetic) [ 20 ]. Studies have concluded that more students fail at later stages of the solution process [ 25 , 26 ]. In other words, fewer students fail in the phase of understanding a problem than during the plan implementation phase. Different studies have stated that students face difficulties in understanding the problem, determining what to assume, and investigating relevant information [ 27 ]. This makes them unable to translate the problem into a mathematical form.

Age or grade is viewed as one factor that influences mathematical problem-solving skills because the skills of the students improve over time as a result of the teaching and learning processes [ 28 ]. Neuroscience research has shown that older students have fewer problems with arithmetic than younger students; however, the hemispheric asymmetry is reduced [ 29 ]. In other words, older students are more proficient, but their flexibility to switch among different strategies is less. Ameer & Sigh [ 28 ] obtained similar results and found a considerable difference in mathematical achievement; specifically, older students performed better than younger students in number sense and computation using one-way analysis of variance (ANOVA) ( F ) of F (2,411) = 4.82, p  < 0.01. Molnár et al. [ 3 ] found that the student grade affects domain-specific and complex problem-solving skills. They observed that the development of problem-solving skills was noticeable across grades in elementary school but stopped in secondary school. The fastest development of domain-specific problem-solving occurred in grades 7 and 8 [ 3 ], but the fastest development of complex problem-solving occurred in grades 5–7 [ 3 ]. No development was detected between grades 4 and 5 as well as grades 6 and 7 for domain-specific and complex problem-solving skills, respectively. Similarly, Greiff et al. [ 4 ] concluded that students developed problem-solving skills across grades 5–11 with older students being more skilled. However, the grade 9 students deviated from the development pattern, and their problem-solving skills dropped. The theories from Molnár et al. [ 3 ] and Greiff et al. [ 4 ] are the benchmark cases herein.

The above studies showed that problem-solving skills mostly developed during compulsory schooling and developed most quickly in specific grades. This indicates that specific development times can be targeted to enhance the problem-solving skills [ 3 ]. However, Jabor et al. [ 30 ] observed contradictory results showing statistically significant differences with small effects in mathematical performance between age groups: those under the age of 19 outperformed those over the age of 19 years old. Grissom [ 13 ] observed a negative correlation between age and school achievement that remained constant over time.

2.2. Effects of school location and gender on mathematical problem-solving skills

School location has been shown to affect mathematical achievement [ 9 , 14 ]. In 15 countries, students in rural schools performed considerably worse than students in urban schools in mathematics [ 9 , 10 ], science and reading [ 9 ]. In addition, Nepal [ 15 ] discovered that urban students significantly outperformed rural students in mathematical problem-solving skills ( t  = −5.11, p  < 0.001) and achievement ( t  = −4.45, p  < 0.001) using the results of an independent sample t -test (t). However, other countries have found that rural students outperformed urban students in mathematics [ 6 , 10 ]. These variations may be attributed to a lack of instructional resources (e.g., facilities, materials, and programs), professional training (e.g., poorly trained teachers), and progressive instruction [ 6 ]. The results of Williams's study [ 10 ] serve as the basis for the current study.

Gender differences in mathematics have received attention because studies show that male students outperform female students on higher-level cognitive tasks [ 31 ]. This is a shift from a meta-analysis study that found gender differences in mathematics to be insignificant and favored female students [ 32 ]. At the college level, female students slightly outperform male students in computation while male students outperform female students in problem solving. However, no gender differences have been observed among elementary and middle school students. This result was strengthened by other meta-analysis studies [ 7 , 8 ], which concluded that there was no gender difference in mathematical performance and problem-solving skills [ 15 , [33] , [35] , [34] ]. Gender similarity in mathematics is achieved when equal learning opportunities and educational choices are provided and the curriculum is expanded to include the needs and interests of the students [ 16 , 18 , 31 ].

From a sociological perspective, gender similarity in mathematics makes sense. If there is a gender difference in mathematics, this has been attributed to science, technology, engineering, and mathematics (STEM) being stereotyped as a male domain [ 8 ]. Stereotypes influence beliefs and self-efficacy of students and perceptions of their own abilities [ 8 , 19 ]. This is the reason for the low interest of female students in advanced mathematics courses [ 18 , 19 ]. However, Halpern et al. [ 16 ] found that more female students are entering many occupations that require a high level of mathematical knowledge. Moreover, Anjum [ 36 ] found that female students outperformed male students in mathematics. This may be because female students prepared better than the male students before the test and were more thorough [ 36 , 37 ]. The study of Anjum [ 36 ] is one of the basis cases of the current study.

Differences in brain structure support the argument that there are gender differences in mathematical performance [ 16 , 17 ]. Females have less brain lateralization (i.e., symmetric left and right hemispheres), which helps them perform better verbally. Meanwhile, males have more brain lateralization, which is important for spatial tasks [ 17 ]. In addition, the male hormone testosterone slows the development of the left hemisphere [ 16 ], which improves the performance of right brain-dominant mathematical reasoning and spatial tasks.

3.1. Instrumentation

In this study, a science-related mathematical problem-solving test was used. This is a mathematics essay test where the problems are in the form of scenarios related to environmental management. Problems are solved by using technology as a tool (e.g., calculator, grid paper). The test was developed in an interdisciplinary STEM framework, and it is targeted toward grades 7–9. There were six scenarios in total: some were given to multiple grades, and others were specific to a grade. They included ecofriendly packaging (grade 7), school park (grade 7), calorie vs. greenhouse gas emissions (grades 7–9), floodwater reservoir (grade 8), city park (grades 8–9), and infiltration well (grade 9). These scenarios cover topics such as number and measurement, ratio and proportion, geometry, and statistics. Every scenario had a challenge, and students were provided with eight metacognitive prompt items to help them explore their problem-solving skills.

The test was administered by using paper and pencils for a 3-h period with a break every hour. At the end of the test, students were asked to fill in their demographic information. Each prompt item had a maximum score of 5 points: a complete and correct answer (5 points), a complete answer with a minor error (4 points), an incomplete answer with a minor error (3 points), an incomplete answer with a major error (2 points), and a completely wrong and irrelevant answer (1 point). Each scenario had a maximum total score of 40 points.

The test was validated to determine whether it contained good and acceptable psychometric evidence. It had an acceptable content validity index (CVI >0.67), moderate intraclass correlation coefficient (ICC) (rxx = 0.63), and acceptable Cronbach's alpha (α = 0.84). The construct validity indicated all scenarios and prompt items were fit (0.77 ≤ weighted mean square ≤1.59) with an acceptable discrimination value (0.48 ≤ discrimination value ≤ 0.93), acceptable behavior of the rating score, and good reliability (scenario reliability = 0.86; prompt item reliability = 0.94).

3.2. Participants

The test was administered to grades 7–9 students in east Java, Indonesia (n = 1067). The students were selected from A-accreditation schools in urban and rural areas; random classes were selected for each grade. The majority of the students were Javanese (95.01%), with the remainder being Madurese (3.3%) and other ethnicities. Table 1 describes the demographics of the participants.

Demographic characteristics of participants.

3.3. Data analysis

Data were collected between July and September 2022. Prior to data collection, ethical approval was sought from the institutional review board (IRB) of the Doctoral School of Education, University of Szeged and was granted with the ethical approval number of 7/2022. In addition, permission letters were sent to several schools to request permission and confirm their participation. The test answers of the students were scored by two raters – the first author of this study and a rater with master's degree in mathematics education – to ensure that the rating scale was consistently implemented. The results showed good consistency with an ICC of 0.992 and Cronbach's alpha of 0.996.

The scores from one of the raters were converted to a logit scale by weighted likelihood estimation (WLE) using the ConQuest software. A logit scale provides a consistent value or meaning in the form of intervals. The logit scale represents the unit interval between locations on the person–item map. WLE was chosen rather than maximum likelihood estimation (MLE) because WLE is more central than MLE, which helps to correct for bias [ 38 ]. The WLE scale was represented by using descriptive statistics to profile the students' mathematical problem-solving skills in terms of the percentage, mean score ( M ) and standard deviation ( SD ) for each phase. The WLE scale was also used to describe common difficulties for each phase. The development of students’ mathematical problem-solving skills across grades was presented by a pirate plot, which is used in R to visualize the relationship between 1 and 3 categorical independent variables and 1 continuous dependent variable. It was chosen because it displays raw data, descriptive statistics, and inferential statistics at the same time. The data analysis was performed using R studio version 4.1.3 software with the YaRrr package. A one-way ANOVA was performed to find significant differences across grades. An independent sample t -test was used to analyze significant differences based on gender and school location. The descriptive statistics, one-way ANOVA test, and independent sample t -test were performed using the IBM SPSS Statistics 25 software.

4.1. Student profiles

The scores of students were converted to the WLE scale, where a score of zero represented a student with average ability, a positive score indicated above-average ability, and a negative score indicated below-average ability. A higher score indicated higher ability. The mean score represented a student with average mathematical problem-solving skills ( M  = 0.001, SD  = 0.39). Overall, 52.1% of students had a score below zero. The distribution of scores among students was predominantly in the interval between −1 and 0. When the problem-solving process was analyzed by phase, the results showed that exploring and understanding were the most mastered problem-solving skills ( M  = 0.24, SD  = 0.51). Only 27.9% of students had below-average scores for the exploring and understanding phases, which indicates that they mostly understood the given problem and recognized the important information. However, the problem-solving skills decreased with higher phases. The students had below-average abilities in the phases of representing and formulating ( M  = −0.01, SD  = 0.36), planning and executing ( M  = −0.15, SD  = 0.41), and monitoring and reflecting ( M  = −0.16, SD  = 0.36). About 57.9% of the students had below-average scores for the representing and formulating phase, which indicates that they had problems making hypotheses regarding science phenomena, representing problems in mathematical form, and designing a prototype. The obvious reason for their difficulty with making hypotheses was that they did not understand simple concepts of science (e.g., CO 2 vs. O 2 ). In the planning and executing phase, 66.8% of the students failed to achieve a score greater than zero. This happened because they failed to apply mathematical concepts and procedures. Because they were unable to plan and execute a strategy, this affected the next phase of the problem-solving process. In the monitoring and reflecting phase, 68.0% of the students had a below-average score.

4.2. Development of mathematical problem-solving skills across grades

The development of the mathematical problem-solving skills of the students across grades was observed based on the increase in the mean score. The problem-solving skills developed from grade 7 to grade 8. The students of grade 7 had a mean score of −0.04 while grade 8 students had the highest mean score of 0.03. The students in grades 7 and 8 also showed more varied problem-solving skills than the grade 9 students did. In contrast, the grade 9 students showed a different pattern of development, and their mean score dropped to 0.01. Although the difference was not large, further analysis was needed to determine its significance.

Fig. 1 displays the development of the mathematical problem-solving skills of the students. The dots represent raw data or WLE scores. The middle line shows the mean score. The beans represent a smoothed density curve showing the full data distribution. The scores of the students in grades 7 and 9 were concentrated in the interval between −0.5 and 0. However, the scores of the grade 8 students were concentrated in the interval between 0 and 0.5. The scores of the students in grades 7 and 8 showed a wider distribution than those of the grade 9 students. The bands which overlap with the line representing the mean score, define the inference around the mean (i.e., 95% of the data are in this interval). The inference of the WLE score was close to the mean.

Fig. 1

Differences in students' mathematical problem-solving skills across grades.

Note : PS: Problem-Solving Skills of Students.

The one-way ANOVA results indicated a significant difference among the problem-solving skills of the students of grades 7–9 ( F (1,066) = 3.01, p  = 0.046). The students of grade 8 showed a significant difference in problem-solving skills and outperformed the other students. The students of grades 7 and 9 showed no significant difference in their mathematical problem-solving skills. Table 2 presents the one-way ANOVA results of the mathematical problem-solving skills across grades.

One-way ANOVA results of the mathematical problem-solving across grades.

Note. Post hoc test: Dunnett's T3. 7, 8, and 9: subsample grade. <: direction of significant difference ( p  < 0.05).

Fig. 2 shows the development of the mathematical problem-solving skills of the students across grades based on school location and gender. The problem-solving skills of the urban students increased from a mean score of 0.07 in grade 7 to 0.14 in grade 8. However, the mean score of urban students in grade 9 dropped. In contrast, the mean scores of the rural students increased continuously with grade. The improvements were significant for both the rural ( F (426) = 10.10, p  < 0.001) and urban ( F (639) = 6.10, p  < 0.01) students. For the rural students, grade 9 students showed a significant difference in problem-solving skills. In contrast, urban students in grades 8 and 9 showed significant differences in problem-solving skills but not in grade 7.

Fig. 2

Differences in students' mathematical problem-solving skills across grades and different demographic backgrounds.

(a) Differences in students grade 7 of mathematical problem-solving skills across grades and different demographic backgrounds

(b) Differences in students grade 8 of mathematical problem-solving skills across grades and different demographic backgrounds

(c) Differences in students grade 9 of mathematical problem-solving skills across grades and different demographic backgrounds

Note: WLE_PS: The students' problem-solving skills in WLE scale; F: Female; M: Male; ScLoc: School location; R: Rural; U: Urban.

When divided by gender, both female and male students showed improvements in their problem-solving skills from grades 7 and 8. However, female students in grade 9 showed a stable score while the scores of male students in grade 9 declined. Only male students in grade 7 showed a significant difference in the mean score. In urban schools, the scores of male and female students increased and decreased, respectively, from grade 7 to grade 8. Male students in rural schools showed an increase in score from grade 7 to grade 9. However, the scores of female students in rural schools decreased from grade 7 to grade 8. Table 3 presents the one-way ANOVA results for the mathematical problem-solving skills of the students considering gender and school location.

One-way ANOVA results for mathematical problem-solving skills across grades and different demographic backgrounds.

Fig. 2 shows that the distributions of the male and female scores of students were similar for every grade except rural grade 9 students. The scores of the rural female students were concentrated in the interval between 0 and 0.5 while the scores of the rural male students were mostly below 0. The scores of rural students in grade 7 and urban students in grade 9 (both male and female) were concentrated in the interval between −0.5 and 0. The scores of urban students in grades 7 and 8 were concentrated in the interval between −0.5 and 0.5.

Fig. 3 shows a detailed analysis of the development of mathematical problem-solving skills across grades for each phase of the problem-solving process. Similar patterns were observed in the exploring and understanding and the representing and formulating phases: the mean score increased from grade 7 to grade 8 but decreased from grade 8 to grade 9. Grade 8 students had the highest mean score and differed significantly from the scores of students in other grades.

Fig. 3

Differences in students' mathematical problem-solving skills in every phase across grades: (1) Exploring & understanding, (2) Representing & formulating, (3) Planning & executing, (4) Monitoring & reflecting.

(a) Differences in students' mathematical problem-solving skills in exploring and understanding phase

(b) Differences in students' mathematical problem-solving skills in representing and formulating phase

(c) Differences in students' mathematical problem-solving skills in planning and executing phase

(d) Differences in students' mathematical problem-solving skills in monitoring and reflecting phase

Note: WLE_Exp_Un: The WLE score in exploring and understanding; WLE_Rep_For: The WLE score in representing and formulating; WLE_Plan_Ex: The WLE score in planning and executing; WLE_Mon_Ref: The WLE score in monitoring and reflecting.

The scores of the students for the planning and executing phase increased with grade. However, the difference was only significant at grade 9. Grades 7 and 8 students showed an increase in score, but the improvement was not significant. There was no pattern detected in the monitoring and reflecting phase. The score was stable for grades 7 and 8 students but improved for grade 9 students. The mean score for each phase and the one-way ANOVA results are presented in Table 4 .

One-way ANOVA results for every phase of problem-solving across grades.

Fig. 3 shows that the distributions of the problem-solving skills of the students were similar across grades and phases. However, the distributions were different for grade 9 students in the representing and formulating, planning and executing, and monitoring and reflecting phases, where 95% of the data were in the interval between −0.5 and 0.5.

4.3. Effects of demographic background

4.3.1. school location.

The mathematical problem-solving skills of the students differed significantly based on school location. Urban students scored higher than rural students. The results of the t -test for mathematical problem-solving skills based on school location are presented in Table 5 .

T-test results for mathematical problem-solving skills based on school location.

The effects of the school's location on the performances of male and female students were analyzed. The results showed that the scores of the female students differed significantly based on school location ( t (613) = −6.09, p  < 0.001). Female students in urban schools ( M  = 0.18, SD  = 0.39) outperformed female students in rural schools ( M  = −0.08, SD  = 0.37). Similar results were observed for male students with urban students ( M  = −0.01, SD  = 0.35) outperforming rural students ( M  = −0.12, SD  = 0.39) by a significant margin ( t (382.764) = −3.25, p  < 0.01).

When analyzed by grade, grades 7 and 8 students contributed to the difference based on school location with t (377.952) = −6.34, p  < 0.001 and t (300.070) = −5.04, p  < 0.001, respectively. Urban students in grades 7 and 8 performed significantly better than their rural counterparts did. However, there was no significant difference between rural and urban students in grade 9 ( t (354) = 0.71, p  = 0.447).

4.3.2. Gender

Male and female students showed a significant difference in their mathematical problem-solving skills. Overall, female students outperformed male students. The detailed results of the independent sample t -test for mathematical problem-solving skills based on gender are presented in Table 6 .

T-test results for mathematical problem-solving skills based on gender.

The results were analyzed to determine whether the school location contributed to the gender difference. The gender difference was most significant among urban students ( t (596.796) = −4.36, p  < 0.001). Female students from urban schools ( M  = 0.12, SD  = 0.39) outperformed male students from urban schools ( M  = −0.01, SD  = 0.35). There was no significant difference between female and male students from rural schools ( t (425) = −1.31, p  = 0.191).

Grades 7 and 9 students contributed to the gender difference with t (372.996) = −3.90, p  < 0.001 and t (354) = −2.73, p  < 0.01, respectively. Female students in grades 7 and 9 outperformed their male counterparts. However, there was no significant gender difference among grade 8 students ( t (329) = −0.10, p  = 0.323).

5. Discussion

The mathematical problem-solving skills of the students were categorized as average. In addition, the difficulties of students increased in line with the problem-solving phase. Fewer students failed the exploring and understanding phase than the subsequent phases. This confirms the results of previous studies indicating that more students failed further along the problem-solving process [ 25 , 26 ]. Because the problem-solving process is sequential, students who have difficulty understanding a problem will fail the subsequent phases [ 27 ].

The development of mathematical problem-solving skills was evaluated according to the mean WLE score. The mathematical problem-solving skills of the students developed from grade 7 to grade 8 based on the increase in their mean scores. However, the development dropped in grade 9. This agrees with previous results that concluded that higher grades had the highest problem-solving skills, but the fastest skill development took place in grades 7–8 after which it dropped [ 3 , 4 ]. These results indicate that the mathematical problem-solving skills of the students should improve and be strengthened in grades 7–8, which will help them perform better in grade 9.

In this study, the effects of the demographic background of the students were analyzed in detail, which is an aspect missing from previous studies. The results showed that the mathematical problem-solving skills of urban students increased from grade 7 to grade 8 but decreased in grade 9. The same pattern was found among male and female students. However, a different pattern was observed for rural students, where the skills of grade 9 students continued to increase. The different patterns may be attributed to a structural reorganization of cognitive processes at a particular age [ 3 ]. However, more research is needed on the effects of the demographic backgrounds of students on mathematical problem-solving skills. These results were different from previous results because the previous studies only analyzed the development in general, without focusing on their demographic background. Hence, different patterns of development were observed when it was thoroughly examined.

Because solving problems is a cognitive process, the development of problem-solving skills for particular phases and processes needed to be analyzed. The students showed the same pattern for knowledge acquisition (i.e., exploring and understanding, and representing and formulating phases), with an increase in skill from grade 7 to grade 8 but a decrease in grade 9. However, the students showed increasing skill in knowledge application (i.e., planning and executing, as well as monitoring and reflecting phases) across grades. This means that the difference between the mean scores in grade 9 was not significant across phases. Grade 9 students had lower scores than grade 8 students for the knowledge acquisition phase but higher scores for the knowledge application phase. In contrast, the gap between the mean scores of grades 7 and 8 was large across phases.

These results proved that there is a significant difference in the mathematical problem-solving skills of students based on their demographic backgrounds. The urban students outperformed rural students, which confirms the results of previous studies [ 9 , 10 , 15 ]. The difference can be attributed to the availability of facilities, teacher quality, and interactive teaching and learning instruction [ 6 ]. In Indonesia, the policies for the public educational system for middle schools are set at the municipal level. This means that each city has its own policies for teacher training, teacher recruitment, teaching and learning processes, facilities, etc. Urban schools mostly have stricter policies as well as various programs to help students improve their knowledge and skills. In addition, they have supportive facilities for teaching and learning. This unequal environment is the strongest reason for the difference in mathematical problem-solving skills.

The results were analyzed in detail to observe which groups in the rural and urban schools contributed to the difference. Both male and female students in urban schools performed better than their counterparts in rural schools did. In addition, urban students in grades 7 and 8 outperformed their rural counterparts. There was no significant difference between urban and rural students in grade 9. This may be because grade 9 is the last grade in middle school, so students have to prepare for high school entrance requirements, including exam and/or grade point average scores. Hence, both rural and urban schools focus much effort on the teaching and learning process in this grade.

In this study, the female students surprisingly had better mathematical problem-solving skills than the male students did. This confirmed the results of the meta-analysis by Hyde et al. [ 32 ] and study by Anjum [ 36 ], which found that female students slightly outperformed male students in mathematics. This difference may be because of motivation and attitude [ 39 , 40 ]. Female Indonesian students are typically more diligent, thorough, responsible, persistent, and serious with their tasks.

A detailed analysis was performed to evaluate which group of students contributed to the gender differences. The results showed that female students outperformed male students in urban schools. This may be because male students at urban schools typically display an unserious attitude toward low-stake tests. In addition, female students outperformed their male counterparts in grades 7 and 9. The reason for this difference requires further analysis.

6. Conclusion

Studying the problem-solving skills of students is crucial to facilitating their development. In this study, the conclusions are presented as follows:

  • • The mathematical problem-solving skills of the students were categorized as average. More students failed at higher phases of the problem-solving process.
  • • Students showed development of their mathematical problem-solving skills from grade 7 to grade 8 but a decline in grade 9. The same pattern was detected across grades for urban students, both female and male. However, the problem-solving skills of rural students increased with the grade.
  • • A similar development was observed for the individual problem-solving phases. In the knowledge acquisition phase, the problem-solving skills of the students developed from grade 7 to grade 8 but decreased in grade 9. However, problem-solving skills increased across grades in the knowledge application phase.
  • • The school location was shown to have a significant effect on the mathematical problem-solving skills of the students. Urban students generally outperform students in rural schools. However, gender and grade contributed to differences in mathematical problem-solving skills based on school location. Female and male urban students in grades 7 and 8 outperformed their rural counterparts.
  • • In general, female students outperformed male students in mathematical problem-solving skills, particularly those from urban schools and in grades 7 and 9.

The sampling method and the number of demographic backgrounds limited the scope of this study. Only students from A-accreditation schools were selected because higher-order problem-solving skills were considered assets. Moreover, the study only included three demographic factors: grade, gender, and school location. More demographic information, such as school type, can be added (public or private schools). Hence, future studies will need to broaden the sample size and consider more demographic factors. Despite these limitations, this study can help teachers determine the best period for enhancing the development of mathematical problem-solving skills. Moreover, the differences in mathematical problem-solving skills due to demographic background can be used as a basis for educational policymakers and teachers to provide equal opportunity and equitable education to students.

Author contribution statement

Ijtihadi Kamilia Amalina: Conceived and designed the experiments; Performed the experiments; Analyzed and interpreted the data; Contributed reagents, materials, analysis tools or data; Wrote the paper.

Tibor Vidákovich: Conceived and designed the experiments; Contributed reagents, materials, analysis tools or data.

Funding statement

This work was supported by University of Szeged Open Access Fund with the grant number of 6020.

Data availability statement

Additional information.

No additional information is available for this paper.

Declaration of competing interest

No potential conflict of interest was reported by the authors.

Teaching support from the UK’s largest provider of in-school maths tuition

blogs read

resources downloaded

one to one lessons

one to one lessons

schools supported

schools supported

Built by teachers for teachers

In-school online one to one maths tuition developed by maths teachers and pedagogy experts

Hundreds of FREE online maths resources!

Daily activities, ready-to-go lesson slides, SATs revision packs, video CPD and more!

Hundreds of FREE online maths resources!

Maths Problem Solving: Engaging Your Students And Strengthening Their Mathematical Skills

Meriel willatt.

Maths problem solving can be challenging for pupils. There’s no ‘one size fits all’ approach or strategy and questions often combine different topic areas. Pupils often don’t know where to start. It’s no surprise that problem solving is a common topic teachers struggle to teach effectively to their pupils.

In this blog, we consider the importance of problem solving and share with you some ideas and resources for you to tackle problem solving in your maths classroom, from KS2 up to GCSE.

What is maths problem solving?

Why is maths problem solving so difficult, how to develop problem solving skills in maths, maths problem solving ks2, maths problem solving ks3, maths problem solving gcse.

Maths problem solving is when a mathematical task challenges pupils to apply their knowledge, logic and reasoning in unfamiliar contexts. Problem solving questions often combine several elements of maths.

We know from talking to the hundreds of school leaders and maths teachers that we work with as one to one online maths tutoring providers that this is one of their biggest challenges: equipping pupils with the skills and confidence necessary to approach problem solving questions.

The Ultimate Guide to Problem Solving Techniques

Download these 9 ready-to-go problem solving techniques that every pupil should know

The challenge with problem solving in maths is that there is no generic problem solving skill that can be taught in an isolated maths lesson. It’s a skill that teachers must explicitly teach to pupils, embed into their learning and revisit often.

When pupils are first introduced to a topic, they cannot start problem solving straight away using it. Problem solving relies on deep knowledge of concepts. Pupils need to become familiar with it and practice using it in different contexts before they can make connections, reason and problem solve with it. In fact, some researchers suggest that it could take up to two years to do this (Burkhardt, 2017). 

At Third Space Learning, we specialise in online one to one maths tutoring for schools, from KS1 all the way up to GCSE. Our lessons are designed by maths teachers and pedagogy experts to break down complex problems into their constituent parts. Our specialist tutors then carefully scaffold learning to build students’ confidence in key skills before combining them to tackle problem solving questions.

sample problem solving maths lessons

In order to develop problem solving skills in maths, pupils need lots of different contexts and word problems in which to practise them and the opportunity to engage in mathematical talk that draws on their metacognitive skills. 

The EEF suggests that to develop problem solving skills in maths, teachers need to teach pupils:

  • To use different approaches to problem solving
  • Use worked examples
  • To use metacognition to plan, monitor and reflect on their approaches to problem solving

Below, we take a closer look at problem solving at each stage, from primary school all the way to GCSEs. We’ve also included links to maths resources and CPD to support you and your team’s classroom teaching.

At lower KS2, the National Curriculum states that pupils should develop their ability to solve a range of problems. However, these will involve simple calculations as pupils develop their numeracy skills. As pupils progress to upper KS2, the demand for problem solving skills increases. 

“At this stage, pupils should develop their ability to solve a wider range of problems, including increasingly complex properties of numbers and arithmetic, and problems demanding efficient written and mental methods of calculation. With this foundation in arithmetic, pupils are introduced to the language of algebra as a means for solving a variety of problems.” National curriculum in England: mathematics programmes of study (Upper key stage 2 – years 5 and 6)

KS2 problem solving can often fall into the trap of relying on acronyms, such as RICE, RIDE or even QUACK. The most popular is RUCSAC (Read, Underline, Calculate, Solve, Answer, Check). While these do aim to simplify the process for young minds, it encourages a superficial, formulaic approach to problem solving, rather than deep mathematical thinking. Also, consider how much is wrapped up within the word ‘solve’ – is this helpful?

We teach thousands of pupils KS2 maths problem solving skills every week through our one to one online tutoring programme for maths. In our interventions, we encourage deep mathematical thinking by using a simplified version of George Polya’s four stages of problem solving. Here are the four stages:

Understand the problem

  • Devise a strategy for solving it
  • Carry out the problem solving strategy
  • Check the result

We use UCR as a simplified model: Understand, Communicate & Reflect. You may choose to adapt this depending on the age and ability of your class.

For example:

Maisy, Heidi and Freddie are children in the same family. The product of their ages is a score. How old might they be?

There are three people.

There are three numbers that multiply together to make twenty (a score is equal to 20). There will be lots of answers, but no ‘right’ answer.

Communicate

To solve the word problem we need to find the numbers that will go into 20 without a remainder (the factors).

The factors of 20 are 1, 2, 4, 5, 10 and 20.

Combinations of numbers that could work are: 1, 1, 20 1, 2, 10 1, 4, 5 2, 2, 5.

The question says children, which means ‘under 18 years’, so that would mean we could remove 1, 1, 20 from our list of possibilities. 

In our sessions, we create a nurturing learning environment where pupils feel safe to make mistakes. This is so important in the context of problem solving as the best problem solvers will be resilient and able to overcome challenges in the ‘Reflect’ stage. Read more: What is a growth mindset

Looking for more support teaching KS2 problem solving? We’ve developed a powerpoint on problem solving, reasoning and planning for depth that is designed to be used as CPD by primary school teachers, maths leads and SLT. 

The resource reflects on how metacognition can enhance reasoning and problem solving abilities, the ‘curse’ of real life maths (think ‘Carl buys 60 watermelons…) and how teachers can practically implement and teach strategies in the classroom.

You may also be interested in: 

  • Developing Thinking Skills At KS2
  • KS2 Maths Investigations
  • Word problems for Year 6

At KS3, the importance of seeing mathematical concepts as interconnected with other skills, including problem solving, is foregrounded. The National Curriculum also stresses the importance of a strong foundation in maths before moving on to complex problem solving.

“Mathematics is an interconnected subject in which pupils need to be able to move fluently between representations of mathematical ideas. The programme of study for key stage 3 is organised into apparently distinct domains, but pupils should build on key stage 2 and connections across mathematical ideas to develop fluency, mathematical reasoning and competence in solving increasingly sophisticated problems” National curriculum in England: mathematics programmes of study (Key stage 3)

“Decisions about progression should be based on the security of pupils’ understanding and their readiness to progress to the next stage. Pupils who grasp concepts rapidly should be challenged through being offered rich and sophisticated problems before any acceleration through new content in preparation for key stage 4.” National curriculum in England: mathematics programmes of study (Key stage 3)

For many students, the transition from primary to secondary school can be a huge challenge.

Especially in the aftermath of the Covid-19 pandemic and the resultant school closures, students may arrive into Year 7 with various learning gaps and misconceptions that will hold them. Some students may need focused support to plug these gaps and grow in confidence.

You can give pupils a smoother transition from KS2 to KS3 with personalised one to one online tuition with specialist tutors with Third Space Learning. Our lessons cover content from Years 5-7 and build a solid foundation for pupils to develop their problem solving skills. Pupils are supported towards independent practice through worked examples, questioning and support slides.

KS3 problem solving maths activities

The challenge for KS3 maths problem solving activities is that learners may struggle to get invested unless you start with a convincing hook. Engage your young mathematicians on topics you know well or you know they’ll be invested in and try your hand at designing your own mathematical problems. Alternatively, get some inspiration from our crossover ability and fun maths problems .

Since the new GCSE specification began in 2015, there has been an increased focus on non-routine problem solving questions. These questions demand students to make sense of lots of new information at once before they even move on to selecting the strategies they’ll use to find the correct answer. This is where many learners get stuck.

In recent years, teachers and researchers in pedagogy (including Ofsted) have recognised that open ended problem solving tasks do not in fact lead to improved student understanding. While they may be enjoyable and engage learners, they may not lead to improved results.

SSDD problems (Same Surface Different Depth) can offer a solution that develops students’ critical thinking skills, while ensuring they engage fully with the information they’re provided. The idea behind them is to provide a set of questions that look the same and use the same mathematical hook but each question requires a different mathematical process to be solved.

ssdd questions example problem solving maths

Read more about SSDD problems , tips on writing your own questions and download free printable examples. There are also plenty of more examples on the NRICH website.

Worked examples, careful questioning and constructing visual representations can help students to convert the information embedded in a maths challenge into mathematical notations. Read our blog on problem solving maths questions for Foundation, Crossover & Higher examples, worked solutions and strategies.

Remember that students can only move on to mathematics problem solving once they have secure knowledge in a topic. If you know there are areas your students need extra support, check our Secondary Maths Resources library for revision guides, teaching resources and worksheets for KS3 and GCSE topics.

Do you have students who need extra support in maths? Every week Third Space Learning’s maths specialist tutors support thousands of students across hundreds of schools with weekly online 1-to-1 lessons and maths interventions designed to address learning gaps and boost progress. Since 2013 we’ve helped over 150,000 primary and secondary students become more confident, able mathematicians. Learn more or request a personalised quote for your school to speak to us about your school’s needs and how we can help.

Subsidised one to one maths tutoring from the UK’s most affordable DfE-approved one to one tutoring provider.

Related Articles

Yr7 Maths Test OG image

FREE Guide to Maths Mastery

All you need to know to successfully implement a mastery approach to mathematics in your primary school, at whatever stage of your journey.

Ideal for running staff meetings on mastery or sense checking your own approach to mastery.

Privacy Overview

  • Grade 1 Lessons
  • Grade 2 Lessons
  • Grade 3 Lessons
  • Grade 4 Lessons
  • Grade 5 Lessons
  • Math Activities

How to Improve Problem-Solving Skills in Math

what are the problem solving skills in mathematics

Importance of Problem-Solving Skills in Math

Problem-solving skills are crucial in math education , enabling students to apply mathematical concepts and principles to real-world situations. Here’s why problem-solving skills are essential in math education:

1. Application of knowledge: Problem-solving in math requires encouraging students to apply the knowledge they acquire in the classroom to tackle real-life problems. It helps them understand the relevance of math in everyday life and enhances their critical thinking skills.

2. Developing critical thinking:  Problem-solving requires students to analyze, evaluate, and think critically about different approaches and strategies to solve a problem. It strengthens their mathematical abilities and improves their overall critical thinking skills.

3. Enhancing problem-solving skills:  Math problems often have multiple solutions, encouraging students to think creatively and explore different problem-solving strategies. It helps develop their problem-solving skills, which are valuable in various aspects of life beyond math.

4. Fostering perseverance:  Problem-solving in math often requires persistence and resilience. Students must be willing to try different approaches, learn from their mistakes, and keep trying until they find a solution. It fosters a growth mindset and teaches them the value of perseverance.

Benefits of strong problem-solving skills

Having strong problem-solving skills in math offers numerous benefits for students:

1. Improved academic performance:  Students with strong problem-solving skills are likelier to excel in math and other subjects that rely on logical reasoning and critical thinking.

2. Enhanced problem-solving abilities:  Strong problem-solving skills extend beyond math and can be applied to various real-life situations. It includes decision-making, analytical thinking, and solving complex problems creatively.

3. Increased confidence:  Successfully solving math problems boosts students’ self-confidence and encourages them to tackle more challenging tasks. This confidence spills over into other areas of their academic and personal lives.

4. Preparation for future careers:  Problem-solving skills are highly sought after by employers in various fields. Developing strong problem-solving skills in math sets students up for successful careers in engineering, technology, finance, and more.

Problem-solving skills are essential for math education and have numerous benefits for students. By fostering these skills, educators can empower students to become confident, critical thinkers who can apply their mathematical knowledge to solve real-world problems.

Understand the Problem

Breaking down the problem and identifying the key components.

To improve problem-solving math skills, it’s essential to first understand the problem at hand. Here are some tips to help break down the problem and identify its key components:

1. Read the problem carefully:  Take your time to read it attentively and ensure you understand what it asks. Pay attention to keywords or phrases that indicate what mathematical operation or concept to use.

2. Identify the known and unknown variables:  Determine what information is already given in the problem (known variables) and what you need to find (unknown variables). This step will help you analyze the problem more effectively.

3. Define the problem in your own words:  Restate the problem using your own words to ensure you clearly understand what needs to be solved. It can help you focus on the main objective and eliminate any distractions.

4. Break the problem into smaller parts:  Complex math problems can sometimes be overwhelming. Breaking them down into smaller, manageable parts can make them more approachable. Identify any sub-problems or intermediate steps that must be solved before reaching the final solution.

Reading and interpreting math word problems effectively

Many math problems are presented as word problems requiring reading and interpreting skills. Here are some strategies to help you effectively understand and solve math word problems:

1. Highlight key information:  As you read the word problem, underline or highlight any important details, such as numbers, units of measurement, or specific keywords related to mathematical operations.

2. Visualize the problem:  Create visual representations, such as diagrams or graphs, to help you understand the problem better. Visualizing the problem can make determining what steps to take and how to approach the solution easier.

3. Translate words into equations:  Convert the information in the word problem into mathematical equations or expressions. This translation step helps you transform the problem into a solvable math equation.

4. Solve step by step:  Break down the problem into smaller steps and solve each step individually. This approach helps you avoid confusion and progress toward the correct solution.

Improving problem-solving skills in math requires practice and patience. By understanding the problem thoroughly, breaking it into manageable parts, and effectively interpreting word problems, you can confidently enhance your ability to solve math problems.

Use Visual Representations

Using diagrams, charts, and graphs to visualize the problem.

One effective way to improve problem-solving skills in math is to utilize visual representations. Visual representations , such as diagrams, charts, and graphs, can help make complex problems more tangible and easily understood. Here are some ways to use visual representations in problem-solving:

1. Draw Diagrams:  When faced with a word problem or a complex mathematical concept, drawing a diagram can help break down the problem into more manageable parts. For example, suppose you are dealing with a geometry problem. In that case, sketching the shapes involved can provide valuable insights and help you visualize the problem better.

2. Create Charts or Tables:  For problems that involve data or quantitative information, creating charts or tables can help organize the data and identify patterns or trends. It can be particularly useful in analyzing data from surveys, experiments, or real-life scenarios.

3. Graphical Representations:  Graphs can be powerful tools in problem-solving, especially when dealing with functions, equations, or mathematical relationships. Graphically representing data or equations makes it easier to identify key features that may be hard to spot from a numerical representation alone, such as intercepts or trends.

Benefits of visual representation in problem-solving

Using visual representations in problem-solving offers several benefits:

1. Enhances Comprehension:  Visual representations provide a visual context for abstract mathematical concepts, making them easier to understand and grasp.

2. Encourages Critical Thinking:  Visual representations require active engagement and critical thinking skills. Students can enhance their problem-solving and critical thinking abilities by analyzing and interpreting visual data.

3. Promotes Pattern Recognition: Visual representations simplify identifying patterns, trends, and relationships within data or mathematical concepts. It can lead to more efficient problem-solving and a deeper understanding of mathematical principles.

4. Facilitates Communication:  Visual representations can be shared and discussed, helping students communicate their thoughts and ideas effectively. It can be particularly useful in collaborative problem-solving environments.

Incorporating visual representations into math problem-solving can significantly enhance understanding, critical thinking, pattern recognition, and communication skills. Students can approach math problems with a fresh perspective and improve their problem-solving abilities using visual tools.

Work Backwards

Understanding the concept of working backward in math problem-solving.

Working backward is a problem-solving strategy that starts with the solution and returns to the given problem. This approach can be particularly useful in math, as it helps students break down complex problems into smaller, more manageable steps. Here’s how to apply the concept of working backward in math problem-solving:

1. Identify the desired outcome : Start by clearly defining the goal or solution you are trying to reach. It could be finding the value of an unknown variable, determining a specific measurement, or solving for a particular quantity.

2. Visualize the result : Imagine the final step or solution. It will help you create a mental image of the steps needed to reach that outcome.

3. Trace the steps backward : Break down the problem into smaller steps, working backward from the desired outcome. Think about what needs to happen immediately before reaching the final solution and continue tracing the steps back to the beginning of the problem.

4. Check your work : Once you have worked backward to the beginning of the problem, double-check your calculations and steps to ensure accuracy.

Real-life examples and applications of working backward

Working backward is a valuable problem-solving technique in math and has real-life applications. Here are a few examples:

1. Financial planning : When creating a budget, you can work backward by determining your desired savings or spending amount and then calculating how much income or expenses are needed to reach that goal.

2. Project management : When planning a project, you can work backward by setting a fixed deadline and then determining the necessary steps and timelines to complete the project on time.

3. Game strategy : In games like chess or poker, working backward can help you anticipate your opponent’s moves and plan your strategy accordingly.

4. Recipe adjustments : When modifying a recipe, you can work backward by envisioning the final taste or texture you want to achieve and adjusting the ingredients or cooking methods accordingly.

By practicing working backward in math and applying it to real-life situations, you can enhance your problem-solving abilities and find creative solutions to various challenges.

Try Different Strategies

When solving math problems, it’s essential to have a repertoire of problem-solving strategies. You can improve your problem-solving skills and tackle various mathematical challenges by trying different approaches. Here are some strategies to consider:

Exploring Various Problem-Solving Strategies

1. Guess and Check:  This strategy involves making an educated guess and checking if it leads to the correct solution. It can be useful when dealing with trial-and-error problems.

2. Drawing a Diagram:  Visually representing the problem through diagrams or graphs can help you understand and solve it more effectively. This strategy is particularly useful in geometry and algebraic reasoning.

3. Using Logic:  Using logical reasoning is useful for breaking down complicated problems into smaller, more manageable components. This strategy is especially useful in mathematical proofs and logical puzzles.

4. Working Backwards:  Start with the desired outcome and return to the given information. When dealing with equations or word problems, this approach can assist.

5. Using Patterns:  Look for patterns and relationships within the problem to determine a solution. This approach can be used for different mathematical problems, such as sequences and numerical patterns.

When and How to Apply Different Strategies in Math Problem-Solving

Knowing when and how to apply different problem-solving strategies is crucial for success in math. Here are some tips:

  • Understand the problem: Read the problem carefully and identify the key information and requirements.
  • Select an appropriate strategy: Choose the most appropriate problem-solving strategy for the problem.
  • Apply the chosen strategy: Implement the selected strategy, following the necessary steps.
  • Check your solution: Verify your answer by double-checking the calculations or applying alternative methods.
  • Reflect on the process: After solving the problem, take a moment to reflect and evaluate your problem-solving approach. Identify areas for improvement and consider alternative strategies that could have been used.

By exploring different problem-solving strategies and applying them to various math problems, you can enhance your problem-solving skills and develop a versatile toolkit for tackling mathematical challenges. Practice and persistence are key to honing your problem-solving abilities in math.

Key takeaways and tips for improving problem-solving skills in math

In conclusion, developing strong problem-solving skills in math is crucial for success in this subject. Here are some key takeaways and tips to help you improve your problem-solving abilities:

  • Practice regularly:  The more you practice solving math problems, the better you will become at identifying patterns, applying strategies, and finding solutions.
  • Break down the problem:  When faced with a complex math problem, break it into smaller, more manageable parts. It will make it easier to understand and solve.
  • Understand the problem:  Before diving into a solution, fully understand the problem. Identify what information is given and what you are asked to find.
  • Draw diagrams or visualize:  Use visual aids, such as diagrams or sketches, to help you better understand the problem and visualize the solution.
  • Use logical reasoning:  Apply logical reasoning skills to analyze the problem and determine the most appropriate approach or strategy.
  • Try different strategies:  If one approach doesn’t work, don’t be afraid to try different strategies or methods. There are often multiple ways to solve a math problem.
  • Seek help and collaborate:  Don’t hesitate to seek help from your teacher, classmates, or online resources. Collaborating with others can provide different perspectives and insights.
  • Learn from mistakes:  Mistakes are a valuable learning opportunity. Analyze your mistakes, understand where you went wrong, and learn from them to avoid making the same errors in the future.
  • Grade 6 Lessons
  • Grade 7 Lessons
  • Grade 8 Lessons
  • Kindergarten
  • Math Lessons Online
  • Math Tutorial
  • Multiplication
  • Subtraction
  • #basic mathematic
  • #Basic Mathematical Operation
  • #best math online math tutor
  • #Best Math OnlineTutor
  • #dividing fractions
  • #effective teaching
  • #grade 8 math lessons
  • #linear equation
  • #Math Online Blog
  • #mathematical rule
  • #mutiplying fractions
  • #odd and even numbers
  • #Online Math Tutor
  • #online teaching
  • #order of math operations
  • #pemdas rule
  • #Point-Slope Form
  • #Precalculus
  • #Slope-Intercept Form
  • #Tutoring Kids

LearnZoe Logo

Thank you for signing up!

GET IN TOUCH WITH US

Building Problem-solving skills for math

Building Problem-solving Skills for 7th-Grade Math

Mathematics is a subject that requires problem-solving skills to excel. In 7th grade, students begin to encounter more complex math concepts, and the ability to analyze and solve problems becomes increasingly important. Building problem-solving skills for math not only helps students to master math concepts but also prepares them for success in higher-level math courses and in life beyond academics. 

In this article, we will several key skills that are needed for success in 7th-grade math, and also explore how they can benefit students both academically and personally. We will also provide tips and strategies to help students develop and improve their problem-solving skills. Let’s dive in!

Building Analytical Skills

what are the problem solving skills in mathematics

The first of seven important skills to build is that of analytical skills. These allow students to analyze a problem and break it down into smaller parts. From there, they’re able to identify the key components that need to be addressed. Analytical skills also hone students’ abilities to identify patterns. Students should be able to identify patterns in mathematical data, such as in number sequences, geometric shapes, and graphs. Importantly, students should not just be able to recognize the pattens, but they should be able to describe them (more on that in communication) and use them to make predictions and solve problems.

We alluded to this earlier, but breaking down problems is an essential component of analytical skills. Students with strong analytical skills can break problems down into smaller and more manageable parts. They are then able to identify key components of a problem and use this information to develop a strategy for solving it. 

Along with identifying patterns comes identifying relationships. Students with good mathematical analytical skills can identify relationships between different mathematical concepts, such as the relationship between addition and subtraction, or the relationship between angles and shapes. Through strengthening this skill, students will be able to describe these relationships and use them to solve problems. 

An important part of analytical skills is the ability to analyze data. Students should be able to analyzeand interpret data presented in a variety of formats, such as graphs, charts, and tables. They should be able to use this data to make predictions, draw conclusions, and solve problems.

Speaking of conclusions, reaching sound conclusions based on mathematical data is a fundamental skill needed for making predictions based on trends in a graph, or drawing inferences from a set of data.

Another skill students should master is the ability to compare and contrast mathematical concepts, such as the properties of different shapes or the strategies for solving different types of problems. Through this, they’ll be able to use the information they gather to solve problems. 

With all these skills at play comes arguably the most important: Critical thinking. This is an indicator that a student really grasps the concepts and it’s just repeating them back to you on command. Critical thinking is the ability to evaluate information and arguments, and make judgements and decisions based on evidence, and apply logic and reasoning to solve problems.

Building Creative Thinking

what are the problem solving skills in mathematics

This is the ability for students (or anyone, really) to think outside the box and come up with innovative solutions to problems. This involves being able to approach problems from different angles and to consider multiple perspectives. For a 7th-grader, this skill can be exercised through the following:

  • Thinking Outside the Box: Students should be encouraged to think creatively and come up with innovative solutions to problems. This involves thinking outside the box and considering multiple perspectives.
  • Finding Multiple Solutions: Students should be able to come up with multiple solutions to a problem and evaluate each one to determine which is the most effective.
  • Developing Original Ideas: Students should be able to develop original ideas and approaches to solving problems. This involves being able to come up with unique and innovative solutions that may not have been tried before.
  • Making Connections: Students should be able to make connections between different mathematical concepts and apply these connections to solve problems. This involves looking for similarities and differences between concepts and using this information to make new connections.
  • Visualizing Solutions : Students should be able to visualize solutions to problems and use diagrams, charts, and other visual aids to help them solve problems.
  • Using Metaphors and Analogies: Students should be able to use metaphors and analogies to help them understand complex mathematical concepts. This involves using familiar concepts to explain unfamiliar ones and making connections between different ideas.

Building Problem-Solving Strategies

what are the problem solving skills in mathematics

It may sound like the same thing, but building problem-solving strategies is not the same as building problem-solving skills. Building strategies for problem-solving lends itself to actual problem-solving. Let’s expand on this: Say your student is presented a problem that they’re struggling with, these are some of the problem-solving strategies they may use in order to solve the puzzle.

  • Identify the problem: The first step in problem-solving is to identify the problem and understand what is being asked. Students should carefully read the problem and make sure they understand the question before attempting to solve it.
  • Draw a diagram: Students can draw a diagram to help visualize the problem and better understand the relationships between different parts of the problem.
  • Use logic: Students can use logic to identify patterns and relationships in the problem. They can use this information to develop a plan to solve the problem.
  • Break the problem down: Students can break a complex problem down into smaller, more manageable parts. They can then solve each part of the problem individually before combining the solutions to get the final answer.
  • Guess and check: Students can guess and check different solutions to the problem until they find the correct answer. This method involves trying different solutions and evaluating the results until the correct answer is found.
  • Use algebra: Algebraic equations can be used to solve a variety of mathematical problems. Students can use algebraic equations to represent the problem and solve for the unknown variable.
  • Work backward: Students can work backward from the final answer to determine the steps required to solve the problem. This method involves starting with the end goal and working backward to determine the steps needed to get there.

Building Persistence and Perseverance

what are the problem solving skills in mathematics

In an increasingly instant-gratification world with apps, searches and AI chatbots just a click away, this is an important skill not just in the math classroom, but for life in general. Problem-solving, whether that’s a math problem or a life challenge, often requires persistence and perseverance. Student need to learn to be able to stick with a problem even when it seems challenging, difficult, or seemingly impossible. Here are ways you can encourage your students to stick it out when working on problems:

  • Trying multiple approaches: When faced with a challenging problem, students can demonstrate persistence by trying multiple approaches until they find one that works. They don’t give up after one attempt but keep trying until they find a solution.
  • Reframing the problem: If a problem seems particularly difficult, students can demonstrate perseverance by reframing the problem in a different way. This can help them see the problem from a new perspective and come up with a different approach to solve it.
  • Asking for help: Sometimes, even with persistence, a problem may still be difficult to solve. In these cases, students can demonstrate perseverance by asking for help from their teacher or classmates. This shows that they are willing to put in the effort to find a solution, even if it means seeking assistance.
  • Learning from mistakes: Making mistakes is a natural part of the problem-solving process, but students can demonstrate persistence by learning from their mistakes and using them to improve their problem-solving skills. They don’t get discouraged by their mistakes, but instead, they use them as an opportunity to learn and grow.
  • Staying focused: In order to solve complex math problems, it’s important for students to stay focused and avoid distractions. Students can demonstrate perseverance by staying focused on the problem at hand and not getting distracted by other things.

Building Communication Skills

Communication is essential for building problem-solving skills for math

We alluded to this earlier, but a central part of building problem-solving skills is building the ability to articulate a problem or a solution. This isn’t just for the sake of personal understanding, but critical for collaboration. Students need to be able to explain their thinking, ask questions, and work with others to solve problems. Here are some examples of communication skills that can be used to build problem-solving skills:

  • Clarifying understanding: Students can ask questions to clarify their understanding of the problem. They can seek clarification from their teacher or classmates to ensure they are interpreting the problem correctly.
  • Explaining their reasoning: When solving a math problem, students can explain their reasoning to show how they arrived at a particular solution. This can help others understand their thought process and can also help students identify errors in their own work.
  • Collaborating with peers: Problem-solving can be a collaborative effort. Students can work together in groups to solve problems and communicate their ideas and solutions with each other. This can lead to a better understanding of the problem and can also help students learn from each other.
  • Writing clear explanations: When presenting their solutions to a math problem, students can write clear and concise explanations that are easy to understand. This can help others follow their thought process and can also help them communicate their ideas more effectively.
  • Using math vocabulary: Math has its own language and using math vocabulary correctly is essential for effective communication. Students can demonstrate their understanding of math concepts by using correct mathematical terms and symbols when explaining their solutions.

Building Mathematical Knowledge

Building problem-solving skills for math involves solid understanding of mathematical concepts

This would seem like a no-brainer, since you’re a math educator clicking on an article about building math problem-solving skills. However, it’s worth being explicit that problem-solving in math requires a solid understanding of mathematical concepts, including arithmetic, algebra, geometry, and data analysis. Students need to be able to apply these concepts to solve problems in real-world contexts.

7th-grade math covers a wide range of mathematical concepts and skills. Here are some examples of mathematical knowledge that 7th-grade math students should have:

  • Algebraic expressions and equations: Students should be able to write and simplify algebraic expressions and solve one-step and two-step equations.
  • Proportional relationships: Students should be able to understand and apply proportional relationships, including identifying proportional relationships in tables, graphs, and equations.
  • Geometry: Students should have a solid understanding of geometry concepts such as angles, triangles, quadrilaterals, circles, and transformations.
  • Statistics and probability: Students should be able to analyze and interpret data using measures of central tendency and variability, and understand basic probability concepts.
  • Rational numbers: Students should have a solid understanding of rational numbers, including ordering, adding, subtracting, multiplying, and dividing fractions and decimals.
  • Integers: Students should be able to perform operations with integers, including adding, subtracting, multiplying, and dividing.
  • Ratios and proportions: Students should be able to understand and use ratios and proportions in a variety of contexts, including scale drawings and maps.

In conclusion, problem-solving skills are essential for success in 7th grade math. Analytical skills, critical and creative thinking, problem-solving strategies, persistence, communication skills, and mathematical knowledge are all important components of effective problem-solving. By developing these skills, students can approach math problems with confidence and achieve their full potential.

If you enjoyed this read, be sure to browse more of our articles . More importantly, if you want to save yourself hours of preparation time by having full math curriculums, review guides and tests available at the click of a button, be sure to sign up to our 7th Grade Newsletter . You’ll receive loads of free lesson resources, tips and advice and exclusive subscription offers!

Images Sources

Featured image by Karla Hernandez on Unsplash

https://www.freepik.com/free-photo/boy-pretends-be-superhero-uses-his-mind-draw-concept_6170411.htm#query=child%20thinking&position=21&from_view=search&track=ais

https://www.freepik.com/free-photo/happy-asian-child-student-holding-light-bulb-with-schoolbag-isolated-yellow-background_26562776.htm#query=child%20thinking%20idea&position=1&from_view=search&track=ais

https://www.freepik.com/free-photo/girl-playing-with-cube-puzzle_1267051.htm#query=child%20building&position=14&from_view=search&track=ais

https://www.freepik.com/free-photo/adorable-girl-propping-up-her-head-with-fists-being-upset-dreaming_6511917.htm#page=2&query=child%20thinking&position=0&from_view=search&track=ais

https://www.freepik.com/free-photo/boys-doing-high-five_4350791.htm#page=2&query=child%20talking&position=2&from_view=search&track=ais

https://www.freepik.com/free-photo/schoolgirl-smiling-blackboard-class_1250271.htm#query=child%20math&position=13&from_view=search&track=ais

Share this:

  • Click to share on Twitter (Opens in new window)
  • Click to share on Facebook (Opens in new window)

Leave a Reply Cancel reply

Your email address will not be published. Required fields are marked *

Notify me of follow-up comments by email.

Notify me of new posts by email.

Teaching and Learning

Elevating math education through problem-based learning, by lisa matthews     feb 14, 2024.

Elevating Math Education Through Problem-Based Learning

Image Credit: rudall30 / Shutterstock

Imagine you are a mountaineer. Nothing excites you more than testing your skill, strength and resilience against some of the most extreme environments on the planet, and now you've decided to take on the greatest challenge of all: Everest, the tallest mountain in the world. You’ll be training for at least a year, slowly building up your endurance. Climbing Everest involves hiking for many hours per day, every day, for several weeks. How do you prepare for that?

The answer, as in many situations, lies in math. Climbers maximize their training by measuring their heart rate. When they train, they aim for a heart rate between 60 and 80 percent of their maximum. More than that, and they risk burning out. A heart rate below 60 percent means the training is too easy — they’ve got to push themselves harder. By combining this strategy with other types of training, overall fitness will increase over time, and eventually, climbers will be ready, in theory, for Everest.

what are the problem solving skills in mathematics

Knowledge Through Experience

The influence of constructivist theories has been instrumental in shaping PBL, from Jean Piaget's theory of cognitive development, which argues that knowledge is constructed through experiences and interactions , to Leslie P. Steffe’s work on the importance of students constructing their own mathematical understanding rather than passively receiving information .

You don't become a skilled mountain climber by just reading or watching others climb. You become proficient by hitting the mountains, climbing, facing challenges and getting right back up when you stumble. And that's how people learn math.

what are the problem solving skills in mathematics

So what makes PBL different? The key to making it work is introducing the right level of problem. Remember Vygotsky’s Zone of Proximal Development? It is essentially the space where learning and development occur most effectively – where the task is not so easy that it is boring but not so hard that it is discouraging. As with a mountaineer in training, that zone where the level of challenge is just right is where engagement really happens.

I’ve seen PBL build the confidence of students who thought they weren’t math people. It makes them feel capable and that their insights are valuable. They develop the most creative strategies; kids have said things that just blow my mind. All of a sudden, they are math people.

what are the problem solving skills in mathematics

Skills and Understanding

Despite the challenges, the trend toward PBL in math education has been growing , driven by evidence of its benefits in developing critical thinking, problem-solving skills and a deeper understanding of mathematical concepts, as well as building more positive math identities. The incorporation of PBL aligns well with the contemporary broader shift toward more student-centered, interactive and meaningful learning experiences. It has become an increasingly important component of effective math education, equipping students with the skills and understanding necessary for success in the 21st century.

At the heart of Imagine IM lies a commitment to providing students with opportunities for deep, active mathematics practice through problem-based learning. Imagine IM builds upon the problem-based pedagogy and instructional design of the renowned Illustrative Mathematics curriculum, adding a number of exclusive videos, digital interactives, design-enhanced print and hands-on tools.

The value of imagine im's enhancements is evident in the beautifully produced inspire math videos, from which the mountaineer scenario stems. inspire math videos showcase the math for each imagine im unit in a relevant and often unexpected real-world context to help spark curiosity. the videos use contexts from all around the world to make cross-curricular connections and increase engagement..

This article was sponsored by Imagine Learning and produced by the Solutions Studio team.

Imagine Learning

More from EdSurge

As States Make It Easier to Become a Teacher, Are They Reducing Barriers or Lowering the Bar?

Teacher Preparation

As states make it easier to become a teacher, are they reducing barriers or lowering the bar, by emily tate sullivan.

Computer Science Course Offerings in High School Spur More Students to Coding Degrees

Computer Science

Computer science course offerings in high school spur more students to coding degrees, by jeffrey r. young.

How a Culture of Caring Is Helping These Schools Improve Student Mental Health

Mental Health

How a culture of caring is helping these schools improve student mental health, by nadia tamez-robledo.

What If Myths, Metaphors and Riddles Are the Key to Reshaping K-12 Education?

EdSurge Podcast

What if myths, metaphors and riddles are the key to reshaping k-12 education.

Journalism that ignites your curiosity about education.

EdSurge is an editorially independent project of and

  • Product Index
  • Write for us
  • Advertising

FOLLOW EDSURGE

© 2024 All Rights Reserved

How can procedural flowcharts support the development of mathematics problem-solving skills?

  • Original Article
  • Open access
  • Published: 22 February 2024

Cite this article

You have full access to this open access article

  • Musarurwa David Chinofunga   ORCID: orcid.org/0000-0002-0262-3039 1 ,
  • Philemon Chigeza   ORCID: orcid.org/0000-0001-9964-0988 1 &
  • Subhashni Taylor   ORCID: orcid.org/0000-0002-1624-0901 1  

Supporting students’ problem-solving skills, solution planning and sequencing of different stages that are involved in successfully developing a meaningful solution to a problem has been a challenge for teachers. This case study was informed by reflective investigation methodology which explored how procedural flowcharts can support student mathematics problem solving in a senior Mathematical Methods subject in Queensland. The paper used thematic analysis to analyse and report on teachers’ perceptions of the utility of procedural flowcharts during problem solving as well as content analysis on how student-developed flowcharts can support their problem-solving skills. Results show that development of procedural flowcharts can support problem solving as it helps with integration of problem-solving stages.

Avoid common mistakes on your manuscript.

Introduction

Problem solving is central to teaching and learning of mathematics (see Cai, 2010 ; Lester, 2013 ; Schoenfeld et al., 2014 ). For decades, research in mathematics problem solving, including special issues from leading mathematics education journals (see, Educational Studies in Mathematics, (Vol. 83, no. 2013); The Mathematics Enthusiast, (Vol. 10, nos. 1–2); ZDM , (Vol. 39, nos. 5–6)), have offered significant insights but struggled to produce well-articulated guidelines for educational practice (English & Gainsburg, 2016 ). This could possibly be the reason why mathematics teachers’ efforts to improve students’ problem-solving skills have not produced the desired results (Anderson, 2014 ; English & Gainsburg, 2016 ). Despite Polya’s ( 1945 ) heuristics being so valuable in problem solving, there appears to be limited success when translated into the classroom environment (English & Gainsburg, 2016 ). English and Gainsburg went further to posit that one of the issues to be addressed is how to support problem-solving competency in students during the process of problem solving. Thus, teachers’ perceptions in this study are a valuable part in evaluating how procedural flowcharts can support problem solving.

The problem-solving process is a dialogue between the prior knowledge the problem solver possesses, the tentative plan of solving the problem and other relevant thoughts and facts (Schoenfeld, 1983 ). However, research is still needed on tools that teachers can use to support students during problem solving (Lester & Cai, 2016 ). Although research in mathematics problem solving has been progressing, it has remained largely theoretical (Lester, 2013 ). Schoenfeld ( 2013 ) suggests that research focus should now advance from the framework for examining problem solving to explore how ideas grow and are presented and shared during the problem-solving process. Recently, Kaitera and Harmoinen ( 2022 ) emphasised the need to support teachers through resources that can help students develop problem solving skills. They went on to posit that resources that can assist students in presenting different approaches to a solution and displaying their understanding are critical to build their problem-solving skills.

The study by Kaitera and Harmoinen ( 2022 ) introduced mathematics students to ‘problem-solving keys’ which are heuristics for problem solving that students are to follow as they engage with tasks. Their conclusion was also noted by Vale and Barbosa ( 2018 ) who observed that a key area that would benefit from further research is the identification of strategies or plan that support students’ ability to construct and present their mathematical knowledge effectively during problem solving, particularly if complex processes such as integration and modification of several procedures are involved. Similarly, students face challenges in connecting or bringing all the ideas together and showing how they relate as they work towards the solution (Reinholz, 2020 ). Problem solving in mathematics is challenging for students (Ahmad et al., 2010 ), and therefore, supporting students’ problem-solving skills needs urgent attention (Schoenfeld, 2016 ). Furthermore, Mason ( 2016 ) posits that the crucial yet not significantly understood issue for adopting a problem-solving approach to teaching is the issue of “when to introduce explanatory tasks, when to intervene and in what way” (p. 263). Therefore, teachers also need resources to support the teaching of problem-solving skills, often because they were not taught these approaches when they were school students (Kaitera & Harmoinen, 2022 ; Sakshaug & Wohlhuter, 2010 ).

Flowcharts have been widely used in problem solving across different fields. In a technology-rich learning environment such as Lego Robotics, creating flowcharts to explain processes was observed to facilitate understanding, thinking, making sense of how procedures relate, investigating and communicating the solution (Norton et al., 2007 ). They are effective in guiding students during problem solving (Gencer, 2023 ), enhancing achievement and improving problem-solving skills in game-based intelligent tutoring (Hooshyar et al., 2016 ). Flowcharts have been identified as an effective problem-solving tool in health administration (McGowan & Boscia, 2016 ). In mathematics education, heuristic trees and flowcharts were observed to supplement each other in influencing students’ problem solving behaviour (Bos & van den Bogaart, 2022 ). Importantly, McGowan and Boscia emphasised that “one of the greatest advantages of a flowchart is its ability to provide for the visualisation of complex processes, aiding in the understanding of the flow of work, identifying nonvalue-adding activities and areas of concern, and leading to improved problem-solving and decision-making” (p. 213). Identifying the most appropriate strategy and making the correct decision at the right stage are keys to problem solving. Teaching students to use visual representations like flowcharts as part of problem solving supports the ability to easily identify new relationships among different procedures and assess the solution being communicated faster as visual representations are more understandable (Vale et al., 2018 ).

The purpose of this case study was to explore, through an in-depth teacher’s interview, and student-developed artefacts, the utility of procedural flowcharts in supporting the development of students’ problem-solving skills in mathematics. The study will focus on problem solving in Mathematical Methods which is one of the calculus-based mathematics subjects at senior school in Queensland. The aim was to investigate if the development of procedural flowcharts supported students in planning, logically connecting and integrating mathematical procedures (knowledge) and to communicate the solution effectively during problem solving. The use of flowcharts in this study was underpinned by the understanding that visual aids that support cognitive processes and interlinking of ideas and procedures influence decision-making, which is vital in problem-based learning (McGowan & Boscia, 2016 ). Moreover, flowcharts are effective tools for communicating the processes that need to be followed in problem solving (Krohn, 1983 ).

Problem-solving learning in mathematics education

The drive to embrace a problem-solving approach to develop and deepen students’ mathematics knowledge has been a priority in mathematics education (Koellner et al., 2011 ; Sztajn et al., 2017 ). In the problem-solving approach, the teacher provides the problem to be investigated by students who then design ways to solve it (Colburn, 2000 ). To engage in problem solving, students are expected to use concepts and procedures that they have learnt (prior knowledge) and apply them in unfamiliar situations (Matty, 2016 ). Teachers are encouraged to promote problem-solving activities as they involve students engaging with a mathematics task where the procedure or method to the solution is not known in advance (National Council of Teachers of Mathematics [NCTM], 2000 ), thus providing opportunities for deep understanding as well as providing students with the opportunity to develop a unique solution (Queensland Curriculum and Assessment Authority [QCAA], 2018 ). Using this approach, students are given a more active role through applying and adapting procedures to solve a non-routine problem and then communicating the method (Karp & Wasserman, 2015 ). The central role problem solving plays in developing students’ mathematical understanding has resulted in the development of different problem-solving models over the years.

The process of problem solving in mathematics requires knowledge to be organised as the solution is developed and then communicated. Polya is among the first to systematise problem solving in mathematics (Voskoglou, 2021 ). Students need to understand the problem, plan the solution, execute the plan and reflect on the solution and process (Polya, 1971 ). Voskoglou’s ( 2021 ) problem-solving model emphasised that the process of modelling involves analysis of problem, mathematisation, solution development, validation and implementation. Similarly, problem solving is guided by four phases: discover, devise, develop and defend (Makar, 2012 ). During problem solving, students engage with an unfamiliar real-world problem, develop plans in response, justify mathematically through representation, then evaluate and communicate the solution (Artigue & Blomhøj, 2013 ). Furthermore, Schoenfeld ( 1980 ) posited that problem solving involves problem analysis, exploration, design, implementation and verification of the solution. When using a problem-solving approach, students can pose questions, develop way(s) to answer problems (which might include drawing diagrams, carrying out calculations, defining relationships and making conclusions), interpreting, evaluating and communicating the solution (Artigue et al., 2020 ; Dorier & Maass, 2020 ). Problem solving involves understanding the problem, devising and executing the plan and evaluating (Nieuwoudt, 2015 ). Likewise, Blum and Leiß ( 2007 ) developed a modelling approach that was informed by these stages, understanding, simplifying, mathematising, working mathematically, interpreting and validating.

Similarly, mathematical modelling involves problem identification from a contextualised real-world problem, linking the solution to mathematics concepts, carrying out mathematic manipulations, justifying and evaluating the solution in relation to the problem and communicating findings (Geiger et al., 2021 ). Likewise, in modelling, Galbraith and Stillman ( 2006 ) suggested that further research is needed in fostering students’ ability to transition effectively from one phase to the next. “Mathematical modelling is a special kind of problem solving which formulates and solves mathematically real-world problems connected to science and everyday life situations” (Voskoglou, 2021 p. 85). As part of problem solving, mathematical modelling requires students to interpret information from a variety of narrative, expository and graphic texts that reflect authentic real-life situations (Doyle, 2005 ).

There are different approaches to problem solving and modelling, but all of them focus on the solving of real-world problems using mathematical procedures and strategies (Hankeln, 2020 ). A literature synthesis is critical where several models exist as it can be used to develop an overarching conceptual model (Snyder, 2019 ). Torraco ( 2005 ) noted that literature synthesis can be used to integrate different models that address the same phenomenon. For example, in this study, it was used to integrate problem solving models cited in the literature. Moreover, the review was necessitated by the need to reconceptualise the problem-solving model by Polya ( 1971 ) to include the understanding that the definition of problem solving has now broadened to include modelling. Torraco went further to suggest that as literature grows, and knowledge expands on a topic which might accommodate new insights, there is a need for literature synthesis with the aim to reflect the changes. Thus, the model in Fig.  1 took into consideration the key stages broadly identified by the researchers and the understanding that modelling is part of problem solving. Problem solving and modelling is generally a linear process that can include loops depending on how the problem identification, mathematisation and implementation effectively address the problem (Blum & Leiß, 2007 ; Polya, 1957 ).

figure 1

Stages of mathematics problem solving

Figure  1 identifies the main stages that inform mathematics problem solving from the literature.

Problem identification and the design to solve the problem might be revisited if the procedures that were identified and their mathematical justification do not address the problem. Likewise, justification and evaluation after implementation might prompt the problem solver to realise that the problem was incorrectly identified. The loop is identified by the backward arrow, and the main problem-solving stages are identified by the linear arrows. The Australian Curriculum, Assessment and Reporting Authority notes that during problem solving:

Students solve problems when they use mathematics to represent unfamiliar situations, when they design investigations and plan their approaches, when they apply their existing knowledge to seek solutions, and when they verify that their answers are reasonable. Students develop the ability to make choices, interpret, formulate, model and investigate problem situations, and communicate solutions effectively. (Australia Curriculum and Reporting Authority, 2014 , p. 5)

Therefore, during problem solving, students have to plan the solution to the problem and be able to communicate all the key processes involved. However, although problem solving is highly recommended in mathematics education, it presents several challenges for teachers in terms of how they can best support students to connect the processes and mathematics concepts into something coherent that can lead to a meaningful solution (Hacker, 1998 ). Therefore, relevant tools that support problem solving and decision-making can make a difference for both mathematics teachers and students (McGowan & Boscia, 2016 ).

Students can solve problems better if they can think critically (Kules, 2016 ). Problem solving requires their active engagement in analysing, conceptualising, applying concepts, evaluating, comparing, sequencing, synthesising, reasoning, reflecting and communicating, which are skills that are said to promote critical thinking (Kim et al., 2012 ; King, 1995 ; Moon, 2008 ; QCAA, 2018 ). Similarly, the ability to undertake problem solving is supported when students are provided with the opportunity to sequence ideas logically and evaluate the optimal strategy to solve the problem (Parvaneh & Duncan, 2021 ). However, finding tools that can support problem solving has been a focus for researchers for a long time but with very limited breakthroughs (McCormick et al., 2015 ). This study explored how procedural flowcharts as visual representations can support students in organising ideas, execute procedures, justify solutions and communicate their solution.

Importance of visual representations in mathematics problem-solving

Research on how visual representations support mathematics discovery and structural thinking in problem solving has come a long way (see Hadamard, 1945 ; Krutetskii, 1976 ; Polya, 1957 ). Visual representations are classified as graphs, tables, maps, diagrams, networks and icons and are widely used to convey information in a recognisable form that can be easily interpreted without resorting to tedious computations (Lohse et al., 1994 ). Visual representations can be used as a tool to capture mathematics relations and processes (van Garderen et al., 2021 ) and used in many cognitive tasks such as problem solving, reasoning and decision making (Zhang, 1997 ). Indeed, representations can be modes of communicating during concepts exploration and problem solving (Roth & McGinn, 1998 ). Likewise, visual representations can be a powerful way of presenting the solution to a problem, including self-monitoring on how the problem is being solved (Kingsdorf & Krawec, 2014 ; Krawec, 2014 ). Using visualisations created by teachers or students in mathematics can support students’ problem-solving abilities (Csíkos et al., 2012 ).

Visual representations show thoughts in non-linguistic format, which is effective for communication and reflection. “Visual representations serve as tools for thinking about and solving problems. They also help students communicate their thinking to others” (NCTM, 2000 , p. 206). In mathematics, visual representation plays a significant role in showing the cognitive constructs of the solution (Owens & Clements, 1998 ), a view echoed by Arcavi ( 2003 ), who said that visual representations can be appreciated as a central part of reasoning and as a resource to use in problem solving. More importantly, they can be used to represent the logical progression of ideas and reasoning during problem solving (Roam, 2009 ). However, there is need to explore how visual representations can be used to support and illustrate the problem-solving process and to create connections among concepts (Stylianou, 2010 ). Importantly, developing diagrams is often a recommended strategy for solving mathematics problems (Pape & Tchoshanov, 2001 ; Jitendra et al., 2013 ; Zahner & Corter, 2010 ). Therefore, this study will explore the utility of procedural flowcharts as a visual representation and resource in supporting problem analysis, problem understanding, solution development and evaluation, while communicating the whole problem-solving process effectively. It will go further to explore how development of procedural flowcharts can support educational practice in Mathematical Methods subject.

Procedural flowcharts are a visual representation of procedures, corresponding steps and stages of evaluation of a solution to a problem (Chinofunga et al., 2022 ). These authors noted that procedural flowcharts developed by the teacher can guide students during the inquiry process and highlight key procedures and stages for decision-making during the process of problem solving. This is because “a procedural flowchart graphically displays the information–decision–action sequences in the proposed order” (Krohn, 1983 , p. 573). Similarly, Chinofunga and colleagues ( 2022 ) emphasised that procedural flowcharts can be used to visually represent procedural flexibility as more than one procedure can be accommodated, making it easier to compare the effectiveness of different procedures as they are being applied. They further posited that student-developed procedural flowcharts provide students with the opportunity to comprehensively engage with the problem and brainstorm different ways of solving it, thus deepening their mathematics knowledge. Moreover, a procedural flowchart can be a visual presentation of an individual or group solution during problem solving.

Research has identified extended benefits of problem solving in small groups (Laughlin et al., 2006 ). Giving groups an opportunity to present a solution visually can be a quicker way to evaluate a group solution because visual representations can represent large amounts of information (even from different sources) in a simple way (Raiyn, 2016 ). Equally, Vale and colleagues encouraged visual representation of solutions with multisolutions as a tool to teach students problem solving ( 2018 ). Therefore, students can be asked to develop procedural flowcharts individually then come together to synthesise different procedural flowcharts.

Similarly, flowcharts are a visual aid used to represent how procedures interrelate and function together. “They are tools to visually break down complex information into individual building blocks and how the blocks are connected” (Grosskinsky et al., 2019 , p. 24). They outlay steps in a procedure and show how they can be applied, thus helping to visualise the process (Ledin & Machin, 2020 ; Reingewertz, 2013 ). Flowcharts can also be used when a logical and sequenced approach is needed to address a problem (Cantatore & Stevens, 2016 ). Importantly, in schools, Norton and colleagues ( 2007 ) noted that “planning facilitated through the use of flow charts should be actively encouraged and scaffolded so that students can appreciate the potential of flow charts to facilitate problem-solving capabilities” (p. 15). This was because the use of flowcharts in problem solving provided a mental representation of a proposed approach to solve a task (Jonassen, 2012 ). The success of flowcharts in problem solving in different fields can be attributed to their ability to facilitate deep engagement in planning the solution to the problem.

Flowcharts use has distinct advantages that can benefit problem solving. Norton and colleagues ( 2007 ) posited that using a well-planned and well-constructed flowchart in problem solving results in a good-quality solution. Furthermore, flowcharts can also be a two-way communication resource between a teacher and students or among students (Grosskinsky et al., 2019 ). These authors further noted that flowcharts can help in checking students’ progress, tracking their progress and guide them. They can also be used to highlight important procedures that students can follow during the process of problem solving.

Similarly, flowcharts can be used to provide a bigger picture of the solution to a problem (Davidowitz & Rollnick, 2001 ). Flowcharts help students gain an overall and coherent understanding of the procedures involved in solving the problem as they promote conceptual chunking (Norton et al., 2007 ). Importantly, “they may function to amplify the zone of proximal development for students by simplifying tasks in the zone” (Davidowitz & Rollnick, 2001 , p. 22). Use of flowcharts by students reduces the cognitive load which then may help them focus on more complex tasks (Berger, 1998 ; Sweller et al., 2019 ). Indeed, development of problem-solving skills can be supported when teachers introduce learning tools such as flowcharts, because they can help structure how the solution is organised (Santoso & Syarifuddin, 2020 ). Therefore, the use of procedural flowcharts in mathematics problem solving has the potential to transform the process.

The research question in this study was informed by the understanding that limited resources are available to teachers to support students’ problem-solving abilities. In addition, the literature indicates that visual representation such as procedural flowcharts can support students’ potential in problem solving. Therefore, the research described in this study addressed the following research question: What are teachers’ perceptions of how procedural flowcharts can support the development of students’ problem-solving skills in the Mathematical Methods subject?

Methodology

The case study draws from the reflective investigation methodology (Trouche et al., 2018 ,  2020 ). The methodology explores how teaching and learning was supported by facilitating a teacher’s reflection on the unexpected use of a resource, in this case procedural flowcharts. The reflective methodology emphasises a teacher’s active participation through soliciting views on the current practice and recollection on previous work (Trouche et al., 2020 ). Using the methodology, a teacher is asked to reflect on and describe the resource used, the structure (related to the activity), the implementation and the outcomes (Huang et al., 2023 ).

This case study focuses on phases three and four of a broad PhD study that involved four phases. The broad study was informed by constructivism. Firstly, phase one investigated Queensland senior students’ mathematics enrolment in different mathematics curricula options from 2010 to 2020. Secondly, phase two developed and introduced pedagogical resources that could support planning, teaching and learning of calculus-based mathematics with a special focus on functions in mathematical methods. The pedagogical resources included a framework on mathematics content sequencing which was developed through literature synthesis to guide teachers on how to sequence mathematics content during planning. Furthermore, the phase also introduced concept maps as a resource for linking prior knowledge to new knowledge in a constructivist setting. Procedural flowcharts were also introduced to teachers in this phase as a resource to support development of procedural fluency in mathematics. Importantly, a conference workshop organised by the Queensland Association of Mathematics Teachers (Cairns Region) provided an opportunity for teachers to contribute their observations on ways that concept maps and procedural flowcharts can be used to support teaching. Thirdly, phase three was a mixed-method study that focused on evaluating the pedagogical resources that were developed or introduced in phase two with 16 purposively sampled senior mathematics teachers in Queensland who had been given a full school term to use the resources in their practice. Some qualitative data collected through semistructured interviews from phase three were included in the results of the study reported here. During the analysis of the qualitative data, a new theme emerged which pointed to the unexpected use of procedural flowcharts during teaching and learning beyond developing procedural fluency. As a result, the researchers decided to explore how development of procedural flowcharts supported teaching and learning of mathematics as an additional phase. Phase four involved an in-depth interview with Ms. Simon (pseudonym) a teacher who had unexpectedly applied procedural flowcharts in a problem-solving task, which warranted further investigation. Ms. Simon’s use of procedural flowcharts was unexpected as she had used them outside the context and original focus of the broader study. Importantly, in phase four, artefacts created by the teacher and her four students in the problem-solving task were also collected.

Ms. Simon (pseudonym) had explored the use of procedural flowcharts in a problem-solving and modelling task (PSMT) in her year 11 Mathematical Methods class. This included an introduction to procedural flowcharts, followed by setting the students a task whereby they were asked to develop a procedural flowchart as an overview on how they would approach a problem-solving task. The students were expected to first develop the procedural flowcharts independently then to work collaboratively to develop and structure an alternative solution to the same task. The student-developed procedural flowcharts (artefacts) and the in-depth interview with Ms. Simon were included in the analysis. As this was an additional study, an ethics amendment was applied for and granted by the James Cook University Ethics committee, approval Number H8201, as the collection of students’ artefacts was not covered by the main study ethics approval for teachers.

Research context of phase four of the study

In the state of Queensland, senior mathematics students engage with three formal assessments (set by schools but endorsed by QCAA) in year 12 before the end of year external examination. The formal internal assessments consist of two written examinations and a problem-solving and modelling task (PSMT). The PSMT is expected to cover content from Unit 3 (Further Calculus). The summative external examination contributes 50% and the PSMT 20% of the overall final mark, demonstrating that the PSMT carries the highest weight among the three formal internal assessments.

The PSMT is the first assessment in the first term of year 12 and is set to be completed in 4 weeks. Students are given 3 h of class time to work on the task within the 4 weeks and write a report of up to 10 pages or 2000 words. The 4 weeks are divided into four check points, one per week with the fourth being the submission date. On the other three checkpoints, students are expected to email their progress to the teacher. At checkpoint one, the student will formulate a general plan on how to solve the problem which is detailed enough for the teacher to provide meaningful feedback. Checkpoint one is where this study expects teachers to provide students with the opportunity to develop a procedural flowchart of the plan to reach the solution. Importantly at checkpoint one, teachers are interested in understanding which mathematics concepts students will select and apply to try and solve the problem and how the concepts integrate or complement each other to develop a mathematically coherent, valid and appropriate solution. Moreover, teachers are expected to have provided students with opportunities to develop skills in undertaking problem-solving and modelling task before they engage with this formal internal assessment. The QCAA has provided a flowchart to guide teachers and students on how to approach a PSMT ( Appendix 1 )

Participants in phase four of the study

Ms. Simon and a group of four students were the participants in this study. Ms. Simon had studied mathematics as part of her undergraduate education degree, which set her as a highly qualified mathematics teacher. At the time of this study, she was the Head of Science and Mathematics and a senior mathematics teacher at one of the state high schools in Queensland. She had 35 years’ experience in teaching mathematics across Australia in both private and state schools, 15 of which were as a curriculum leader. She was also part of the science, technology, engineering and mathematics (STEM) state-wide professional working group. Since the inception of the external examination in Queensland in 2020, she had been an external examination marker and an assessment endorser for Mathematical Methods with QCAA. The students who were part of this study were aged between 17 and 18 years and were from Ms. Simon’s Mathematical Methods senior class. Two artefacts were from individual students, and the third was a collaborative work from the two students.

Phase four data collection

First, data were collected through an in-depth interview between the researcher and Ms. Simon. The researcher used pre-prepared questions and incidental questions arising from the interview. The questions focused on exploring how she had used procedural flowcharts in a PSMT with her students. The interview also focused on her experiences, observations, opinions, perceptions and results, comparing the new experience with how she had previously engaged her students in such tasks. The interview lasted 40 min, was transcribed and coded so as to provide evidence of the processes involved in the problem solving. Some of the pre-prepared questions were as follows:

What made you consider procedural flowcharts as a resource that can be used in a PSMT?

How have you used procedural flowcharts in PSMT?

How has the use of procedural flowcharts transformed students’ problem-solving skills?

How have you integrated procedural flowcharts to complement the QCAA flowchart on PSMT in mathematics?

What was your experience of using procedural flowcharts in a collaborative setting?

How can procedural flowcharts aid scaffolding of problem-solving tasks?

Second, Ms. Simon shared her formative practice PSMT task (described in detail below), and three of her students’ artefacts. The artefacts that she shared (with the students’ permission) were a critical source of data as they were a demonstration of how procedural flowcharts produced by students can support the development of problem solving and provided an insight into the use of procedural flowcharts in a PSMT.

Problem-solving and assessment task

The formative practice PSMT that Ms. Simon shared is summarised below under the subheadings: Scenario, Task, Checkpoints and Scaffolding.

You are part of a team that is working on opening a new upmarket Coffee Café. Your team has decided to cater for mainly three different types of customers. Those who:

Consume their coffee fast.

Have a fairly good amount of time to finish their coffee.

Want to drink their coffee very slowly as they may be reading a book or chatting.

The team has tasked you to come up with a mode or models that can be used to understand the cooling of coffee in relation to the material the cup is made from and the temperature of the surroundings.

Write a mathematical report of at most 2000 words or up to 10 pages that explains how you developed the cooling model/s and took into consideration the open cup, the material the cup was made from, the cooling time, the initial temperature of the coffee and the temperature of the surroundings.

Design an experiment that investigates the differences in the time of cooling of a liquid in open cups made from different materials. Record your data in a table.

Develop a procedural flowchart that shows the steps that you used to arrive at a solution for the problem.

Justify your procedures and decisions by explaining mathematical reasoning.

Provide a mathematical analysis of formulating and evaluating models using both mathematical manipulation and technology.

Provide a mathematical analysis that involves differentiation (rate of change) and/or anti-differentiation (area under a curve) to satisfy the needs of each category of customers.

Evaluate the reasonableness of solutions.

You must consider Newton’s Law of Cooling which states that the rate of change of the temperature of an object is proportional to the difference between its own temperature and the temperature of its surroundings. For a body that has a higher temperature than its surroundings, Newton’s Law of Cooling can model the rate at which the object is cooling in its surroundings through an exponential equation. This equation can be used to model any object cooling in its surroundings: 

y is the difference between the temperature of the body and its surroundings after t minutes,

A 0 is the difference between the initial temperature of the body and its surroundings,

k is the cooling constant.

Checkpoints

Week 1: Students provide individual data from the experiment and create a procedural flowchart showing the proposed solution to the problem. Teacher provides individual feedback. Week 2: Students provide a consolidated group procedural flowchart. Teacher provides group feedback Week 3: Students email a copy of their individually developed draft report for feedback. Week 4: Students submit individual final response in digital (PDF format) by emailing a copy to their teacher, providing a printed copy to their teacher and saving a copy in their Maths folder.

Additional requirements/instructions

The response must be presented using an appropriate mathematical genre (i.e., a mathematical report).

The approach to problem-solving and mathematical modelling must be used.

All sources must be referenced.

Data analysis

The analysis of data includes some observations and perceptions of mathematics teachers which were collected through surveys and interviews from phase three of the broader PhD study. The survey and interviews data in the broader study including phase four in-depth interview with Ms. Simon were transcribed and coded using thematic analysis (TA). TA is widely used in qualitative research to identify and describe patterns of meaning within data (Braun & Clarke, 2006 ; Ozuem et al., 2022 ). The thematic validity was ensured using theory triangulation. It involves sharing qualitative responses among colleagues at different status positions in the field and then comparing findings and conclusions (Guion et al., 2011 ). The study adopted the inductive approach which produces codes that are solely reflective of the contents of the data (Byrne, 2022 ).

Coding was done with no pre-set codes, and line-by-line coding was used as this was mainly an inductive analysis. The research team comprising of the researcher and two advisors/supervisors met to set the initial coding mechanism and code part of the data for consistency before independent coding of all the data. This is supported by King ( 2004 ) who suggested that when searching for themes, it is best to start with a few codes to help guide analysis. The data covered a wide variety of concepts, so initially the different concepts that grouped the research questions as ‘conceptual themes’ were utilised to organise the data. The research team examined the codes, checking their meaning and relationships between them to determine which ones were underpinned by a central concept. In Excel, codes that shared a core idea from the initial phase that used data from the open-ended responses and interview transcripts were colour coded. After the independent thematic analysis, the filter function in Excel was used to sort the codes using cell colour. Moreover, Excel provided the opportunity to identify duplicates as codes were collated from the three researchers. Same coloured codes were synthesised to develop a general pattern of meaning, which we referred to as candidate themes. The sorting and collation approach would bring together all codes under each theme which then would facilitate further analysis and review (Bree et al., 2014 ).

The research team went on to review the relationship of the data and the codes that informed the themes. This is supported by Braun and Clarke ( 2012 , 2021 ) who posited that researchers should conduct a recursive review of the candidate themes in relation to the coded data items and the entire dataset. During the review, whenever themes were integrated or codes were moved to another theme, a new spreadsheet was created so that if further review was necessary, the old data and layout would still be available. Importantly, if the codes form a coherent and meaningful pattern, the theme makes a logical argument and may be representative of the data (Nowell et al., 2017 ). Furthermore, the team also reviewed the themes in relation to the data. This is because Nowell and others posited that themes should provide the most accurate interpretation of the data. The research team also discussed and wrote detailed analysis for each candidate theme identifying the main story behind each theme and how each one fit into the overall story about the data through the lens of the research questions. Finally, the researchers also linked quotes to final themes reached during the analysis. Illustrating findings with direct quotations from the participants strengthen the face validity and credibility of the research (Bryne, 2022 ; Patton, 2002 ; Nowell et al., 2017 ).

Student artefacts

The students’ artefacts (procedural flowcharts) in Figs.  5 , 6 and 7 were analysed using content analysis. Content analysis can be used to analyse written, verbal or visual representations (Cole, 1988 ; Elo & Kyngäs, 2008 ). Content analysis is ideal when there is a greater need to identify critical processes (Lederman, 1991 ). Unlike interviews, documents that are ideal for qualitative analysis should be developed independently without the researcher’s involvement (Merriam & Tisdell, 2015 ). In fact, the documents should not have been prepared for the purpose of research (Hughes & Goodwin, 2014 ), hence they are a stable and discrete data source (De Massis & Kotlar, 2014 ; Merriam & Tisdell, 2015 ). The students’ artefacts used in this study were not prepared for the purpose of the study but as a mathematics task. Deductive content analysis is used when the structure of analysis is implemented on the basis of previous knowledge and the purpose of the study is model testing or confirmation (Burns & Grove, 2009 ). Similarly, it is an analytical method that aims to test existing concepts, models or hypotheses in a new context (Kyngäs et al., 2020 ). They went further to note that researchers can use deductive analysis to determine how a model fit a new context.

Deductive content analysis follows three main stages: preparation, organising and reporting (Elo et al., 2014 ; Elo & Kyngäs, 2008 ). Firstly, preparation involves identifying the unit of analysis (Guthrie et al., 2004 ). In this study, the unit of analysis are the artefacts developed by the students. Furthermore, the phase requires the researcher to be immersed in the data reading and digesting to make sense of the whole set of data through reflexivity, open-mindedness and following the rationale of what guided participants’ narratives or in developing the artefact (Azungah, 2018 ). Secondly, a categorisation matrix based on existing knowledge should be developed or identified to facilitate the coding of the data according to categories (Hsieh & Shannon, 2005 ) (Table  1 ). Importantly, when using deductive content analysis, researchers require a theoretical structure or model from which they can build an analysis matrix (Kyngäs et al., 2020 ). Finally, the analysis results should be reported in ways that promote interpretation of the data and the results, for example, in tabular form (Elo & Kyngäs, 2008 ) (Fig.  2 ).

figure 2

Stages followed during analysis of procedural flowcharts

The students’ procedural flowcharts were coded and interpreted on how they respond to different stages of problem solving. The researcher’s codes, interpretations and findings should be clearly derived and justified using the available data and then inform conclusions and interpretations for confirmability (Tobin & Begley, 2004 ). The artefacts were shared between the researcher and his supervisors; the analysis was done independently then reviewed by the researcher and his supervisors. Schreier ( 2012 ) recommended that analysis should be done by more than one person to promote thoroughness and broaden the interpretation of the data. Schreier went further to note that if the categorisation matrix is clear and of high quality, the coding should produce very little discrepancies. Very little discrepancies were observed except that some stages on the students’ procedural flowcharts overlapped between skills.

This section presents results from the analysis of the interviews data and student artefacts.

Semi-structured interviews

The thematic analysis of interviews resulted in two themes:

The utility of procedural flowcharts in supporting mathematics problem solving.

The utility of procedural flowcharts in supporting the integration of the four stages of mathematics problem solving.

In phase three, which prompted the targeted phase four study described in this study, teachers were asked the question, “How have you used procedural flowcharts to enhance teaching and learning of mathematics?” The question was not specific to problem solving but the teachers’ observations and perceptions strongly related to problem-solving and student-centred learning.

Theme 1 The utility of procedural flowcharts generally supports mathematics problem solving

The visual nature of procedural flowcharts was seen as an advantage to both teachers and students. For students, drawing a flowchart was easier than writing paragraphs to explain how they had arrived at the intended solution. For teachers, the flowchart was easier to process for timely feedback to students. Developing a procedural flowchart at the first checkpoint in the PSMT allows teachers to provide valuable feedback as the procedural flowchart can be used to represent several processes compared to written because of its visual nature. Engagement can be promoted because students can use the targeted feedback to improve their solutions as they will have provided a detailed overview of how they propose to solve the problem.

They present steps in diagrammatic form which is easy to process and easy to understand and process… students prefer them more as its in diagrammatic form and I have witnessed more students engaging. (Participant 8, phase three study) I find it (visual) a really efficient way for me to look at the proposed individual students processes and provide relevant feedback to the student or for the student to consider. And, you know, once the students are comfortable with using these procedural flowcharts you know, I find it much easier for me to give them relevant feedback, and I actually find that feedback more worthwhile than feedback we used to give them, you know, that was just based on what they wrote in paragraphs,…students get to practice in creating their own visual display, which communicates their intended strategies to solve the problem, then they have opportunities to use it, and fine tune it as they work out the problem … student developed procedural flow charts, they represent a student’s maths knowledge in a visual way. (Ms. Simon).

Identifying students’ competencies early was seen as central to successful problem solving as it provided opportunities for early intervention. Results showed that teachers viewed procedural flowcharts as a resource that could be used to identify gaps in skills, level of understanding and misconceptions that could affect successful and meaningful execution of a problem-solving task. Going through a student-developed flowchart during problem solving provided the teachers with insight into the student’s level of understanding of the problem and how the effectiveness of the procedures proposed to address the problem. This is critical for tasks that require students to develop a report detailing the solution at the end of developing the solution. Teachers can get the opportunity to gain an insight of the proposed solution before the student commit to write the report. The procedural flowchart provides the bigger picture of the solution plan which might expose gaps in knowledge.

I found it quite useful because I can identify what kids or which kids are competent in what, which sort of problem-solving skills. And I can identify misconceptions that students have or gaps in students understanding. (Participant 1, phase three study) It also to me highlights gaps in students’ knowledge in unique ways that students intend to reach a solution because the use of the procedural flow chart encourages students to explain the steps or procedures behind any mathematical manipulation that you know they're intending to use. And it's something that was much more difficult to determine prior to using procedural flow charts… I've also used you know, student developed procedural flow charts to ascertain how narrow or wide the students’ knowledge is and that's also something that wasn't obvious to make a judgement about prior to using procedural flow charts. (Ms. Simon)

Problem solving was seen as student-centred. If procedural flowcharts could be used to support problem solving, then they could facilitate an environment where students were the ones to do most of the work. The students could develop procedural flowcharts showing how they will solve a PSMT task using concepts and procedures they have learnt. The open-ended nature of the problem in a PSMT provides opportunities for diverse solutions that are validated through mathematical justifications. The visual nature of procedural flowcharts makes them more efficient to navigate compared to text.

Mathematics goes from being very dry and dusty to being something which is actually creative and interesting and evolving, starting to get kids actually engaging and having to back themselves. (Participant 7, phase three study) As a teacher, I find that procedural flowcharts are a really efficient way to ascertain the ways that students have considered and how they are going to solve a problem … It engages the students from start to finish, you know in different ways this method demands students to compare, interpret, analyse, reason, evaluate, and to an extent justify as they develop this solution. (Ms. Simon)

Similarly, results showed that procedural flowcharts could be used as a resource to promote collaborative learning and scaffolding. Students could be asked to collaboratively develop a procedural flowchart or could be provided with one to follow as they worked towards solving the problem. Collaborative development of procedural flowcharts can support problem solving as students can bring their different mathematical understanding to develop a solution from different perspectives.

Sometimes, you know, I get students to work on it in groups as they share ideas and get that mathematisation happening. So, it's really helpful there … I looked at the PSMT and its Marking Guide, and develop a more detailed procedural flowchart for students to use as a scaffold to guide them through the process. So, procedural flowcharts provide a structure in a more visual way for students to know what to do next. (Ms. Simon)

Ms. Simon shared her detailed procedural flowchart in Fig.  3 that she used to guide students in PSMTs.

figure 3

Ms. Simon’s procedural flowchart on problem solving

The participants also observed that procedural flowcharts could be used to promote opportunities for solution evaluation which played an important role in problem solving. Loops can be introduced in procedural flowcharts to provide opportunities for reflection and reasoning as alternative paths provide flexibility while the solution is being developed. Following Fig.  4 are participants’ comments referring to the figure which was among procedural flowcharts shared with participants as examples of how they can be used to teach syllabus identified Mathematical Methods concepts. The Mathematical Methods syllabus expects students to “recognise the distinction between functions and relations and use the vertical line test to determine whether a relation is a function” (QCAA, 2018 p. 20).

The cycle approach, the feeding back in the feeding back out that type of stuff, you know, that is when we starting to teach students how to think . (Participant 7, phase three study) Complex procedural flowcharts like the one you provided guide students in making key decisions as they work through solutions which is key to critical thinking and judgement and these two are very important in maths. (Participant 8, phase three study) I also sincerely believe that procedural flowcharts are a way to get students to develop and demonstrate the critical thinking skills, which PSMTs are designed to assess. Students inadvertently have to use their critical thinking skills to analyse and reason as they search for different ways to obtain a solution to the problem presented in the PSMT … the use of procedural flowcharts naturally permits students to develop their critical thinking skills as it gets their brain into a problem-solving mode as they go through higher order thinking skills such as analysis, reasoning and synthesis and the like … this visual way of presenting solution provides students with opportunities to think differently, which they're not used to do, and it leads them to reflect and compare. (Ms. Simon)

figure 4

Procedural flowchart on distinguishing functions and relations

Problem solving of non-routine problems uses a structure that should be followed. Resources that are intended to support problem solving in students can be used to support the integration of the stages involved in problem solving.

Theme 2 The utility of procedural flowcharts in supporting the integration of the four stages of mathematics problem solving.

Procedural flowcharts can support the flow of ideas and processes in the four stages during problem-solving and modelling task in Mathematical Methods subject. Literature synthesis in this study identified the four stages as:

Identification of problem and mathematics strategies than can solve the problem.

Implementation.

Evaluation and justification.

Communicating the solution.

Similarly, QCAA flowchart on PSMT identifies the four stages as formulate, solve, evaluate and verify, and communicate.

The logical sequencing of the stages of mathematics problem solving is crucial to solving and communicating the solution to the problem. Development of procedural flowcharts can play an important role in problem solving through fostering the logical sequencing of processes to reach a solution. Participants noted that the development of procedural flowcharts provides opportunities for showing the flow of ideas and processes which lay out an overview of how different stages connect into a bigger framework of the solution. Furthermore, it can help show how different pieces of a puzzle interconnect, in this case how all the components of the solution interconnect and develop to address the problem. In fact, procedural flowcharts can be used to show how the different mathematics concepts students have learnt can be brought together in a logical way to respond to a problem.

Procedural flowcharts help students sum up and connect the pieces together… connect the bits of knowledge together. (Participant 4, phase three study) Really good how it organises the steps and explains where you need to go if you're at a certain part in a procedure. (Participant 2, phase three study) Potentially, it's also an excellent visual presentation, which shows a student's draft of their logical sequence of processes that they're intending to develop to solve the problem … So, the steps students need to follow actually flows logically. So really given a real-life scenario they need to solve in a PSMT students need to mathematise it and turn it into a math plan, where they execute their process, evaluate and verify it and then conclude … so we use procedural flowcharts to reinforce the structure of how to approach problem-solving … kids, you know, they really struggling, you know, presenting things in a logical way, because they presume that we know what they're thinking . (Ms. Simon)

Developing procedural flowcharts provided students with opportunities to plan the solution informed by the stages of problem solving. Teachers could reinforce the structure of problem solving by telling students what they could expect to be included on the procedural flowchart. Procedural flowcharts can be used as a visual tool to highlight all the critical stages that are included during the planning of the solution.

I tell the students, “I need to see how you have interpreted the problem that you need to solve. I need to see how you formulated your model that involves the process of mathematisation, where you move from the real world into the maths world, and I need to see all the different skills you're intending to use to arrive at your solution.” (Ms. Simon)

Similarly, procedural flowcharts could visually represent more than one strategy in the “identify and execute mathematics procedures that can solve the problem” stage, thereby providing a critical resource to demonstrate flexibility. When there are multiple ways of addressing a problem, developing a procedural flowchart can provide an opportunity of showing all possible paths or relationships between different paths to the solution, thus promoting flexibility. Procedural flowcharts provide an opportunity to show how different procedures can be used or integrated to solve a problem.

Students are expected to show evidence that they have the knowledge of solving the problem using several ways to get to the same solution. So, it goes beyond the students’ preferred way of answering a question and actually highlights the importance of flexibility when it comes to processes and strategies of solving a problem … By using procedural flowcharts, I'm saying to the students, “Apart from your preferred way of solving the problem, give me a map of other routes, you can also use to get to your destination.” (Ms. Simon)

The results also indicated that procedural flowcharts could be used to identify strengths and limitations of procedures in the “evaluate solution” stage and thus demonstrate the reasonableness of the answer. Having more than one way of solving a problem on a procedural flowchart helps in comparing and evaluating the most ideal way to address the problem.

And I'm finding that, you know, as students go through, and they compare the different processes, you know, the strengths and limitations, literally stare them in the face. So, they don't have to. They're not ... they don't struggle as much as they used to in coming up with those sorts of answers … it's also a really easy way that once the students reach the next phase, which is the evaluating verified stage, they can go back to their procedural flow chart and identify and explain strengths and limitations of their model … It's a convenient way for students to show their reasonableness of their solution by comparing strengths and weaknesses of all the strategies presented on the procedural flowchart, something that they've struggled with in the past. (Ms. Simon)

The results from the interview show that the procedural flowcharts supported efficient communication of the steps to be followed in developing the solution to the problem. Student-developed procedural flowcharts allowed the teacher to have an insight and overview of the solution to the problem earlier in the assessment task. In addition, they provided an alternative way of presenting their solution to the teacher.

I expect students to use the procedural flowchart as a way to communicate to me how they're planning to solve the scenario in the PSMT…It's also one of the parts that students are expected to hand in to me on one of the check points, and I find it a really efficient way for me to look at, you know, a proposed individual students processes, and provide relevant feedback to the student to consider in a really efficient way…I just found that it helps students communicate their solution to a problem in lots of different ways that challenges students to logically present a solution. (Ms. Simon)

She went on to say,

Students also found it challenging to communicate their ideas in one or two paragraphs, when more than one process or step was required to solve the problem. So, I found that, you know, procedural flowcharts, have filled this gap really nicely, as that provides students with a simple tool that they can use to present a visual overview of the processes they've chosen to use to solve the problem. And so, for me, as a teacher, procedural flowcharts are an efficient way for me to scan the intended processes that an individual student is proposing to use to solve the problem in their authentic way and provide them with valuable feedback.

In summary, the teacher’s experiences, views and perceptions showed that procedural flowcharts can be a valuable resource in supporting students in all four stages of problem solving.

Students’ artefacts

The student-generated flowcharts in this part of the research gave an insight into students’ understanding as they planned how to solve the problem presented to them. Students were expected to use the problem-solving stages to successfully develop solutions to problems. Their de-identified procedural flowcharts are shown in Figs.  5 , 6 and 7 .

figure 5

Procedural flowchart developed by student 1

figure 6

Procedural flowchart developed by student 2

figure 7

Collaboratively developed procedural flowchart

Students 1 and 2 also collaboratively developed a procedural flowchart, shown as Fig.  7 .

This discussion is presented as two sections: (1) how developing procedural flowcharts can support mathematics problem solving and (2) how developing procedural flowcharts support the integration of the different stages of mathematics problem solving. This study although limited by sample size highlighted how developing procedural flowcharts can support mathematics problem solving, can reinforce the structure of the solution to a problem and can help develop metacognitive skills among students. The different stages involved in problem solving inform the process of developing the solution to the problem. The focus on problem-based learning has signified the need to introduce resources that can support students and teachers in developing and structuring solutions to problems. Results from this study have also provided discussion points on how procedural flowcharts can have a positive impact in mathematics problem solving.

Procedural flowcharts can support mathematics problem solving

Procedural flowcharts help in visualising the process of problem solving. The results described in this study show that student-generated flowcharts can provide an overview of the proposed solution to the problem. The study noted that students preferred developing procedural flowcharts rather than writing how they planned to find a solution to the problem. The teachers also preferred visual aids because they were easier and quicker to process and facilitated understanding of the steps taken to reach the solution. These results are consistent with the findings of other researchers (McGowan & Boscia, 2016 ; Raiyn, 2016 ). The results are also consistent with Grosskinsky and colleagues’ ( 2019 ) findings that flowcharts break complex information into different tasks and show how they are connected, thereby enhancing understanding of the process. Consequently, they allow teachers to provide timely feedback at a checkpoint compared to the time a teacher would take to go through a written draft. Procedural flowcharts connect procedures and processes in a solution to the problem (Chinofunga et al., 2022 ). Thus, the feedback provided by the teacher can be more targeted to a particular stage identified on the procedural flowchart, making the feedback more effective and worthwhile. The development of a procedural flowchart during problem solving can be viewed as a visual representation of students’ plan and understanding of how they plan to solve the problem as demonstrated in Figs.  5 , 6 and 7 .

In this study, Ms. Simon noted that procedural flowcharts can represented students’ knowledge or thinking in a visual form, which is consistent with Owens and Clements’ ( 1998 ) findings that visual representations are cognitive constructs. Consequently, they can facilitate evaluation of such knowledge. This study noted that developing procedural flowcharts can provide opportunities to identify gaps in students’ understanding and problem-solving skills. It also noted that providing students with opportunities to develop procedural flowcharts may expose students’ misconceptions, the depth and breadth of their understanding of the problem and how they plan to solve the problem. This is supported by significant research (Grosskinsky et al., 2019 ; Norton et al., 2007 ; Vale & Barbosa, 2018 ), which identified flowcharts as a resource in helping visualise and recognise students’ understanding of a problem and communication of the solution. Thus, providing teachers with opportunities to have an insight into students’ thinking can facilitate intervention early in the process. The results in this study showed that when students develop their own plan on how to respond to a problem, they are at the centre of their learning. However, scaffolding and collaborative learning can also support problem solving.

Vygotsky ( 1978 ) posited that in the Zone of Proximal Development, collaborative learning and scaffolding can facilitate understanding. In this study, the results indicated that a teacher-developed procedural flowchart can be used to guide students in developing a solution to a problem. These results are consistent with Davidowitz and Rollnick’s study that concluded that flowcharts provide a bigger picture of how to solve the problem. In Queensland, the QCAA has developed a flowchart (see Appendix 1 ) to guide schools on problem-solving and modelling tasks. It highlights the significant stages to be considered during the process and how they relate to each other. Teachers are encouraged to contextualise official documents to suit their school and classes. In such cases, a procedural flowchart acts as a scaffolding resource in directing students on how to develop the solution to the problem. The findings are consistent with previous literature that flowcharts can give an overall direction of the process, help explain what is involved, may help reduce cognitive load and allow students to focus on complex tasks (Davidowitz & Rollnick, 2001 ; Norton et al., 2007 ; Sweller et al., 2019 ).

In addition to being a scaffolding resource, results showed that procedural flowcharts can be developed collaboratively providing students with an opportunity to share their solution to the problem. Being a scaffolding resource or a resource to use in a community of learning highlights the importance of procedural flowcharts in promoting learning within a zone of proximal development, as posited by Davidowitz and Rollnick ( 2001 ). Scaffolding students to problem solve and develop procedural flowcharts collaboratively provides students with the opportunity to be at the centre of problem solving.

Research has identified problem solving as student-centred learning (Ahmad et al., 2010 ; Karp & Wasserman, 2015 ; Reinholz, 2020 ; Vale & Barbosa, 2018 ). The process of developing the procedural flowcharts as students plan for the solution provides students with opportunities to engage more with the problem. Results showed that when students developed procedural flowcharts themselves, mathematics learning transformed from students just being told what to do or follow procedures into something creative and interesting. As students develop procedural flowcharts, they use concepts they have learnt to develop a solution to an unfamiliar problem (Matty, 2016 ), thus engaging with learning from the beginning of the process until they finalise the solution. The results indicated that developing procedural flowcharts promoted students’ ability to not only integrate different procedures to solve the problem but also determine how and when the conditions were ideal to address the problem, providing opportunities to justify and evaluate the procedures that were used.

Deeper understanding of mathematics and relationships between concepts plays an important role in problem solving, and the results from this study showed that different procedures can be integrated to develop a solution to a problem. The participants observed that developing procedural flowcharts could support the brainstorming ideas as they developed the flowchart, as ideas may interlink in a non-linear way. Moreover, students are expected at different stages to make key decisions about the direction they will need to take to reach the solution to the problem, as more than one strategy may be available. For example, student 1 planned on using only technology to develop the models while student 2 considered both technology and algebra. This showed that student 2 applied flexibility in using alternative methods, thus demonstrating a deeper understanding of the problem. Equally important, Ms. Simon observed that as students developed their procedural flowcharts while planning the steps to reach a solution, they were required to analyse, conceptualise, reason, analyse, synthesise and evaluate, which are important attributes of deeper understanding. Fostering deeper understanding of mathematics is the key goal of using problem solving (Kim et al., 2012 ; King, 1995 ; Moon, 2008 ; QCAA, 2018 ). The results are additionally consistent with findings from Owens and Clements ( 1998 ) and Roam ( 2009 ), who posited that visual aids foster reasoning and show cognitive constructs. Similarly, logical sequencing of procedures and ways to execute a strategy expected when developing procedural flowchart can support deeper understanding, as posited by Parvaneh and Duncan ( 2021 ). When developing procedural flowchart, students are required to link ideas that are related or feed into another, creating a web of knowledge. Students are also required to identify the ways in which a concept is applied as they develop a solution, and this requires deeper understanding of mathematics. Working collaboratively can also support deeper and broader understanding of mathematics.

The procedural flowchart that was developed collaboratively by the two students demonstrated some of the skills that they did not demonstrate in their individual procedural flowcharts. Like student 2, the collaboratively developed flowchart included use of technology and algebra to determine the models for the three different cups. The students considered both rate of change and area under a curve in the task analysis. Apart from planning to use rate at a point, average rate and definite integration, they added the trapezoidal rule. Both average rate and definite integration were to be applied within the same intervals, building the scope for comparison. The trapezoidal rule would also compare with integration. The complexity of the collaboratively developed procedural flowchart concurred with Rogoff and others ( 1984 ) and Stone ( 1998 ), who suggested that a community of learning can expand current skills to higher levels than individuals could achieve on their own. It seems the students used the feedback provided by the teacher on their individually developed procedural flowcharts as scaffolding to develop a much more complex procedural flowchart with competing procedures to address the problem. Their individually developed flowcharts might have acted as reference points, as their initial plans were still included in the collaboratively developed plan but with better clarity. This observation is consistent with Guk and Kellogg ( 2007 ), Kirova and Jamison ( 2018 ) and Ouyang and colleagues ( 2022 ), who noted that scaffolding involving peers, teacher and other resources enhances complex problem-solving tasks and transfer of skills.

Supporting the integration of the different stages of mathematics problem solving

When students develop procedural flowcharts, it supports the logical sequencing of ideas from different stages into a process that ends with a solution. Problem solving follows a proposed order and procedural flowcharts visually display decision and/or action sequences in a logical order (Krohn, 1983 ). They are used when a sequenced order of ideas is emphasised, such as in problem solving (Cantatore & Stevens, 2016 ). This study concurs with Krohn, Cantatore and Stevens, as the results showed that procedural flowcharts could be used to organise steps and ideas logically as students worked towards developing a solution. Students’ procedural flowcharts are expected to be developed through the following stages: problem identification, problem mathematisation, planning and execution and finally evaluation. Such a structure can be reinforced by teachers by sharing a generic problem-solving flowchart outlining the stages so that students can then develop a problem-specific version. Importantly, students’ artefacts in Figs.  5 , 6 and 7 provided evidence of how procedural flowcharts support the different stages of problem-solving stages to create a logical and sequential flow of the solution (see Appendix 1 ). Similarly, Ms. Simon noted that while her students had previously had problems in presenting the steps to their solution in a logical way, she witnessed a significant improvement after she asked them to develop procedural flowcharts first. Further, the results are consistent with Chinofunga et al.’s ( 2022 ) work that procedural flowcharts can support procedural flexibility, as they can accommodate more than one procedure in the “identify and execute mathematics procedures that can solve the problem” stage. Thus, stages that require one procedure or more than one procedure can all be accommodated in a single procedural flowchart. Evaluating the different procedures is also a key stage in problem solving.

As students develop the solution to the problem and identify ways to address the problem, they also have to evaluate the procedures, reflecting on the limitations and strengths of the solutions they offer. Ms. Simon observed that her students had previously struggled with identifying strengths and weaknesses of different procedures. However, she noted that procedural flowcharts gave students the opportunity to reflect and compare as they planned the solution. For example, students could have the opportunity to reflect and compare rate at a point, average rate and integration so they can evaluate which strategy can best address he problem. The artefacts identified the different procedures the students used in planning the solution, enabling them to evaluate the effectiveness of each strategy. Thus, enhancing students’ capacity to make decisions and identify the optimal strategy to solve a problem aligns with the work of McGowan and Boscia ( 2016 ). Similarly, Chinofunga and colleagues’ findings noted that developing procedural flowcharts can be effective in evaluating different procedures as they can accommodate several procedures. The different stages that need to be followed during problem solving and the way the solution to the problem is logically presented are central to how the final product is communicated.

In this study, procedural flowcharts were used to communicate the plan to reach the solution to a problem. The length of time given to students to work on their problem-solving tasks in Queensland is fairly long (4 weeks) and students may struggle to remember some key processes along the way. Developing procedural flowcharts to gain an overview of the solution to the problem and share it with the teacher at an early checkpoint is of significant importance. In this study, Ms. Simon expected her students to share their procedural flowcharts early in the process for her to give feedback, thus making the flowcharts a communication tool. The procedural flowcharts developed by the students in Figs.  5 , 6 and 7 show how students proposed solving the problem. This result lends further support to the NCTM ( 2000 ) findings that visual representations can help students communicate their thinking before applying those thoughts to solving a problem. Ms. Simon also noted that before introducing students to procedural flowcharts, they did not have an overall coherent structure to follow, which presented challenges when they wanted to communicate a plan that involved more than one strategy. However, the students’ artefacts were meaningful, clearly articulating how the solution to the problem was being developed, thus demonstrating that procedural flowcharts can provide the structure that supports the coherent and logical communication of the solution to the problem by both teachers and students (Norton et al., 2007 ). The visual nature of the students’ responses in the form of procedural flowcharts is key to communicating the proposed solution to the problem.

Visual representations are a favourable alternative to narrative communication. Procedural flowcharts can help teachers to check students’ work faster and provide critical feedback in a timely manner. Ms. Simon noted that the use of procedural flowcharts provided her with the opportunity to provide feedback faster and more effectively earlier in the task because the charts provided her with an overview of the whole proposed solution. Considering that students are expected to write a report of 2000 words or 10 pages on the task, the procedural flowchart provides the opportunity to present large amounts of information in just one visual representation. Raiyn ( 2016 ) noted that visual representations can be a quicker way to evaluate a solution and represent large amounts of information.

The procedural flowcharts that were created by students in this study demonstrate that they can be effective in supporting the development of problem-solving skills. This study suggests that including procedural flowcharts in problem solving may support teachers and students in communicating efficiently about how to solve the problem. For students, it is a resource that provides the solution overview, while teachers can consider it as a mental representation of students’ thinking as they plan the steps to reach a solution. Student-developed procedural flowcharts may represent how a student visualises a solution to a problem after brainstorming different pathways and different decision-making stages.

Moreover, as highlighted in this study, the visual nature of procedural flowcharts may offer a diverse range of support for problem solving. Procedural flowcharts make it easy to process and provide timely feedback that in turn might help students engage with the problem meaningfully. Furthermore, they may also provide a structure of the problem-solving process and guide students through the problem-solving process. Navigating through stages of problem solving might be supported by having students design procedural flowcharts first and then execute the plan. Indeed, this study showed that the ability of procedural flowcharts to represent multiple procedures, evaluation stages or loops and alternative paths helps students reflect and think about how to present a logically cohesive solution. Importantly, procedural flowcharts have also been identified as a resource that can help students communicate the solution to the problem. Procedural flowcharts have been noted to support deeper understanding as it may facilitate analysis, logical sequencing, reflection, reasoning, evaluation and communication. Although the in-depth study involved one teacher and three artefacts from her students, which is a very small sample to be conclusive, it identified the numerous advantages that procedural flowcharts bring to mathematics learning and teaching, particularly in terms of supporting the development of problem-solving skills. The study calls for further investigation on how procedural flowcharts can support students’ problem solving.

Ahmad, A., Tarmizi, R. A., & Nawawi, M. (2010). Visual representations in mathematical word problem-solving among form four students in malacca. Procedia - Social and Behavioral Sciences, 8 , 356–361. https://doi.org/10.1016/j.sbspro.2010.12.050

Article   Google Scholar  

Anderson, J. (2014). Forging new opportunities for problem solving in Australian mathematics classrooms through the first national mathematics curriculum. In Y. Li & G. Lappan (Eds.), Mathematics curriculum in school education (pp. 209–230). Springer.

Chapter   Google Scholar  

Arcavi, A. (2003). The role of visual representations in the learning of mathematics. Educational Studies in Mathematics, 52 (3), 215–241. https://doi.org/10.1023/A:1024312321077

Artigue, M., & Blomhøj, M. (2013). Conceptualizing Inquiry-Based Education in Mathematics. ZDM, 45 (6), 797–810. https://doi.org/10.1007/s11858-013-0506-6

Artigue, M., Bosch, M., Doorman, M., Juhász, P., Kvasz, L., & Maass, K. (2020). Inquiry based mathematics education and the development of learning trajectories. Teaching Mathematics and Computer Science, 18 (3), 63–89. https://doi.org/10.5485/TMCS.2020.0505

Australia Curriculum and Reporting Authority. (2014). Mathematics proficiencies (Version 8.4) . https://www.australiancurriculum.edu.au/resources/mathematics-proficiencies/portfolios/problem-solving/

Azungah, T. (2018). Qualitative research: deductive and inductive approaches to data analysis. Qualitative Research Journal, 18 (4), 383–400. https://doi.org/10.1108/QRJ-D-18-00035

Berger, M. (1998). Graphic calculators: An Interpretative framework. For the Learning of Mathematics, 18 (2), 13–20.

Google Scholar  

Blum, W., & Leiß, D. (2007). Deal with modelling problems. Mathematical Modelling: Education, Engineering and Economics, 12 , 222. https://doi.org/10.1533/9780857099419.5.221

Bos, R., & van den Bogaart, T. (2022). Heuristic trees as a digital tool to foster compression and decompression in problem-solving. Digital Experiences in Mathematics Education, 8 (2), 157–182. https://doi.org/10.1007/s40751-022-00101-6

Braun, V., & Clarke, V. (2006). Using thematic analysis in psychology. Qualitative Research in Psychology, 3 (2), 77–101. https://doi.org/10.1191/1478088706qp063oa

Braun, V., & Clarke, V. (2012). Thematic analysis. In H. Cooper, P. M. Camic, D. L. Long, A. T. Panter, D. Rindskopf, & K. J. Sher (Eds.), APA Handbook of Research Methods in Psychology, Research Designs (Vol. 2, pp. 57–71). American Psychological Association.

Braun, V., & Clarke, V. (2021). One size fits all? What counts as quality practice in (reflexive) thematic analysis? Qualitative Research in Psychology, 18 (3), 328–352. https://doi.org/10.1080/14780887.2020.1769238

Bree, R. T., Dunne, K., Brereton, B., Gallagher, G., & Dallat, J. (2014). Engaging learning and addressing over-assessment in the Science laboratory: Solving a pervasive problem. The All-Ireland Journal of Teaching and Learning in Higher Education, 6 (3), 206.1–206.36. http://ojs.aishe.org/index.php/aishe-j/article/viewFile/206/290

Burns, N., & Grove, S. (2009). The practice of nursing research: Appraisal, synthesis and generation of evidence (6th ed.). St. Louis: Saunders Elsevier. https://doi.org/10.7748/ns2013.04.27.31.30.b1488

Book   Google Scholar  

Byrne, D. (2022). A worked example of Braun and Clarke’s approach to reflexive thematic analysis. Quality & Quantity, 56 (3), 1391–1412. https://doi.org/10.1007/s11135-021-01182-y

Cai, J. (2010). Helping elementary school students become successful mathematical problem solvers. In D. Lambdin (Ed.), Teaching and learning mathematics: Translating research to the elementary classroom (pp. 9–14). Reston, VA: National Council of Teachers of Mathematics.

Cantatore, F., & Stevens, I. (2016). Making connections : Incorporating visual learning in law subjects through mind mapping and flowcharts. Canterbury Law Review, 22 (1), 153–170. https://doi.org/10.3316/agis_archive.20173661

Chinofunga, M. D., Chigeza, P., & Taylor, S. (2022). Procedural flowcharts can enhance senior secondary mathematics. In N. Fitzallen, C. Murphy, & V. Hatisaru (Eds.), Mathematical confluences and journeys (Proceedings of the 44th Annual Conference of the Mathematics Education Research Group of Australasia, July 3-7) (pp. 130–137). Launceston: MERGA. https://files.eric.ed.gov/fulltext/ED623874.pdf

Colburn, A. (2000). An inquiry primer. Science Scope, 23 (6), 42–44. http://www.cyberbee.com/inquiryprimer.pdf

Cole, F. L. (1988). Content analysis: Process and application. Clinical Nurse Specialist, 2 (1), 53–57. https://doi.org/10.1097/00002800-198800210-00025

Article   CAS   PubMed   Google Scholar  

Csíkos, C., Szitányi, J., & Kelemen, R. (2012). The effects of using drawings in developing young children’s mathematical word problem solving: A design experiment with third-grade Hungarian students. Educational Studies in Mathematics, 81 , 47–65. https://doi.org/10.1007/s10649-011-9360-z

Davidowitz, B., & Rollnick, M. (2001). Effectiveness of flow diagrams as a strategy for learning in laboratories. Australian Journal of Education in Chemistry, (57), 18–24. https://search.informit.org/doi/10.3316/aeipt.129151

De Massis, A., & Kotlar, J. (2014). The case study method in family business research: Guidelines for qualitative scholarship. Journal of Family Business Strategy, 5 (1), 15–29. https://doi.org/10.1016/j.jfbs.2014.01.007

Dorier, J.-L., & Maass, K. (2020). Inquiry-based mathematics education. In S. Lerman (Ed.), Encyclopedia of mathematics education (pp. 384–388). Springer. https://doi.org/10.1007/978-3-030-15789-0_176

Doyle, K. M. (2005). Mathematical problem solving: A need for literacy. In F. Bryer, B. Bartlett, & D. Roebuck (Eds.), Proceedings Stimulating the “Action” as participants in participatory research 2 (pp. 39–45). Australia: Surfers Paradise.

Elo, S., & Kyngäs, H. (2008). The qualitative content analysis process. Journal of Advanced Nursing, 62 (1), 107–115. https://doi.org/10.1111/j.1365-2648.2007.04569.x

Article   PubMed   Google Scholar  

Elo, S., Kääriäinen, M., Kanste, O., Pölkki, T., Utriainen, K., & Kyngäs, H. (2014). Qualitative content analysis: A focus on trustworthiness. SAGE Open, 4 (1), 215824401452263. https://doi.org/10.1177/2158244014522633

English, L., & Gainsburg, J. (2016). Problem solving in a 21st-century mathematics curriculum. In L. English & D. Kirshner (Eds.), Handbook of international research in mathematics education (3rd ed., pp. 313–335). New York, NY: Routledge.

Galbraith, P., & Stillman, G. (2006). A framework for identifying student blockages during transitions in the modelling process. ZDM – Mathematics Education, 38 (2), 143–162. https://doi.org/10.1007/BF02655886

Geiger, V., Galbraith, P., Niss, M., & Delzoppo, C. (2021). Developing a task design and implementation framework for fostering mathematical modelling competencies. Educational Studies in Mathematics, 109 (2), 313–336. https://doi.org/10.1007/s10649-021-10039-y

Gencer, S. (2023). Development and use of flowchart for preservice chemistry teachers’ problem solving on the first law of thermodynamics. Journal of Chemical Education, 100 (9), 3393–3401. https://doi.org/10.1021/acs.jchemed.3c00224

Article   CAS   Google Scholar  

Grosskinsky, D. K., Jørgensen, K., & Hammer úr Skúoy, K. (2019). A flowchart as a tool to support student learning in a laboratory exercise. Dansk Universitetspædagogisk Tidsskrift, 14 (26), 23–35. https://doi.org/10.7146/dut.v14i26.104402

Guion, L. A., Diehl, D. C., & McDonald, D. (2011). Triangulation: Establishing the validity of qualitative studies. EDIS, (8), 3–3. https://doi.org/10.32473/edis-fy394-2011

Guk, I., & Kellogg, D. (2007). The ZPD and whole class teaching: Teacher-led and student-led interactional mediation of tasks. Language Teaching Research, 11 (3), 281–299. https://doi.org/10.1177/1362168807077561

Guthrie, J., Petty, R., Yongvanich, K., & Ricceri, F. (2004). Using content analysis as a research method to inquire into intellectual capital reporting. Journal of Intellectual Capital, 5 (2), 282–293. https://doi.org/10.1108/14691930410533704

Hacker, D. J., Dunlosky, J., & Graesser, A. C. (Eds.). (1998). Metacognition in educational theory and practice (1st ed.). Routledge. https://doi.org/10.4324/9781410602350

Hadamard, J. (1945). The psychology of invention in the mathematical field . Princeton, NJ: Princeton University Press.

Hankeln, C. (2020). Mathematical modeling in Germany and France: A comparison of students’ modeling processes. Educational Studies in Mathematics, 103 (2), 209–229. https://doi.org/10.1007/s10649-019-09931-5

Hooshyar, D., Ahmad, R. B., Yousefi, M., Fathi, M., Horng, S.-J., & Lim, H. (2016). Applying an online game-based formative assessment in a flowchart-based intelligent tutoring system for improving problem-solving skills. Computers and Education, 94 , 18–36. https://doi.org/10.1016/j.compedu.2015.10.013

Hsieh, H.-F., & Shannon, S. E. (2005). Three approaches to qualitative content analysis. Qualitative Health Research, 15 (9), 1277–1288. https://doi.org/10.1177/1049732305276687

Huang, X., Huang, R., & Trouche, L. (2023). Teachers’ learning from addressing the challenges of online teaching in a time of pandemic: A case in Shanghai. Educational Studies in Mathematics, 112 (1), 103–121. https://doi.org/10.1007/s10649-022-10172-2

Hughes, J. R. A., & Goodwin, J. (2014). Editors’ introduction: Human documents and archival research . University of Leicester. Chapter. https://hdl.handle.net/2381/31547

Jitendra, A. K., Dupuis, D. N., Rodriguez, M. C., Zaslofsky, A. F., Slater, S., Cozine-Corroy, K., & Church, C. (2013). A randomized controlled trial of the impact of schema-based instruction on mathematical outcomes for third-grade students with mathematics difficulties. The Elementary School Journal, 114 (2), 252–276. https://doi.org/10.1086/673199

Jonassen, D. H. (2012). Designing for decision making. Educational Technology Research and Development, 60 (2), 341–359. https://doi.org/10.1007/s11423-011-9230-5

Kaitera, S., & Harmoinen, S. (2022). Developing mathematical problem-solving skills in primary school by using visual representations on heuristics. LUMAT: International Journal on Math, Science and Technology Education, 10 (2), 111–146. https://doi.org/10.31129/LUMAT.10.2.1696

Karp, A., & Wasserman, N. (2015). Mathematics in middle and secondary school: A problem-solving approach . Charlotte, North Carolina: Information Age Publishing Inc.

Kim, K., Sharma, P., Land, S. M., & Furlong, K. P. (2012). Effects of active learning on enhancing student critical thinking in an undergraduate general science course. Innovative Higher Education, 38 (3), 223–235. https://doi.org/10.1007/s10755-012-9236-x

King, A. (1995). Designing the instructional process to enhance critical thinking across the curriculum: Inquiring minds really do want to know: Using questioning to teach critical thinking. Teaching of Psychology, 22 (1), 13–17. https://doi.org/10.1207/s15328023top2201_5

Article   MathSciNet   Google Scholar  

King, N. (2004). Using templates in the thematic analysis of text. In C. Cassell & G. Symon (Eds.), Essential guide to qualitative methods in organizational research (pp. 257–270). London, UK: Sage. https://doi.org/10.4135/9781446280119

Kingsdorf, S., & Krawec, J. (2014). Error analysis of mathematical word problem solving across students with and without learning disabilities. Learning Disabilities Research & Practice, 29 (2), 66–74. https://doi.org/10.1111/ldrp.12029

Kirova, A., & Jamison, N. M. (2018). Peer scaffolding techniques and approaches in preschool children’s multiliteracy practices with iPads. Journal of Early Childhood Research, 16 (3), 245–257. https://doi.org/10.1177/1476718X18775762

Koellner, K., Jacobs, J., & Borko, H. (2011). Mathematics professional development: Critical features for developing leadership skills and building teachers’ capacity. Mathematics Teacher Education & Development, 13 (1), 115–136. Retrieved from https://files.eric.ed.gov/fulltext/EJ960952.pdf

Krawec, J. L. (2014). Problem representation and mathematical problem solving of students of varying math ability. Journal of Learning Disabilities, 47 , 103–115. https://doi.org/10.1177/0022219412436976

Krohn, G. S. (1983). Flowcharts used for procedural instructions. Human Factors, 25 (5), 573–581. https://doi.org/10.1177/001872088302500511

Krutetskii, V. A. (1976). The psychology of mathematical abilities in schoolchildren . Chicago: University of Chicago Press.

Kules, B. (2016). Computational thinking is critical thinking: Connecting to university discourse, goals, and learning outcomes. Proceedings of the Association for Information Science and Technology, 53 (1), 1–6. https://doi.org/10.1002/pra2.2016.14505301092

Kyngäs, H., Mikkonen, K., & Kääriäinen, M. (2020). The application of content analysis in nursing science research . Cham: Springer. https://doi.org/10.1007/978-3-030-30199-6

Laughlin, P. R., Hatch, E. C., Silver, J. S., & Boh, L. (2006). Groups perform better than the best individuals on letters-to-numbers problems: Effects of group size. Journal of Personality and Social Psychology, 90 (4), 644–651. https://doi.org/10.1037/0022-3514.90.4.644

Lederman, R. P. (1991). Content analysis: Steps to a more precise coding procedure. MCN, The American Journal of Maternal Child Nursing, 16 (5), 275–275. https://doi.org/10.1097/00005721-199109000-00012

Ledin, P., & Machin, D. (2020). The misleading nature of flow charts and diagrams in organizational communication: The case of performance management of preschools in Sweden. Semiotica, 2020 (236), 405–425. https://doi.org/10.1515/sem-2020-0032

Lester, F. (2013). Thoughts about research on mathematical problem-solving instruction. The Mathematics Enthusiast, 10 (1–2), 245–278.

Lester, F. K., & Cai, J. (2016). Can mathematical problem solving be taught? Preliminary answers from 30 years of research. In P. Felmer, E. Pehkonen, & J. Kilpatrick (Eds.), Posing and solving mathematical problems: Advances and new perspectives (pp. 117–135). Springer International Publishing. https://doi.org/10.1007/978-3-319-28023-3_8

Lohse, G., Biolsi, K., Walker, N., & Rueter, H. (1994). A classification of visual representations. Communications of the ACM, 37 (12), 36–49. https://doi.org/10.1145/198366.198376

Makar, K. (2012). The pedagogy of mathematical inquiry. In R. Gillies (Ed.), Pedagogy: New developments in the learning sciences (pp. 371–397). Hauppauge, N.Y.: Nova Science Publishers.

Mason, J. (2016). When is a problem…? “When” is actually the problem! In P. Felmer, E. Pehkonen, & J. Kilpatrick (Eds.), Posing and solving mathematical problems. Advances and new perspectives (pp. 263–287). Switzerland: Springer. https://doi.org/10.1007/978-3-319-28023-3_16

Matty, A. N. (2016). A study on how inquiry based instruction impacts student achievement in mathematics at the high school level . ProQuest Dissertations Publishing. https://www.proquest.com/openview/da895b80797c90f9382f0c9a948f7f68/1?pq-origsite=gscholar&cbl=18750

McCormick, N. J., Clark, L. M., & Raines, J. M. (2015). Engaging students in critical thinking and problem-solving: A brief review of the literature. Journal of Studies in Education, 5 (4), 100–113. https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.960.810&rep=rep1&type=pdf

McGowan, M. M., & Boscia, M. W. (2016). Opening more than just a bag: Unlocking the flowchart as an effective problem-solving tool. The Journal of Health Administration Education, 33 (1), 211–219.

Merriam, S. B., & Tisdell, E. J. (2015). Qualitative research: A guide to design and implementation (4th ed.). Newark: Wiley.

Moon, J. (2008). Critical thinking: An exploration of theory and practice . Routledge. https://doi.org/10.4324/9780203944882

National Council of Teachers of Mathematics. (2000). Principles and standards for school mathematics . Reston, VA: National Council of Teachers of Mathematics.

Nieuwoudt, S. (2015). Developing a model for problem-solving in a Grade 4 mathematics classroom. Pythagoras, 36 (2), 1–7. https://doi.org/10.4102/pythagoras.v36i2.275

Norton, S. J., McRobbie, C. J., & Ginns, I. S. (2007). Problem-solving in a middle school robotics design classroom. Research in Science Education, 37 (3), 261–277. https://doi.org/10.1007/s11165-006-9025-6

Nowell, L. S., Norris, J. M., White, D. E., & Moules, N. J. (2017). Thematic analysis: Striving to meet the trustworthiness criteria. International Journal of Qualitative Methods, 16 (1), 1609406917733847. https://doi.org/10.1177/1609406917733847

Ouyang, F., Chen, S., Yang, Y., & Chen, Y. (2022). Examining the effects of three group-level metacognitive scaffoldings on in-service teachers’ knowledge building. Journal of Educational Computing Research, 60 (2), 352–379. https://doi.org/10.1177/07356331211030847

Owens, K. D., & Clements, M. A. (1998). Representations in spatial problem-solving in the classroom. The Journal of Mathematical Behavior, 17 (2), 197–218. https://doi.org/10.1016/S0364-0213(99)80059-7

Ozuem, W., Willis, M., & Howell, K. (2022). Thematic analysis without paradox: Sensemaking and context. Qualitative Market Research, 25 (1), 143–157. https://doi.org/10.1108/QMR-07-2021-0092

Pape, S. J., & Tchoshanov, M. A. (2001). The role of representation(s) in developing mathematical understanding. Theory into Practice, 40 (2), 118–127. https://doi.org/10.1207/s15430421tip4002_6

Parvaneh, H., & Duncan, G. J. (2021). The role of robotics in the development of creativity, critical thinking and algorithmic thinking. Australian Primary Mathematics Classroom, 26 (3), 9–13. https://doi.org/10.3316/informit.448545849534966

Patton, M. Q. (2002). Qualitative research and evaluation methods (3rd ed.). Sage Publications.

Polya, G. (1945). How to solve it: A new aspect of mathematical method . Princeton, NJ: Princeton University Press.

Polya, G. (1957). How to solve it: A new aspect of mathematical method . Princeton: Princeton University Press.

Polya, G. (1971). How to solve it: A new aspect of mathematical method (2nd ed.). Princeton University Press.

Queensland Curriculum and Assessment Authority (QCAA). (2018). Mathematical methods. general senior syllabus . Brisbane: Queensland Curriculum and Assessment Authority. https://www.qcaa.qld.edu.au/downloads/senior-qce/syllabuses/snr_maths_methods_19_syll.pdf

Raiyn, J. (2016). The role of visual learning in improving students’ high-order thinking skills. Journal of Education and Practice, 7 , 115–121. https://www.learntechlib.org/p/195092/

Reingewertz, Y. (2013). Teaching macroeconomics through flowcharts. International Review of Economics Education, 14 , 86–93. https://doi.org/10.1016/j.iree.2013.10.004

Reinholz, D. L. (2020). Five practices for supporting inquiry in analysis. Problems Resources and Issues in Mathematics Undergraduate Studies, 30 (1), 19–35. https://doi.org/10.1080/10511970.2018.1500955

Roam, D. (2009). The back of the napkin: Solving problems and selling ideas with pictures (1st ed.). Singapore: Marshall Cavendish International (Asia) Private Limited.

Rogoff, B., Malkin, C., & Gilbride, K. (1984). Interaction with babies as guidance in development. New Directions for Child and Adolescent Development, 1984 (23), 31–44. https://doi.org/10.1002/cd.23219842305

Roth, W. M., & McGinn, M. (1998). Inscriptions: Toward a theory of representing as social practice. Review of Educational Research, 68 (1), 35–59.

Sakshaug, L. E., & Wohlhuter, K. A. (2010). Journey toward teaching mathematics through problem-solving. School Science and Mathematics, 110 (8), 397–409. https://doi.org/10.1111/j.1949-8594.2010.00051.x

Santoso, B., & Syarifuddin, H. (2020). Validity of mathematic learning teaching administration on realistic mathematics education based approach to improve problem-solving. Journal of Physics. Conference Series, 1554 (1), 12001. https://doi.org/10.1088/1742-6596/1554/1/012001

Schoenfeld, A. H. (1980). Teaching problem-solving skills. The American Mathematical Monthly, 87 (10), 794. https://doi.org/10.2307/2320787

Schoenfeld, A. H. (1983). Problem solving in the mathematics curriculum . The Mathematical Association of America.

Schoenfeld, A. H. (2013). Reflections on problem-solving theory and practice. The Mathematics Enthusiast, 10 (1/2), 9.

Schoenfeld, A. H. (2016). Learning to think mathematically: Problem-solving, metacognition, and sense making in mathematics (Reprint). Journal of Education, 196 (2), 1–38. https://doi.org/10.1177/002205741619600202

Schoenfeld, A. H., Floden, R. E., & The algebra teaching study and mathematics assessment project. (2014). An introduction to the TRU Math document suite . Berkeley, CA & E. Lansing, MI: Graduate School of Education, University of California, Berkeley & College of Education, Michigan State University. Retrieved from: http://ats.berkeley.edu/tools.html

Schreier, M. (2012). Qualitative content analysis in practice . London: SAGE.

Snyder, H. (2019). Literature review as a research methodology: An overview and guidelines. Journal of Business Research, 104 , 333–339. https://doi.org/10.1016/j.jbusres.2019.07.039

Stone, C. A. (1998). Should we salvage the scaffolding metaphor? Journal of Learning Disabilities, 31 (4), 409–413. https://doi.org/10.1177/002221949803100411

Stylianou, D. A. (2010). Teachers’ conceptions of representation in middle school mathematics. Journal of Mathematics Teacher Education, 13 (4), 325–343. https://doi.org/10.1007/s10857-010-9143-y

Sweller, J., Van Merrienboer, J. J. G., & Paas, F. (2019). Cognitive architecture and instructional design: 20 years later. Educational Psychology Review, 31 (2), 261–292. https://doi.org/10.1007/s10648-019-09465-5

Sztajn, P., Borko, H., & Smith, T. (2017). Research on mathematics professional development. In J. Cai (Ed.), Compendium for research in mathematics education (Chapter 29, pp. 213–243). Reston, VA: National Council of Teachers of Mathematics.

Tobin, G. A., & Begley, C. M. (2004). Methodological rigor within a qualitative framework. Journal of Advanced Nursing, 48 , 388–396. https://doi.org/10.1111/j.1365-2648.2004.03207.x

Torraco, R. J. (2005). Writing integrative literature reviews: Guidelines and examples. Human Resource Development Review, 4 (3), 356–367. https://doi.org/10.1177/1534484305278283

Trouche, L., Gueudet, G., & Pepin, B. (2018). Documentational approach to didactics. In S. Lerman (Ed.), Encyclopedia of mathematics education. Cham: Springer. https://doi.org/10.1007/978-3-319-77487-9_100011-1

Trouche, L., Rocha, K., Gueudet, G., & Pepin, B. (2020). Transition to digital resources as a critical process in teachers’ trajectories: The case of Anna’s documentation work. ZDM Mathematics Education, 52 (7), 1243–1257. https://doi.org/10.1007/s11858-020-01164-8

Vale, I., & Barbosa, A. (2018). Mathematical problems: The advantages of visual strategies. Journal of the European Teacher Education Network, 13 , 23–33.

Vale, I., Pimentel, T., & Barbosa, A. (2018). The power of seeing in problem solving and creativity: An issue under discussion. In S. Carreira, N. Amado, & K. Jones (Eds.), Broadening the scope of research on mathematical problem-solving: A focus on technology, creativity and affect (pp. 243–272). Switzerland: Springer.

van Garderen, D., Scheuermann, A., Sadler, K., Hopkins, S., & Hirt, S. M. (2021). Preparing pre-service teachers to use visual representations as strategy to solve mathematics problems: What did they learn? Teacher Education and Special Education, 44 (4), 319–339. https://doi.org/10.1177/0888406421996070

Voskoglou, M. (2021). Problem solving and mathematical modelling. American Journal of Educational Research, 9 (2), 85–90. https://doi.org/10.12691/education-9-2-6

Vygotsky, L. S. (1978). Mind in society . Cambridge, MA: Harvard University Press.

Zahner, D., & Corter, J. E. (2010). The process of probability problem solving: Use of external visual representations. Mathematical Thinking and Learning, 12 (2), 177–204. https://doi.org/10.1080/10986061003654240

Zhang, J. (1997). The nature of external representations in problem solving. Cognitive Science, 21 (2), 179–217. https://doi.org/10.1207/s15516709cog2102_3

Download references

Acknowledgements

We would like to acknowledge and thank the teachers and students involved in the research.

Open Access funding enabled and organized by CAUL and its Member Institutions The study was financially supported by James Cook University Higher degree by research grant.

Author information

Authors and affiliations.

College of Arts, Society and Education, James Cook University, Cairns, Australia

Musarurwa David Chinofunga, Philemon Chigeza & Subhashni Taylor

You can also search for this author in PubMed   Google Scholar

Contributions

David: developed original idea, completed literature review, data analysis and authored the first draft of the article (80%). Philemon and Subhashni contributed to the data analysis, coherence of ideas and editing of the article (10% each).

Corresponding author

Correspondence to Musarurwa David Chinofunga .

Ethics declarations

Ethics approval.

This research was approved by the Human Research Ethics Committee, James Cook University (Approval Number H8201).

Informed consent

Informed consent was sought from all participants in accordance with the above ethics approval conditions. Before seeking consent from participants, permission was first obtained from the Queensland Department of Education and school principals of participating schools. The information sheets and consent forms were sent to participating mathematics teachers. An information sheet and consent form for students to share their artifacts was send through their teacher and consent was obtained directly from them as young adults (17–18 years). Consent forms and the data collected has been deidentified to protect participants and stored in the university repository.

Conflict of interest

The authors declare no competing interests.

Additional information

Publisher's note.

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

A research report which is part of a PhD study by the first author who is an experienced high school mathematics teacher in Queensland, Australia. The second and third authors are primary and secondary advisors respectively. Correspondence concerning this article should be addressed to David Chinofunga, College of Arts, Society and Education, Nguma-bada Campus, Smithfield, Building A4, Cairns, PO Box 6811 Cairns QLD 4870, Australia.

Appendix 1 An approach to problem solving and mathematical modelling

figure a

Appendix 2 Phases three and four thematic analysis themes

figure b

Rights and permissions

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/ .

Reprints and permissions

About this article

Chinofunga, M.D., Chigeza, P. & Taylor, S. How can procedural flowcharts support the development of mathematics problem-solving skills?. Math Ed Res J (2024). https://doi.org/10.1007/s13394-024-00483-3

Download citation

Received : 09 February 2023

Revised : 28 November 2023

Accepted : 06 January 2024

Published : 22 February 2024

DOI : https://doi.org/10.1007/s13394-024-00483-3

Share this article

Anyone you share the following link with will be able to read this content:

Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative

  • Problem solving
  • Procedural flowcharts
  • Problem-solving stages
  • Solution planning
  • Visual representation
  • Find a journal
  • Publish with us
  • Track your research

Mom and More

10 Helpful Worksheet Ideas for Primary School Math Lessons

M athematics is a fundamental subject that shapes the way children think and analyze the world. At the primary school level, laying a strong foundation is crucial. While hands-on activities, digital tools, and interactive discussions play significant roles in learning, worksheets remain an essential tool for reinforcing concepts, practicing skills, and assessing understanding. Here’s a look at some helpful worksheets for primary school math lessons.

Comparison Chart Worksheets

Comparison charts provide a visual means for primary school students to grasp relationships between numbers or concepts. They are easy to make at www.storyboardthat.com/create/comparison-chart-template , and here is how they can be used:

  • Quantity Comparison: Charts might display two sets, like apples vs. bananas, prompting students to determine which set is larger.
  • Attribute Comparison: These compare attributes, such as different shapes detailing their number of sides and characteristics.
  • Number Line Comparisons: These help students understand number magnitude by placing numbers on a line to visualize their relative sizes.
  • Venn Diagrams: Introduced in later primary grades, these diagrams help students compare and contrast two sets of items or concepts.
  • Weather Charts: By comparing weather on different days, students can learn about temperature fluctuations and patterns.

Number Recognition and Counting Worksheets

For young learners, recognizing numbers and counting is the first step into the world of mathematics. Worksheets can offer:

  • Number Tracing: Allows students to familiarize themselves with how each number is formed.
  • Count and Circle: Images are presented, and students have to count and circle the correct number.
  • Missing Numbers: Sequences with missing numbers that students must fill in to practice counting forward and backward.

Basic Arithmetic Worksheets

Once students are familiar with numbers, they can start simple arithmetic. 

  • Addition and Subtraction within 10 or 20: Using visual aids like number lines, counters, or pictures can be beneficial.
  • Word Problems: Simple real-life scenarios can help students relate math to their daily lives.
  • Skip Counting: Worksheets focused on counting by 2s, 5s, or 10s.

Geometry and Shape Worksheets

Geometry offers a wonderful opportunity to relate math to the tangible world.

  • Shape Identification: Recognizing and naming basic shapes such as squares, circles, triangles, etc.
  • Comparing Shapes: Worksheets that help students identify differences and similarities between shapes.
  • Pattern Recognition: Repeating shapes in patterns and asking students to determine the next shape in the sequence.

Measurement Worksheets

Measurement is another area where real-life application and math converge.

  • Length and Height: Comparing two or more objects and determining which is longer or shorter.
  • Weight: Lighter vs. heavier worksheets using balancing scales as visuals.
  • Time: Reading clocks, days of the week, and understanding the calendar.

Data Handling Worksheets

Even at a primary level, students can start to understand basic data representation.

  • Tally Marks: Using tally marks to represent data and counting them.
  • Simple Bar Graphs: Interpreting and drawing bar graphs based on given data.
  • Pictographs: Using pictures to represent data, which can be both fun and informative.

Place Value Worksheets

Understanding the value of each digit in a number is fundamental in primary math.

  • Identifying Place Values: Recognizing units, tens, hundreds, etc., in a given number.
  • Expanding Numbers: Breaking down numbers into their place value components, such as understanding 243 as 200 + 40 + 3.
  • Comparing Numbers: Using greater than, less than, or equal to symbols to compare two numbers based on their place values.

Fraction Worksheets

Simple fraction concepts can be introduced at the primary level.

  • Identifying Fractions: Recognizing half, quarter, third, etc., of shapes or sets.
  • Comparing Fractions: Using visual aids like pie charts or shaded drawings to compare fractions.
  • Simple Fraction Addition: Adding fractions with the same denominator using visual aids.

Money and Real-Life Application Worksheets

Understanding money is both practical and a great way to apply arithmetic.

  • Identifying Coins and Notes: Recognizing different denominations.
  • Simple Transactions: Calculating change, adding up costs, or determining if there’s enough money to buy certain items.
  • Word Problems with Money: Real-life scenarios involving buying, selling, and saving.

Logic and Problem-Solving Worksheets

Even young students can hone their problem-solving skills with appropriate challenges.

  • Sequences and Patterns: Predicting the next item in a sequence or recognizing a pattern.
  • Logical Reasoning: Simple puzzles or riddles that require students to think critically.
  • Story Problems: Reading a short story and solving a math-related problem based on the context.

Worksheets allow students to practice at their own pace, offer teachers a tool for assessment, and provide parents with a glimpse into their child’s learning progression. While digital tools and interactive activities are gaining prominence in education, the significance of worksheets remains undiminished. They are versatile and accessible and, when designed creatively, can make math engaging and fun for young learners.

The post 10 Helpful Worksheet Ideas for Primary School Math Lessons appeared first on Mom and More .

Mathematics is a fundamental subject that shapes the way children think and analyze the world. At the primary school level, laying a strong foundation is crucial. While hands-on activities, digital tools, and interactive discussions play significant roles in learning, worksheets remain an essential tool for reinforcing concepts, practicing skills, and assessing understanding. Here’s a look […]

IMAGES

  1. Math Problem Solving Strategies

    what are the problem solving skills in mathematics

  2. (PDF) Problem-solving Skills in Mathematics Learning

    what are the problem solving skills in mathematics

  3. 😎 Problem solving mathematics. Seminar on problem solving in mathematics pdf. 2019-01-21

    what are the problem solving skills in mathematics

  4. what are problem solving skills in business

    what are the problem solving skills in mathematics

  5. View source image

    what are the problem solving skills in mathematics

  6. SU LMS

    what are the problem solving skills in mathematics

VIDEO

  1. Maths

  2. Functional Skills Mathematics Level 2 Finding a Range

  3. A wonderful mathematics problem|Olympiad Question|can you solve this problem|x=?,y=?,a=?

  4. Functional Skills Mathematics Level 2 Finding a Median

  5. Mathematics Olympiad Learn how to solve this challenging problem math olympiad question

  6. Calculus ( Jan2023 Q4b)

COMMENTS

  1. 6 Tips for Teaching Math Problem-Solving Skills

    1. Link problem-solving to reading When we can remind students that they already have many comprehension skills and strategies they can easily use in math problem-solving, it can ease the anxiety surrounding the math problem.

  2. 1.1: Introduction to Problem Solving

    Mathematically proficient students start by explaining to themselves the meaning of a problem and looking for entry points to its solution. They analyze givens, constraints, relationships, and goals. They make conjectures about the form and meaning of the solution and plan a solution pathway rather than simply jumping into a solution attempt.

  3. PDF Problem solving in mathematics

    policy advice on recent reforms across all key stages; sections in ACME reports, for example Mathematical Needs: Mathematics in the workplace and in Higher Education and Mathematical Needs of learners. Further information can be found at www.acme-uk.org/policy-advice/ qualifications-and-assessment.

  4. Problem Solving in Mathematics

    When deciding on methods or procedures to use to solve problems, the first thing you will do is look for clues, which is one of the most important skills in solving problems in mathematics. If you begin to solve problems by looking for clue words, you will find that these words often indicate an operation. Look for Clue Words

  5. Problem Solving Skills: Meaning, Examples & Techniques

    Problem-solving skills can be defined as the ability to identify a problem, determine its cause, and figure out all possible solutions to solve the problem. Also read: Trigonometric Problems Problem Solving Skills: Meaning, Examples & Techniques What is problem-solving, then?

  6. Teaching Mathematics Through Problem Solving

    Teaching about problem solving begins with suggested strategies to solve a problem. For example, "draw a picture," "make a table," etc. You may see posters in teachers' classrooms of the "Problem Solving Method" such as: 1) Read the problem, 2) Devise a plan, 3) Solve the problem, and 4) Check your work. There is little or no ...

  7. Module 1: Problem Solving Strategies

    George Pólya was a great champion in the field of teaching effective problem solving skills. He was born in Hungary in 1887, received his Ph.D. at the University of Budapest, and was a professor at Stanford University (among other universities). ... which gave a four-step method for solving mathematical problems: First, you have to understand ...

  8. Problem Solving in Mathematics Education

    Singer et al. ( 2013) provides a broad view about problem posing that links problem posing experiences to general mathematics education; to the development of abilities, attitudes and creativity; and also to its interrelation with problem solving, and studies on when and how problem-solving sessions should take place.

  9. Problem solving

    The greater your skill in this area, the better you are at searching for meaning; making predictions; generating possible solutions; justifying and understanding how you solved something; coping...

  10. The Problem-solving Classroom

    NRICH defines 'problem-solving skills' as those skills which children use once they have got going on a task and are working on the challenge itself. The skills which we consider to be key at NRICH are: Visualising Working backwards Reasoning logically Conjecturing Working systematically Looking for patterns Trial and improvement.

  11. PDF Developing mathematical problem-solving skills in primary school by

    The importance of developing mathematical reasoning and problem -solving skills is also recognised in international assessments, such as PISA and TIMSS. In PISA the problem-solving competence is defined as "an individuals' capacity to engage in cognitive processing to understand and resolve problem situations where a method of

  12. How to Improve Problem-Solving Skills: Mathematics and Critical

    Wonder Math October 23, 2023 All Posts In today's rapidly changing world, problem-solving has become a quintessential skill. When we discuss the topic, it's natural to ask, "What is problem-solving?" and "How can we enhance this skill, particularly in children?" The discipline of mathematics offers a rich platform to explore these questions.

  13. PDF Skills Needed for Mathematical Problem Solving

    Skills: arithmetic, algebraic geometric manipulations, estimation, approximation, reading with understanding ... Thinking and Reasoning: Inductive and deductive reasoning, critical and creative thinking, use of heuristics ... Metacognition: Analyze and control one's thinking.

  14. Mathematics as a Complex Problem-Solving Activity

    Problem-solving in mathematics supports the development of: The ability to think creatively, critically, and logically. The ability to structure and organize. The ability to process information. Enjoyment of an intellectual challenge. The skills to solve problems that help them to investigate and understand the world.

  15. Development and differences in mathematical problem-solving skills: A

    2.1. Mathematical problem-solving skills and their development. Solving mathematical problems is a complex cognitive ability that requires students to understand the problem as well as apply mathematical concepts to them [].Researchers have described the phases of solving a mathematical problem as understanding the problem, devising a plan, conducting out the plan, and looking back [, , , , ].

  16. Problem Solving Maths: Strengthening Mathematical Skills

    Maths problem solving is when a mathematical task challenges pupils to apply their knowledge, logic and reasoning in unfamiliar contexts. Problem solving questions often combine several elements of maths.

  17. PDF Students' Mathematical Problem-solving Ability Based on ...

    Firstly, understanding the problem is the ability to convince yourself that students understand the problem correctly, by describing known and unknown elements, what quantities are known, how they are, whether there are exceptions, and what is asked.

  18. Roles and characteristics of problem solving in the mathematics

    Abstract. Since problem solving became one of the foci of mathematics education, numerous studies have been performed to improve its teaching, develop students' higher-level skills, and evaluate its learning.

  19. How to Improve Problem-Solving Skills in Math

    4. Preparation for future careers: Problem-solving skills are highly sought after by employers in various fields. Developing strong problem-solving skills in math sets students up for successful careers in engineering, technology, finance, and more. Problem-solving skills are essential for math education and have numerous benefits for students.

  20. Building Problem-solving Skills for 7th-Grade Math

    Ratios and proportions: Students should be able to understand and use ratios and proportions in a variety of contexts, including scale drawings and maps. In conclusion, problem-solving skills are essential for success in 7th grade math. Analytical skills, critical and creative thinking, problem-solving strategies, persistence, communication ...

  21. PDF Fostering Problem Solving and Critical Thinking in Mathematics Through

    To tackle this issue, we propose mathematical problem solving activities to be carried out with the aid of ChatGPT, showing how problem solving and critical thinking ... C. et al, 2021. Development of Problem Solving Skills with Maple in Higher Education. In: Corless R.M., Gerhard J., Kotsireas I.S. (eds.) Maple in Mathematics Education and ...

  22. Elevating Math Education Through Problem-Based Learning

    Skills and Understanding. Despite the challenges, the trend toward PBL in math education has been growing, driven by evidence of its benefits in developing critical thinking, problem-solving skills and a deeper understanding of mathematical concepts, as well as building more positive math identities.The incorporation of PBL aligns well with the contemporary broader shift toward more student ...

  23. The Scale for Problem Solving Skills in Mathematics: Further Evidence

    The Scale for Problem Solving Skills in Mathematics was developed by Uysal (2007) in order to determine the level of school students‟ problem solving skills in mathematics. This self-report instrument consists of 28 items scored on a five-point Likert type scale with responses ranging between 1 (never) to 5 (always) and has three subscales ...

  24. Problem-solving Skills in Mathematics Learning

    The same result had found by (Behra, 2009) on his study on problem-solving skills in mathematics learning. Manohra and Ramganesh (2009) conducted a study on creative problem-solving ability of ...

  25. How can procedural flowcharts support the development of mathematics

    Supporting students' problem-solving skills, solution planning and sequencing of different stages that are involved in successfully developing a meaningful solution to a problem has been a challenge for teachers. This case study was informed by reflective investigation methodology which explored how procedural flowcharts can support student mathematics problem solving in a senior ...

  26. 10 Helpful Worksheet Ideas for Primary School Math Lessons

    Mathematics is a fundamental subject that shapes the way children think and analyze the world. At the primary school level, laying a strong foundation is crucial. While hands-on activities ...

  27. Learning Links Foundation on Instagram: "We're thrilled to announce the

    2 likes, 0 comments - learninglinksfoundation on February 19, 2024: "We're thrilled to announce the grand inauguration of our latest Think Big Space lab at Navi Mum..."