PARADIGMA BARU PENDIDIKAN MATEMATIKA DAN APLIKASI ONLINE INTERNET PEMBELAJARAN


Student Group Dynamic Model Based on Understanding in 

Mathematics Subjects 
 

 

M. Ivan Ariful Fathoni1*, Anisa Fitri2, Hanifahtul Husnah3 

1,2,3Department of Mathematics Education, Universitas Nahdlatul Ulama Sunan Giri,  

Bojonegoro, Indonesia 

 

 
 

Article history: 

Received Nov 21, 2020 

Revised May 6, 2021 

Accepted May 30, 2021 

 

 

Kata Kunci:  

Sistem dinamik,  

Model matematika, 

Titik ekuilibrium, 

Interaksi peserta 

didik, Proses 

pembelajaran 

 

Abstrak. Penelitian ini membahas tentang interaksi peserta didik 

dengan sudut pandang pemodelan matematika. Interaksi tersebut 

melibatkan peserta didik yang memahami dan belum memahami materi 

mata pelajaran matematika. Proses interaksi antar grup peserta didik 

dimodelkan dalam suatu sistem persamaan diferensial dua dimensi. 

Variabel A adalah persentase peserta didik yang memahami materi, dan 

variabel B adalah persentase peserta didik yang kurang memahami 

materi. Hasil analisis dinamik diperoleh satu titik ekuilibrium trivial dan 

tiga titik ekuilibrium non-trivial yang eksis dengan beberapa syarat. 

Berdasarkan analisis kestabilan titik ekuilibrium non-trivial, diperoleh 

kondisi tanpa adanya peserta didik yang kurang memahami materi 

pelajaran matematika. Kondisi inilah yang menjadi tujuan dari 

penelitian ini, dimana dengan melibatkan interaksi antar peserta didik, 

dapat meningkatkan keberhasilan proses pembelajaran. 

 

Keywords:  

Dynamical system, 

Mathematical model, 

Equilibrium points, 

Student interaction, 

Learning process 

 

 

Abstract. This study discusses the interaction of students with a 

mathematical modeling point of view. This interaction involves 

students who understand and do not understand mathematics subject 

matter. The interaction process between groups is modeled in a two-

dimensional system of differential equations. Variable A is the 

percentage of students who understand the material, and variable B is 

the percentage of students who do not understand the material. The 

dynamic analysis results obtained by one trivial equilibrium point and 

three non-trivial equilibrium points exist with several conditions. Based 

on the stability analysis of the non-trivial equilibrium point, it is found 

that the conditions without students do not understand mathematics 

subject matter. This condition is the goal of this study, which involves 

interaction between students; it can increase the learning process's 

success. 

  

 

How to cite: 

M. I. A. Fathoni, A. Fitri, and H. Husnah, “Student Group Dynamic Model Based on Understanding 

in Mathematics Subjects”, J. Mat. Mantik, vol. 7, no. 1, pp. 41-50, May 2021. 

 

 
 

  

Jurnal Matematika MANTIK 

Vol. 7, No. 1, May 2021, pp. 41-50 

 

ISSN: 2527-3159 (print) 2527-3167 (online) 

CONTACT:  

M. Ivan Ariful Fathoni,          fathoni@unugiri.ac.id            Department of Mathematics Education, Universitas 
Nahdlatul Ulama Sunan Giri, Bojonegoro, Jawa Timur 62115, Indonesia  

 

       The article can be accessed here. https://doi.org/10.15642/mantik.2021.7.1.41-50   

mailto:fathoni@unugiri@ac.id
https://doi.org/10.15642/mantik.2021.7.1.41-50
http://u.lipi.go.id/1458103791


Jurnal Matematika MANTIK 

Vol. 7, No. 1, May 2021, pp. 41-50 
 

42 

 

1. Introduction  
 

Education means increased skill or development of knowledge and understanding as 

a result of practice, study, or experience [1]. The importance of education places it at the 

highest level of human needs. In the introduction to the book written by Klaus Dieter Bieter, 

Nelson Mandela calls education a powerful force that builds every human being. All 

countries in the world place education as one of the human rights [2]. Likewise, in 

Indonesia, education is one area that is the responsibility of the State. Law of the Republic 

of Indonesia states that: education is a conscious, planned effort to create an atmosphere of 

learning and the learning process to actively develop their potential to have spiritual 

strength, self-control, personality, intelligence, noble morals, and skills needed for 

themselves, society, nation, and state [3] [4].  

In general, education aims to increase the nation's intelligence by increasing students' 

understanding of the subject matter. There are many obstacles for a country to create good 

quality education, especially in developing countries. One of the problems faced in the 

world of education is the weak learning process. Students are encouraged to develop 

thinking skills in the learning process, but in reality, students are only directed to accept 

and memorize information or knowledge provided by the teacher. The teaching method is 

one of the supporting factors for the achievement of national education goals [5]. 

As one of the basic sciences, mathematics has an essential role in the effort to master 

science and technology. Mathematics in schools needs to function as a vehicle to develop 

intelligence, abilities, and skills and shape students' personalities [6]. Not a few students 

think that mathematics is a difficult subject and causes various problems that are difficult 

to solve, resulting in low student learning outcomes. This results from the lack of interactive 

mathematics learning methods, where students are only asked to memorize formulas, 

receive the material, and work on practice questions. Therefore, there is a need for an 

interactive process between students in the mathematics learning process. 

Interaction can be interpreted as communication or a reciprocal relationship between 

two or more people for a specific purpose [7]. Interaction in a lesson is critical and 

necessary to help develop students' understanding and achieve educational goals. Learning 

interaction is an interactive activity of various components to realize the learning objectives 

set when planning to learn [8]. Learning mathematics as the construction and abstraction 

of mathematical concepts can be maximized by solving mathematical problems. The 

problem-solving process will be achieved at a higher level if students work in cooperative 

groups, especially heterogeneously [9]. In other words, the interaction between student’s 

needs to be done without differentiating each student's abilities. 

Based on the learning objectives, students with moderate and low abilities should 

solve problems and be confident and communicate them effectively. A learning strategy is 

needed to accommodate student interactions with the learning environment to achieve this 

goal. One of the learning strategies that support this is a learning strategy that uses 

cooperative groups, or so-called cooperative learning [10]. In this study, the cooperative 

learning process was examined by grouping students based on their understanding and 

mastery of mathematics material. 

According to Murdock-Stewart [11], understanding consists of three general 

categories, which include: (1) understanding structural progress, (2) understanding as a 

form of knowing, (3) understanding as a process. Students are said to understand something 

to connect the ideas in their minds and abstract for the next step [12]. So understanding is 

an organizational process that involves cognitive activities to solve problems. In this study, 

the measurement of students' understanding was carried out through test scores in 

mathematics. Students who have a value above Minimum Learning Completeness are 



M. Ivan Ariful Fathoni, Anisa Fitri, Hanifahtul Husnah 

Student Group Dynamic Model Based on Understanding in Mathematics Subjects 

43 

 

assumed to have understood the material. In contrast, students who have a value below 

Minimum Learning Completeness are supposed to have not understood the material. 

The development of science in the field of mathematics has a role in helping to analyze 

the problems of everyday life. One of these problems is in the field of education. Many 

occurrences in the surroundings can be observed and analyzed in the form of a 

mathematical model. Mathematical models are models that represent a problem in the real 

world into mathematical equations [13]. In this study, we analyzed the dynamics of 

students' level of understanding in mathematics based on time through a modeling 

approach. In this modeling, the mathematical interpretation of the differential equation 

system model in the student population will be known based on the level of mathematical 

understanding. 

Several studies on interactions in the learning process have been carried out several 

times [14]–[16]. In previous research, no one has been able to predict the success of 

learning in the future. In contrast to previous studies, students' interaction in the learning 

process was studied from the mathematical modeling perspective. This approach is an 

alternative method in solving problems in the world of education that have not been widely 

researched. Mathematical modeling can solve a problem by simplifying cases in everyday 

life into a mathematical problem where the solution can be obtained. The mathematical 

model's solution obtained can be used to predict the conditions for the success of the 

learning process. 
 

2. Model Formulation 
 

This study discusses the interaction of students with a mathematical modeling point of 

view. This interaction involves students who understand and do not yet understand the subject 

matter of mathematics. The interaction process between groups is modeled in a two-

dimensional system of differential equations. Variable A is the percentage of students who 

understand the material, and variable B is the percentage of students who do not understand 

the material. The compartment model in Fathoni's research [18] is a reference in this study. 

The basic model in this research is the predator and prey model and the logistic model.  

The relationship between predator and prey is the primary basis of studying ecology. 

One of the important components in this relationship is the speed of predators in preying 

on their prey. The level of prey per capita of predators or the response function is often 

called the basis for the predator-prey theory applied in this study. The group that acts as a 

predator is a group of students who understand mathematics (A). Meanwhile, the group 

that acts as prey is students who do not understand mathematics (B). 

Logistic models are often used to describe the growth rate, including the growth rate 

of the prey population [19]. The prey population does not always increase continuously, 

but it depends on the population's size if there is a limit to the environment's carrying 

capacity. Likewise, the student group does not always experience an increase. The capacity 

of existing classrooms limits the student group. The logistic model in Putranto's research 

[20] is applied in this study, where the increase in students' group follows the growth of 

logistics.  

 



Jurnal Matematika MANTIK 

Vol. 7, No. 1, May 2021, pp. 41-50 
 

44 

 

  

 

 

 

 

Figure 1. The compartment diagram 

 

By the compartment diagram on Figure 1, we construct a mathematical model with 

two-dimensional system of the first order ordinary differential equation (ODE). Our model 
is formulated as the following, see system (1). The parameters used in the model are 

assumed to be positive, with the information in Table 1. Based on the model in equation 

(1), a dynamic analysis process is carried out. The discussion of dynamic analysis 

conducted by Ningsih [21] regarding the growth in the number of students is a reference in 

the discussion of dynamic analysis in this study. The research carried out includes searching 

for the equilibrium points, analyzing the equilibrium points' existence, and analyzing the 

equilibrium points' stability. 

 
𝑑𝐴

𝑑𝑡
=  𝛼𝐴 ( 1 −

𝐴

𝐾
 ) +  𝜇𝐴𝐵 − 𝛾𝐴 

(1) 𝑑𝐵

𝑑𝑡
=  𝛽𝐵 ( 1 −

𝐵

𝐾
 ) −  𝜇𝐴𝐵 − 𝛾𝐵 

 
Table 1.  Parameter description 

Parameter Description Unit 

𝛼 Student group A growth rate. 1/𝑑𝑎𝑦 

𝛽 Student group B growth rate. 1/𝑑𝑎𝑦 

K Carrying capacity of each student group in the class % 

𝜇 Rate of interaction between student group A and student group B 1/% /𝑑𝑎𝑦 

𝛾 Student reduction rate 1/𝑑𝑎𝑦 

 

 
3. Existence of Equilibrium Points 

 

The system (1) has four equilibrium points consisting of one trivial equilibrium point 

and three non-trivial equilibrium points. However, we consider the analysis of the three non-

trivial equilibrium points. The existence of those equilibrium points is presented in Theorem 

1. 

 

Theorem 1. The existences of equilibrium points 𝐸(𝐴, 𝐵) of system (1) 

(i) The equilibrium point 𝐸1 = (0,
𝐾 (−𝛾+𝛽)

𝛽
) exist if 𝛽 > 𝛾 

(ii) The equilibrium point 𝐸2 = (
𝐾(−𝛾+𝛼)

𝛼
, 0) exist if 𝛼 > 𝛾 

𝛽𝐵 𝜇𝐴𝐵 𝛼𝐴 

A B 

𝛼𝐴2

𝐾
 

𝜕𝐴 𝜕𝐵 

𝛽𝐵2

𝐾
 



M. Ivan Ariful Fathoni, Anisa Fitri, Hanifahtul Husnah 

Student Group Dynamic Model Based on Understanding in Mathematics Subjects 

45 

 

(iii) The equilibrium point 𝐸3 = (
𝐾 (−𝜇𝛾𝐾+ 𝜇𝛽𝐾−𝛾𝛽+𝛼𝛽)

𝛽𝛼+ 𝜇2𝐾2
,
𝐾 (𝜇𝛾𝐾− 𝜇𝛼𝐾−𝛾𝛼+𝛼𝛽)

𝛽𝛼+ 𝜇2𝐾2
) exist if 

−𝜇𝛾𝐾 +  𝜇𝛽𝐾 > 𝛾𝛽 − 𝛼𝛽 and 𝜇𝛾𝐾 −  𝜇𝛼𝐾 > 𝛾𝛼 − 𝛼𝛽 
 

4. Stability Analysis 
 

We apply the linearization method to determine the stability of the equilibrium point 

of System (1) and we have the Jacobian matrix as the following, 

𝐽 = [
𝛼 (1 −

𝐴

𝐾
) −

𝛼𝐴

𝐾
+ 𝜇𝐵 − 𝛾 𝜇𝐴

−𝜇𝐵 𝛽 (1 −
𝐵

𝐾
) −

𝛽𝐵

𝐾
− 𝜇𝐴 − 𝛾

] (2) 

Based on the Jacobian matrix (2), the eigenvalues can be obtained from the characteristic 

equation |𝐽 − 𝜆𝐼| = 0 evaluated at 
each point of equilibrium. 

 

4.1 Equilibrium point 𝑬𝟏 
The Jacobian matrix obtained from the linearization of system (1) near the equilibrium 

point 𝐸1 is 

𝐽(𝐸1) =

[
 
 
 
 𝛼 −

𝜇𝐾(𝛾 − 𝛽)

𝛽
− 𝛾 0

𝜇𝐾(𝛾 − 𝛽)

𝛽
𝛽 (1 +

𝛾 − 𝛽

𝛽
) − 𝛽

]
 
 
 
 

 (3) 

The characteristic equation formed from matrix (3) is 

−
(−𝐾𝛽𝜇 + 𝐾𝜇𝛾 − 𝛼𝛽 + 𝛽𝛾 + 𝜆𝛽)(𝛾 − 𝛽 − 𝜆)

𝛽
= 0 

which has the eigenvalues 𝜆1 = 𝛾 − 𝛽 and 𝜆2 =
𝐾𝛽𝜇−𝐾𝜇𝛾+𝛼𝛽−𝛽𝛾

𝛽
. The stability conditions 

for the equilibrium point 𝐸1 are obtained when 𝛾 < 𝛽 and 𝐾𝛽𝜇 − 𝐾𝜇𝛾 < −𝛼𝛽 + 𝛽𝛾. 
 

4.2 Equilibrium point 𝑬𝟐 
The Jacobian matrix obtained from the linearization of system (1) near the equilibrium 

point 𝐸2 is 

𝐽(𝐸2) =

[
 
 
 𝛼 (1 +

−𝛼 + 𝛾

𝛼
) − 𝛼 −

𝜇(−𝛼 + 𝛾)𝐾

𝛼

0 𝛽 +
𝜇(−𝛼 + 𝛾)𝐾

𝛼
− 𝛾

]
 
 
 
 (4) 

The characteristic equation formed from matrix (4) is 
(−𝐾𝛼𝜇 + 𝐾𝜇𝛾 + 𝛼𝛽 − 𝛼𝛾 − 𝜆𝛼)(𝛾 − 𝛼 − 𝜆)

𝛽
= 0 

which has the eigenvalues 𝜆1 = 𝛾 − 𝛼 and 𝜆2 =
−𝐾𝛼𝜇+𝐾𝜇𝛾+𝛼𝛽−𝛼𝛾

𝛼
. The stability conditions 

for the equilibrium point 𝐸2 are obtained when 𝛾 < 𝛼 and −𝐾𝛼𝜇 + 𝐾𝜇𝛾 < −𝛼𝛽 + 𝛼𝛾. 
 

4.3 Equilibrium point 𝑬𝟑 
Linearization of system (1) near the equilibrium 𝐸3 produces the characteristic 

equation as the following 



Jurnal Matematika MANTIK 

Vol. 7, No. 1, May 2021, pp. 41-50 
 

46 

 

1

𝐾2𝜇2 + 𝛼𝛽
(−𝛽(𝐾𝜇 − 𝛽 + 𝛾 − 𝜆)𝛼2

+ ((𝐾𝜇 − 𝛾 + 𝜆)𝛽2 + (−𝐾2𝜇2 + (𝛾 − 𝜆)2)𝛽 + 𝐾𝛾𝜇(𝐾𝜇 + 𝛾 − 𝜆))𝛼

+ 𝐾(𝛾(𝐾𝜇 − 𝛾 + 𝜆)𝛽 − 𝐾𝜇(𝛾 − 𝜆)(𝛾 + 𝜆))𝜇) = 0 
The stability of this equilibrium point was analyzed using the Routh Hurwitz criteria and 

the stability requirements were obtained, 

0 <
−𝐾2𝜇2 − 𝛼𝛽

𝐾2𝜇2 + 𝛼𝛽
 

0 <
−𝛽𝛼2 + (𝐾𝛾𝜇 − 𝛽2 + 2𝛾𝛽)𝛼 − 𝐾𝛽𝛾𝜇

𝐾2𝜇2 + 𝛼𝛽
 

0 <
((𝐾𝜇 − 𝛽 + 𝛾)𝛼 − 𝐾𝜇𝛾)(𝛼𝛽 + (𝐾𝜇 − 𝛾)𝛽 − 𝐾𝜇𝛾)

𝐾2𝜇2 + 𝛼𝛽
 

or 

0 >
−𝐾2𝜇2 − 𝛼𝛽

𝐾2𝜇2 + 𝛼𝛽
 

0 >
−𝛽𝛼2 + (𝐾𝛾𝜇 − 𝛽2 + 2𝛾𝛽)𝛼 − 𝐾𝛽𝛾𝜇

𝐾2𝜇2 + 𝛼𝛽
 

0 >
((𝐾𝜇 − 𝛽 + 𝛾)𝛼 − 𝐾𝜇𝛾)(𝛼𝛽 + (𝐾𝜇 − 𝛾)𝛽 − 𝐾𝜇𝛾)

𝐾2𝜇2 + 𝛼𝛽
 

 

5. Numerical Simulations 
 

The simulation in this study uses assumption data from a condition at school. 

However, the research subject of real data in a school is still an open problem in this study. 

Simulations are carried out based on the assumption of the percentage of the number of 

students in each group in one class to the total number of students in one education level. 

The percentage of students who understand mathematics subject matter (Group A) was 

20%, while students who did not understand mathematics subject matter (Group B) were 

15%. These numbers are assumed to be the initial condition after a teacher conducted a 

math ability test. Furthermore, through the cooperative learning process, where learning is 

carried out that focuses on the interaction between students, it is expected to increase 

students who understand the material. 

In the first case, a simulation based on the system's differential equation model (1) is 

carried out by using the assumed parameter values 𝛼 = 0.6, 𝛽 = 0.7, 𝐾 = 0.4, 𝜇 =
0.01, 𝛾 = 0.2. This case shows a very low interaction process between students, 
characterized by a very small interaction rate (𝜇). Assuming such a parameter value, the 
only stable equilibrium point is 𝐸3. The simulation results are obtained in Figure 2. The 
number of students who understood the material increased from 0.20 to 0.269. The same 

thing happened to students who did not understand, which increased from 0.15 to 0.284. 

The simulation results show that there are still many students who do not understand. It is 

certainly not a goal in the success of the learning process. 

 



M. Ivan Ariful Fathoni, Anisa Fitri, Hanifahtul Husnah 

Student Group Dynamic Model Based on Understanding in Mathematics Subjects 

47 

 

 
Figure 2. The dynamic of changes in the student’s number in each group (case 1) 

 

In the second case, the simulation is carried out based on the assumed parameter values 

𝛼 = 0.6, 𝛽 = 0.7, 𝐾 = 0.4, 𝜇 = 1.9, 𝛾 = 0.02. There is a significant increase in the 
interaction rate from the first case. In this second case, students' movement out of class is 

also increasingly limited by reducing the student reduction rate (𝛾). Assuming such a 
parameter value, the only stable equilibrium point is 𝐸2. The equilibrium point 𝐸3 becomes 
not exist. The simulation results are obtained in Figure 3.  The number of students in group 

A increased from 0.2 to 0.387. The opposite happened in group B, which continued to 

decrease from 0.15 until no more students did not understand mathematics subject matter. 

In the second case, the learning process's objective has been achieved but can still be 

improved. 

 

 
Figure 3. The dynamic of changes in the student’s number in each group (case 2) 

 

In the third case, the simulation is carried out based on the assumed parameter values 

𝛼 = 0.9, 𝛽 = 0.4, 𝐾 = 0.4, 𝜇 = 1.9, 𝛾 = 0.02. We increase the student group A growth 
rate (𝛼) and decrease the student group B growth rate (𝛽). The simulation results are 
obtained in Figure 4. Under these conditions, the stability of the equilibrium point is the 

same as in the second case. However, there was an addition of students who understood 

(group A) to 0.391, while group B students continued to decrease to zero. Another 

difference is that the time the solution moves to equilibrium is faster than the second case. 

In the third case, equilibrium occurs at 16 days. The goal of successful learning happens 

more quickly. 



Jurnal Matematika MANTIK 

Vol. 7, No. 1, May 2021, pp. 41-50 
 

48 

 

 

 
Figure 4. The dynamic of changes in the student’s number in each group (case 3) 

 

The simulation results are shown in Figures 1, 2, and 3 explain the process of changing the 

conditions of students' level of understanding in real-time. Based on this model, predictions can be 

made when learning success can be achieved, so that teachers can apply appropriate learning 

methods before starting the learning process. The implication of this study's results can help teachers 

make teaching more effective and directed under learning outcomes.  

 

6. Concluding Remarks 
 

Mathematical modeling can solve a problem by simplifying cases in everyday life into 

a mathematical problem where the solution can be obtained. This study departs from the 

background above issues, namely, students' interaction in the mathematics class. This 

interaction involves two groups of students who understand and do not understand the 

subject matter of mathematics. The two groups will interact with each other, creating a 

positive atmosphere in the learning process. The interaction process between groups is 

modeled in a system of differential equations. The solution of the system of differential 

equations is expected to reflect the teaching and learning process's success. 

The results of the dynamical analysis obtained are strengthened by numerical 

simulation evidence that supports the analysis. In numerical simulations, it can be 

concluded that by doing learning that focuses on the interaction between students and limits 

students' movement out of the classroom, the learning process can run successfully. All 

students in the class will understand the learning material. Better results are obtained if the 

teacher adds more students who understand and reduces the more students who do not 

understand each group. To increase and decrease can be done by moving students from or 

to another class. Approaching and teaching specifically for some students who do not 

understand can also be done not to be included in the observation group. It will help 

accelerate the success of the learning process. The findings in this study can be used as a 

new research field in the world of education. 

 

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