105  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020) 

 

Learning Mathematics Through Mathematical Modelling Processes 

Within Sports Day Activity 

1
 Sakon Tangkawsakul, 

2
Nuttapat Mookda, & 

3
Weerawat Thaikam 

1 Faculty of Education, Kasetsart University, Bangkok, Thailand 
 
2
 Directorate of Education and Training, RTAF, Thailand 

3
Faculty of Education, Nakhonsawan Rajabhat University, Nakhonsawan, Thailand 

1
 s.tangkawsakul@gmail.com 

 

Abstract 

Applying mathematics in real-life situations is an important objective of mathematics 

education. Yet in Thailand, the students' ability to connect mathematics to real-life situations 

is insufficient.  In this study, we adapted the school sports day to provide opportunities to 

relate real-life situations with mathematical knowledge and skills. This study aims to describe 

the students' responses and the teacher's interaction during a modelling task. The designing of 

the modelling task, inspired by the realistic Fermi problems, involves collaboration between 

mathematics teachers and educators and the participation of 10th grade students. The task is 

set in the context of bleacher in the school sports day. Each experiment's modelling task lasted 

for 45 minutes and was conducted in the one-day camp with 45 students. Data were collected 

through observation, interview, and written task before being analysed through content 

analysis. The results showed that the students who had no previous mathematical modelling 

experience engaged in mathematical modelling processes with their friends under the 

guidance and support of the teacher. Most of them were able to think, make assumptions, 

collect data, observe, make conjectures and create mathematical models to understand and 

solve the modelling task. 

 

Keywords: mathematical modelling, realistic Fermi problems, sports day, real-world problems. 

 

 

Introduction 

In several countries, the promotion of science, technology, engineering, and mathematics 

(STEM) education is an essential educational topic that enables students for a scientific and 

technological society. One of the important teaching and learning approaches for the 

transition to STEM education and interdisciplinary mathematics education is mathematical 

modelling (Borromeo Ferri & Mousoulides, 2017; Tezer, 2019). Besides, mathematical 

modelling can be considered good examples of STEM integration (Kertil & Gurel, 2016).  

Actually, mathematical modelling supports mathematical learning and enables students to 

deal with real-world problems (Blum & Borromeo Ferri, 2009). Although the ability to apply 

mathematical knowledge and solve real-world problems has been recognised in the Basic 

Education Core Curriculum in Thailand, both students and teachers have little experience in 

mathematical modelling. Moreover, about 50 per cent of 15-year-old Thai students did not 

achieve the international basic proficiency level (level 2) at mathematical literacy in PISA 

2009 and PISA 2012. These results show that Thai students lack the ability to connect real-

world problems with mathematics (Klainin, 2015). 

Hence, we were interested in observing and describing how the students respond to 

modelling activities. To achieve that purpose, we started by designing tasks to encourage 

students to connect inside and outside classroom mathematics and foster their ability to solve 



106  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020) 

 

real-world problems with mathematical modelling processes. We adapted the idea of using 

realistic fermi problems about the bleacher in the school sports day, closely related to Thai 

students’ experiences, to introduce mathematical modelling in upper secondary mathematics 

following Ärlebäck and Bergsten (2013). The questions we aim to answer in this paper are as 

follows: 

1. How does the teacher interact with students during the mathematical modelling task? 

2. How do the students respond to mathematical modelling task? 

 

This study aims at describing the students' responses to the modelling task and the 

teacher's interaction with their students during mathematical modelling processes. 

 

Theoretical Framework 

Mathematical modelling processes 

Mathematical modelling is an essential educational topic that fosters the students' ability to 

deal with real-world problems (Blum & Ferri 2009). Mathematical modelling processes 

showed how the process connects real-life contexts and mathematics content. It might look 

different and highlight different perspectives depending on the research's purpose and focus 

(Blum, Galbraith, & Niss, 2007). In this study, we adapted an ideal modelling process that 

includes six phases allowing cognitive activities to solve the modelling tasks described by 

Ferri (2006) as shown in Figure1. 

 

 

Figure 1. Modelling cycle under a cognitive perspective described by Ferri (2006). 

Based on Ferri's model, modelling processes consisted of two components:  phases and 

transitions that intertwined between two domains, reality and mathematics. The six phases 

comprise a real situation, mental representation of the situation, real model, mathematical 

model, mathematical result and real result. Simultaneously, the transitions include six 

activities: understanding the task, simplifying/structuring the task, mathematising, working 

mathematically, interpreting and validating. 

  



107  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020) 

 

The realistic Fermi problems  

There are several important principles in model-eliciting activities (Lesh, Hoover, Hole, 

Kelly, & Post, 2000). Two of them are: 1) model construction principle, as in the problem 

must evoke the need to mathematise and model meaningful situation to solve a problem, and 

2) reality principle, as in the problem need to be relevant and meaningful to the students; the 

kind that they might encounter in real life. Effective modelling activities should also be open, 

in a sense that there are no predetermined right answers. The students have the freedom to 

choose the most suitable mathematical concepts they will use to solve the problem. 

One of the notions that fit these principles is the Fermi problem. The term Fermi problem 

originates from the 1938 Italian Nobel Prize winner in physics Enrico Fermi (1901-1954). He 

had posed and solved problems like how many piano tuners are there in the US. He 

demonstrated that using a few reasonable assumptions and estimates could give accurate and 

reasonable answers (Efthimiou & Llewellyn, 2007). The Fermi problem was always 

answered by simplifying, making assumptions, estimating, and doing rounded calculations 

while the exact answer is often not available. It is the main important feature of the Fermi 

problem-solving process (Sowder, 1992). 

According to Ärlebäck and Bergsten (2013), the characters of Realistic Fermi Problems 

was described as follow: 

1. the realistic Fermi problem does not necessarily demand any specific pre-mathematical 
knowledge. All individual students or groups of students can access and solve the 

problem; 

2. the realistic Fermi problem is more than just an intellectual exercise. The context is 
realistic and presents clear real-world connection; 

3. the realistic Fermi problem is open. The specifying and structuring of the relevant 
information and relationships are needed to tackle the problem; 

4. the realistic Fermi problem does not show the numerical data. The problem solver 
needs to make reasonable estimates of relevant quantities, and 

5. the realistic Fermi problem is to promote group discussion. 
 

Design of the Study  

The question was posited as the students' responses to the modelling task and teachers' 

interaction with their students during each mathematical modelling processes. 

 

Participants 

The study participants were divided into two groups. The first comprised three 

mathematics teachers and two mathematics educators interested in mathematical modelling, 

while the second consisted of 45 tenth grade students. These students had no previous 

experience in mathematical modelling in the classroom based on the Basic Education Core 

Curriculum of Thailand. 

 

Methods 

In designing the bleacher task, the task's objectives were to encourage students to connect 

inside and outside classroom mathematics and enhance their ability to solve real-world 

problems with mathematical modelling. We designed and validated the task by collaborating 



108  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020) 

 

with three mathematics teachers and two mathematics educators interested in mathematical 

modelling. The task validation is based on four notions below.  

1. The characters of Realistic Fermi Problems described by Ärlebäck and Bergsten 
(2013). 

2. The information on the students’ experiences and prior knowledge relevant to the task. 
This information was collected by conducting interviews with mathematics teachers 

who had experience teaching these students. The interview was important to confirm 

that the bleacher in the school sports day problem is both encouraging and engaging 

context for the students. 

3. The framework for designing mathematical modelling learning experience described 
by Ang (2018).  

4. The modelling cycle under a cognitive perspective described by Ferri (2006). 
 

The bleacher task is as follows: 

 

The bleacher task: 

 

In the school sports day, all students were organised into several groups with wide-ranging 

sports and varied performance abilities. Each group was labelled by colour to participate in 

sports, cheerleading and bleacher cheer show performance.  

 

You and your team members are given the relevant materials. Draw your own conclusions 

and answer these following questions:  

1. How many students that can reasonably be arranged in the bleacher for cheer show 

performance? 

2. What is the relationship between the sizes of bleacher and the numbers of students? 

 

In implementing the bleacher task, a qualitative approach was adopted. The teacher's role 

(one of the authors) was as a facilitator, encouraging and guiding a small group of students to 

deal with the bleacher task. The 45 students were divided into eight groups of 4 – 5 students 

with wide-ranging abilities in mathematics. Each experiment lasted for 45 minutes and was 

conducted with two groups of students in the one-day camp. The students' responses and 

teachers' interactions during mathematical modelling process were gathered through 

observations, written work, and interviews. The data were analysed by content analysis 

according to the mathematical modelling framework by Ferri (2006). The result is presented 

in a narrative description. 

 

Results and Discussion 

This study showed the students' responses to the bleacher task and the way that teacher 

interact with their students during each mathematical modelling process as follows. 

Initially, the teacher and students met at bleacher in the school playground (Figure 2). The 

teacher asked the student about their experience with the bleacher on the school sports day. 

All of the students participated in the conversation about the bleacher. The students were 

given the bleacher task. The teacher then gave the students time to understand the task and 

discuss what the problem wanted to know with their friends (Figure 3). 



109  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020) 

 

 

 
Figure 2. Meeting at bleacher in the school playground. 

 

 
Figure 3. Understanding the task. 

 

Next, the teacher discussed the factors related to determining the number of students 

sitting on the bleacher to guide students to simplify the task and make assumptions. Most of 

the students' assumptions were as follows:  

1. each student must be seated according to the size of the bleacher, fit, and not 
overcrowded; 

2. the sitting position must look neat and straight; and 
3. the sitting posture must be the same. 
 

Besides, one group assumed the distance between each student must be appropriate for 

movement in performance. Then, the teacher asked the students what the relevant and 

necessary data is, which we have to search for solving the problem. Some groups of students 

identified some unnecessary data (width and height of the bleacher). In these cases, the 

teacher asked them how the bleacher's width and height were relevant and necessary for 

solving the problem. They discussed and found that the bleacher's width and height were not 

necessary (Figure 4).  

 

 
Figure 4. Identifying some unnecessary data. 



110  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020) 

 

On the other hand, most students were available to identify the relevant and necessary data 

(the size of the student who sat on a bleacher or area for sitting per person) as shown in 

Figure 5. During their search for the data, two groups have interesting reasons for 

determining the size of the student which connects between real-world and mathematics such 

as knowing the height and weight of the student to choose the right seated student, fit and 

balance to the bleacher, and sitting in a straight line. 

 

 
Figure 5. Identifying the relevant and necessary data. 

 

After that, the teacher guided the students to create a real model which simplified and 

structured students' mental picture (Figure 6). They used drawings and diagrams to represent 

the bleacher's size, sitting position, and distance between each student. Some student groups 

identified conditions about sitting posture and performance on the bleacher such as space for 

placing cheer prop and students' size and height. 

 
Figure 6. A real model which simplified and structured students’ mental picture. 

 

The teacher then allowed the students time to discuss and think about the appropriate 

mathematical knowledge and concepts related to solving the problem. Moreover, they tried to 

sit (Figure 7) and measure by using the measuring tape (Figure 8) to collect data, observe, 

make conjectures, and create mathematical models to solve the problem under the teacher's 

guidance and support. 

 
Figure 7. Sitting experiment. 

 



111  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020) 

 

 
Figure 8. Measuring using the measuring tape. 

 

The students used the bleacher sizing and the sitting experiments and obtained 

measurement from the different width of the body (the lap and shoulder). Some groups used 

either the actual measurements (2 decimal places) or approximate values from their 

measurements which round it to integers to make calculations easier (Figure 9). Finally, some 

groups used only one value from one measurement, while others choose to use the mean of 

values from their repeated measurements. Next step, the students worked mathematically 

based on unit rate ideas to represent the relation of seat length per person, then created the 

relation between seat length and the number of the students in general term. The teacher 

asked the students to interpret and check the mathematical results. 

 

 
Figure 9. Working mathematically. 

Furthermore, students validated the result by comparing the solution with their experience. 

Finally, they have to share their problem-solving processes and explain the meaning of all 

variables in the equation based on the real-world situation to others, as shown in Figure 10. In 

this step, we found that some groups have mistaken in interpreting. For example, the students 

used the equation (y = 25x) to model the general relation between seat length (y) and the 

number of students (x). 

 

 
Figure 10. Sharing their problem-solving processes. 



112  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020) 

 

In this case, the teacher asked students to think about applying the student's model in a 

normally real-world context because actually we knew the size of the bleacher first then 

found the number of students. So, the teacher tried to lead students to concern about the 

independent variable (input) and the dependent variable (output) based on the real-world 

situation. 

It was evident from the result that the use of open and complex problems for a diverse 

solution, like Fermi problems, can be an effective modelling task. The problem can elicit the 

cognitive processes essential to mathematical modelling (Ferri, 2006) from the students. This 

is in line with the studies by Peter-Koop (2004) and Ärlebäck (2009), which demonstrate 

Fermi problems' potential to engage the students and encourage them through multiple 

modelling cognitive stages. 

 

Conclusion 

The description of the students' response and the teacher's interaction shows that typical 

Fermi problem, which is open, ill-structured, and possesses high-complexity, can effectively 

engage the students throughout the modelling task and elicit an appropriate cognitive 

response. The real-world context that is closed and related to students' experience also 

enhances students' engagement in the mathematical modelling processes with their friends 

under the teacher's guidance and support. It is recommended for the teacher to plan to deal 

with students in the modelling activity to know about the phases and their transitions in each 

modelling cycle because it is essential to guide and support them in dealing with a real-world 

problem. 

 

 

 

References 

Ang, K. C. (2018). Mathematical modelling for teachers: Resources, pedagogy and practice. 

London, England: Routledge. 

Ärlebäck, J. B., & Bergsten, C. (2013). On the use of realistic Fermi problems in introducing 

mathematical modelling in upper secondary mathematics. In Lesh R., Galbraith P., 

Haines C., Hurford A. (eds) Modeling Students' Mathematical Modeling 

Competencies (pp. 597-609).  Dordrecht, Netherlands: Springer. doi: 10.1007/978-1-

4419-0561-1_52 

Blum, W., & Borromeo Ferri, R. (2009). Mathematical modelling: Can it be taught and 

learnt? Journal of Mathematical Modelling and Application, 1(1), 45-58. 

Borromeo Ferri, R. (2018). Learning how to teach mathematical modelling in school and 

teacher education. Springer International Publishing. doi: 10.1007/978-3-319-68072-9 

Borromeo Ferri, R., & Mousoulides, N. (2017). Mathematical modelling as a prototype for 

interdisciplinary mathematics education? - Theoretical reflections. In T. Dooley & G. 

Gueudet (Eds.), Proceedings of CERME 10 (pp. 900-907). Dublin, Ireland: ERME. 



113  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020) 

 

Efthimiou, C. J., & Llewellyn, R. A. (2007). Cinema, Fermi problems and general education. 

Physics Education, 42(3), 253-261. doi: 10.1088/0031-9120/42/3/003 

Kertil, M., & Gurel, C. (2016). Mathematical modelling: A bridge to STEM 

education. International Journal of Education in mathematics, science and 

Technology, 4(1), 44-55. doi: 10.18404/ijemst.95761 

Sowder, J. T. (1992). Estimation and number sense. In D. A. Grouws (Ed.), Handbook of 

research on mathematics teaching and learning: A project of the National Council of 

Teachers of Mathematics (p. 371–389). Reston, VA: The National Council of Teachers 

of Mathematics, Inc. 

Sunee, Klainin. (2015). Mathematics education at school level in Thailand the development – 

The impact - The dilemmas. Retrieved from https://library.ipst.ac.th/handle/ipst/959 

Tezer, M. (2019). The Role of Mathematical Modeling in STEM Integration and Education. 

In K.G. Fomunyam (Ed.) Theorizing STEM Education in the 21st Century. 

IntechOpen. doi: 10.5772/intechopen.88615 

  

https://library.ipst.ac.th/handle/ipst/959


114  Southeast Asian Mathematics Education Journal, Volume 10, No 2 (2020)