Pedoman Untuk Penulis


P-ISSN 2527-5615 
E-ISSN 2527-5607 
 

Kalamatika: Jurnal Pendidikan Matematika 

Volume 6, No. 1, April 2021, pages 57-70 

                                                                             

 This work is licensed under a Creative 
Commons Attribution - ShareAlike 4.0 International 

License.  

57 

THE POSITION OF STUDENTS’ ERRORS IN ALGEBRAIC PROBLEM-
SOLVING BASED ON FIELD DEPENDENT AND INDEPENDENT 

Aloisius Loka Son1, Darhim2, Siti Fatimah3  

1Universitas Timor, Jln. KM.9, Kefamenanu, Indonesia.  
aloisiuslokason@unimor.ac.id 

2 Universitas Pendidikan Indonesia, Jl. Dr. Setiabudi No.229, Bandung, Indonesia. 
darhim0355@gmail.com 

3 Universitas Pendidikan Indonesia, Jl. Dr. Setiabudi No.229, Bandung, Indonesia. 
sitifatimah@upi.edu 

ABSTRACT 

There is a  strong rela tionship between field-dependent (FD), field-independent (FI) cognitive styles, a nd 

problem -solving performa nce. FD students a re more oriented towa rds the outside world, while FI students rely 

more on their knowledge a nd experience. The present study a imed to revea l the position of the FI a nd FD 

student's errors in a lgebra ic problem -solving. The subjects of this study were 27 students of cla ss VII in one of 

the Junior High Schools in Kefa mena nu, Indonesia , Aca demic Yea r 2018/2019 . Da ta  collection involved tests 

of a lgebra ic problem -solving a bility, interviews, a nd Group Embedded Figure Test. The ca se study results 

showed tha t the a lgebra ic problem-solving a bilities of FI students were better tha n FD students. The scores of 

a lgebra ic problem -solving a bilities of FI students were domina nt in the medium a nd high ca tegories. In 

contra st, the FD students were domina nt in the medium a nd low ca tegories. Also, FI students predomina ntly 

committed procedura l errors. Wherea s, most FD students ma de errors on a ll types of errors, specifica lly fa ctua l, 

conceptua l, a nd procedura l errors. Thus, it is recommended tha t FI a nd FD students' a lgebra ic problem -solving 

a bility become the focus of a ttention a nd importa nce to cha ra cterize them a s a  ba sis for further resea rch . 

ARTICLE INFORMATION 

Keywords  Article History 

Algebra ic problem -solving 

Position of error 

Field-dependent  

Field-independent 
 

Submitted Nov 26, 2020 

Revised Mar 10, 2021 

Accepted Mar 22, 2021 

Corresponding Author 

Aloisius Loka  Son 

Universita s Timor 

Jl. El Ta ri - KM. 09, Kefa mena nu, Indonesia  

Ema il: a loisiusloka son@unimor.a c.id 

How to Cite 

Son, A. L., Da rhim, & Fa tima h, S. (2021). The Position of Students’ Errors in Algebra ic Problem -Solving 

Ba sed on Field Dependent a nd Independent . Kalamatika: Jurnal Pendidikan Matematika , 6(1), 57-70. 

https://doi.org/10.22236/KALAMATIKA.vol6no1.2021pp57-70 

http://creativecommons.org/licenses/by-sa/4.0/
http://creativecommons.org/licenses/by-sa/4.0/
http://creativecommons.org/licenses/by-sa/4.0/


58 KALAMATIKA, Volume 6, No. 1, April 2021, pages 57-70 

INTRODUCTION 

Recently, the need to understand and be able to use mathematics in everyday life will 

continue to increase as a part of cultural heritage, the workplace, the scientific and technical 

community (NCTM, 2000). Therefore, mathematics becomes one of the compulsory subjects 

in formal schools, ranging from elementary school to college. However, in reality, 

mathematics is still considered a scary subject, which has an impact on the low achievement of 

Indonesian students’ mathematical abilities. As reported by Trends in International 

Mathematics and Science Study (TIMSS), in 2015, Indonesian students ranked 45th out of 50 

participating countries (IEA, 2016). Other international institutes that assess student s' 

mathematical abilities are the Program for International Student Assessment (PISA), which 

reported that, in 2018, Indonesian students ranked 72th out of 78 participating countries 

(OECD, 2019). Besides the TIMMS and PISA results, the Indonesia Ministry of Education 

and Culture's central report on the national examination results showed that the national 

average math score in 2018 is 43.34 (Puspendik, 2018). 

One of the specific branches of mathematics as a domain of assessments carried out by 

TIMMS, PISA, and national examinations is Algebra. This shows the importance of Algebra 

in mathematical calculations and as a basis for solving mathematical problems. Almost all 

fields of mathematics require algebra as a problem-solving tool (Agoestanto, et al., 2019). 

Algebra is the beginning of a journey that provides skills to solve more complex problems. 

Knowledge of algebraic concepts and skills is a prerequisite for students to develop higher-

order thinking and problem-solving skills in real-life situations (Ganesen, et al., 2020). 

Algebra is a branch of mathematics. The reports on the results of TIMSS, PISA, and 

national exams showed that the mathematics achievement and the algebraic ability of 

Indonesian students were poor and still far from expected. One of the evidence is the results of  

a national exam at a state junior high school in the city of Kefamenanu. In 2018, the average 

algebraic material mastery of students at the school was 31.28. It was even lower than 2017, 

which amounted to 43.48. While nationally, the average mastery of students' algebraic 

material was 41.88, lower than in 2017, which was 46.60 (Puspendik, 2017., 2018). If this 

problem is not resolved, it will prevent students from learning algebraic material in the next 

stages. 

Results description of the TIMSS, PISA, and national exam showed that the algebraic 



Son, Darhim, & Fatimah     59 
 

ability in particular and the mathematical abilities in general of Indonesian students at the 

international and national levels were not as expected. Indonesian students did not have the 

readiness to face challenges in real life because the assessment conducted by TIMSS makes 

students think of the importance of success in school and success in future careers (Mullis, et 

al., 2004). Whereas the assessment carried out by PISA aims to measure the readiness of the 

younger generation to meet real challenges of contemporary life (Anderson, et al., 2009). 

Based on the issues above, in learning mathematics at schools, students are required to 

habituate themselves in solving problems. Problem-solving should be a core objective of 

teaching mathematics in schools (García, et al., 2019) because by this way then the students 

can learn to apply their math skills in new ways, they will develop a deeper understanding of 

mathematical ideas, and experience being a mathematician (Badger, et al., 2012). The process 

of solving a problem requires the application of a solution strategy, which can direct the 

problem solver to explore many ideas in obtaining solutions to a problem. One of the popular 

problem-solving processes is the methods according to Polya (1957), consisting of 

understanding the problem, devising a plan, carrying out the plan, and looking back. 

Problem-solving abilities are skills that students must master. Their errors become 

obstacles in developing their thinking to solve math problems. Therefore, it is necessary to 

analyze the position of students' mathematical problem-solving errors to minimize them from 

being repeated (Agoestanto, et al., 2019). This information is used to identify at which point in 

the problem-solving task students experience difficulty or frustration (Brown & Skow, 2016). 

Furthermore, they said that the types of errors that students often make in solving math 

problems are factual errors, conceptual errors, and procedural errors. Factual errors are errors 

due to the lack of factual information. Procedural errors are errors due to incorrect 

performance of steps in a mathematical process. Whereas conceptual errors are errors due to 

misconception or a faulty understanding of the underlying principles and ideas connected to 

the mathematical problems. 

Students' problem-solving ability in mathematics can be seen from several dimensions, 

one of them is a cognitive style (Ulya & Retnoningsih, 2014). Most of the research show ed 

that students with different cognitive styles have ways of different processing information and  

problem-solving (Witkin & Goodenough, 1981). Researchers around the world are very 

interested in studying the relationship between dimensions of cognitive style with 



60 KALAMATIKA, Volume 6, No. 1, April 2021, pages 57-70 

mathematical abilities (Chrysostomou, et al., 2011). 

The cognitive style emphasizes a person's characteristics in respond, processing, 

storing, thinking, and using the information to question multiple tasks (Carraher, 2017).  The 

most popular cognitive styles are the field-independent (FI) and field-dependent (FD) 

cognitive styles (Mefoh, Nwoke, & Chijioke, 2017). FI and FD cognitive styles are 

characterized by common ways of thinking, solving problems, learning, and relating to other 

people (Abrams & Belgrave, 2013). Pithers (2006) stated that there is a strong relationship 

between FI-FD cognitive style and problem-solving performance. Based on these reasons, 

then this study was conducted to reveal the position of the FI and FD student's errors in 

algebraic problem-solving. 

METHOD 

The research used a qualitative research method with a case study approach, 

particularly collective case studies. The studies will reveal deviations from the reasonableness 

of a phenomenon, population, or general condition (Creswel, 2012). The subjects of this study 

were  27 Year 7 students from one of the Junior High Schools in Kefamenanu City-Indonesia, 

Academic Year 2018/2019. They consisted of 12 male and 15 female students, who were 

taught by the same mathematics teacher, and had the same average age. 

The data collection sources were tests of algebraic problem-solving ability, interviews, 

and Group Embedded Figure Test (GEFT). Algebraic problem-solving ability tests and 

interviews were conducted to reveal the position of students' errors in solving algebraic 

problems. The test consisted of 4 questions in the form of essays. The assessment guidelines 

referred to indicators of problem-solving ability based on Polya’s principles. While the 

interviews were semi-structured by questioning what, why, and how students' errors. GEFT 

was developed by Witkin in 1971 and used to classify types of cognitive styles based on 

psychological differences, namely the FI and FD cognitive styles. GEFT consist ed of three 

parts that part I consisted of seven questions, part II and part III each consisted of nine 

questions. Part I was an exercise, while the scores were calculated from part II and part III. 

 The data analysis technique used was the triangulation technique. The qualitative study 

relied on the triangulation of the resulting data (Chariri, 2009). Triangulation is the process of 

corroborating evidence from different types of data (Creswell, 2012). Strengthening the 

evidence in this study intended to check the accuracy of the results and interpret dat a to the 



Son, Darhim, & Fatimah     61 
 

same source with different techniques through the analysis of student work and interviews. 

Triangulation activities were carried out through the stages of data reduction, data display, and  

conclusions. 

RESULT AND DISCUSSION 

The results test of the 27 students obtained 10 FI students and 17 FD students of the 

cognitive style. While the test results of students' algebraic problem-solving ability, the 

obtained average was 17.63, the standard deviation was 6.76, the maximum score was 28, and 

the minimum score was 8 from an ideal maximum standard of 36. Based on this average and 

standard deviation, student scores were grouped into high, medium, and low categories. The 

nine students scored in the high category, 13 in the medium category, and five in the low 

category. The percentage of the high and medium scores of FI students were 30% and 7%, 

respectively and  no FI students scored in the low category. Whereas for FD students, 4% of 

students scored in the high category, 41% of the medium category, and 18% of the low 

category. 

The results of students’ work were then analyzed qualitatively to examine the errors 

made by students. Types of student errors were categorized as factual errors, conceptual 

errors, and procedural errors. Based on these types of errors, it can be described and given the 

coding of the errors made by students. Factual errors consisted of the students who were not 

able to describe the elements that are known in the algebraic problem (F1), students that were 

not able to identify the instructions that exist in the algebraic problem (name and meaning of 

symbols, and properties) (F2), and who did not understand the algebraic problem asked (F3). 

Conceptual errors consisted of students who could not determine the formula for solving 

algebraic problems (C1) and students who were not able to use the formula to solve the 

algebraic problem correctly (C2). While procedure errors consisted of the students who were 

not able to do mathematical operations (P1), and who were not able to solve algebraic 

problems systematically (technically) (P2). 

All of the test results of students' algebraic problem-solving ability can be analyzed 

based on the type of error with coding above. Recapitulation of student errors in solve 

algebraic problem-solving tests is described in Table 1.  

Table 1. Percentage of students who make algebraic problem-solving errors 

QN CS 
Students’ errors type (%) 

F1 F2 F3 C1 C2 P1 P2 



62 KALAMATIKA, Volume 6, No. 1, April 2021, pages 57-70 

1 
FI 3.70 3.70 0.00 3.70 7.41 14.81 22.22 

FD 22.22 25.93 11.11 29.63 25.93 51.85 55.56 

2 
FI 3.70 0.00 3.70 7.41 7.41 14.81 22.22 

FD 33.33 33.33 33.33 33.33 40,74 55.56 62.96 

3 
FI 0.00 3.70 0.00 3.70 7.41 11.11 11.11 
FD 0.00 25.93 0.00 33.33 40.74 55.56 62.96 

4 
FI 0.00 0.00 0.00 3.70 3.70 0.00 11.11 

FD 37.04 37.04 37.04 40.74 55.56 55.56 59.26 

AP 
FI 1.85 1.85 0.93 4.63 6.48 10.18 16.67 
FD 23.15 30.56 20.37 34.26 42.59 53.71 57.41 

QN: Question Number, CS: Cognitive Style, AP: Avera ge of Percenta ge  

The table 1 above showed the average percentage of students who made algebraic 

problem-solving errors, FI students who made F1 errors were 1.85%, while the FD students were 

23.15%. The average percentage of FI students who made F2 errors was 1.85%, whereas the 

FD students were 30.56%. FI students who made F3 errors, the average percentage were 

0.93%, the FD students were 20.37%. FI students who made C1 errors were 4.63%, while the 

FD students were 34.26%. Next, FI students who made C2 errors were 6.48%, and the FD 

students were 42.59%. The average percentage of FI students who made P1 error was 10.18%, 

while the FD students were 53.71%, and the average percentage of FI students who made P2 

error was 16.67%, while the FD students were 57.41%. This descriptive statistic revealed that 

FD students made more errors in algebraic problem-solving than FI students. The type of 

errors that FI students often made was procedural errors, while FD students tend ed to make all 

the errors from factual errors to procedural errors. 

Based on the descriptive statistics in Table 1, the researchers conducted interviews 

with four students to confirm the suitability of their answers. The four students consist of two 

from both FI and FD students. Determining them according to the basic errors made by 

students. In this study, the researchers only displayed one work of FI and FD students on item 

number 1. The following is problem 1. 

Look at the following plane figure! 

 

 

 

 

 

Find the area of the plane figure above! 

 

 

 

 



Son, Darhim, & Fatimah     63 
 

The answers of FI and FD students on item number 1 are presented in Figure 1.  

 

 

 

 

 

 

 

 

Figure 1 shows that FI student did not describe the elements that are known in 

algebraic problem and asked in questions (F1 and F3 errors), but the student has been able to 

divide it separately into several parts and grouped them into several groups of squares with the 

length of x side, and  groups of squares with the length of side y. In the next step, the FI 

student devised the formula to determine each square's area and the total area of the figure. 

While FD student could not describe the elements that are known and asked (F1 and  F 3  

errors). In the plane figure given, the FD student divided it separately into several parts, and 

grouped them in rectangle groups with length and width are same i.e., x (the plane was a 

rectangle), and groups of rectangles with length and width are same i.e., y (The shapes were 

rectangle). Though FD student made errors F1, F2, and F3, but in the following steps, FD 

student devised the plan by writing the formula to determine the area of each rectangle which 

was s x s, and determined the rectangle area (big plane) i.e., x2, but it was wrong in figuring 

the area of four rectangles (small plane). It is affected the miscalculation of the overall plane 

area, even the plane area (big) i.e., x2 was written in the form of x. The plane area obtained by 

FD students was 4x + 4y. 

Based on FI and FD students' answers in Figures 1, the researcher continued with an 

interview to confirm the students’ answers. In this article, the author only displayed the results 

of interviews with one of FI and FD student on item question number 1. The results of 

interviews with FI students are presented in Table 2. 

Table 2. Excerpts of the results of interviews with FI student 
Resea rcher FI student 

Look at question number 1! From this problem, try to 
explain the elements that are known and asked! 

This is what is known, sir (pointing to the figure of the airplane in question). 
This problem asks the plane's irregular area, sir. 

What do you have to do to determine the area of the 

plane? 

This plane figure must be divided (separated) into several parts, calculated the 

area of each part, and then added up to get answers to the questions. 

Figure 1. Students' answers on the question to number 1 

recta ngle

e 

 

FD student FI student 



64 KALAMATIKA, Volume 6, No. 1, April 2021, pages 57-70 

Why does it have to be divided (separated)? Yes, because the plane figure is known are an irregular plane. There is no 
specific plane area formula that can be used. 

You can try to cut (separate) the plane! What formula can 
you use to calculate the area of each part? 

(The Student drew the plane figure separately, there were a square with side x, 
and 4 squares with side y), then explained that the square area formula with side 

x is , and the square area formula with side y was . 

Try to calculate the area of each plane! (student write and explain) 
         

                    

Why is the L2 formula multiplied by 4? Because the number of squares with side y is 4 squares, sir. 

Try to write the area of the plane figure asked in the 
problem! 

The area of the plane figure is:  unit of area 

 

The interview results in Table 2 show that FI student was able to describe the elements known 

and asked, identify the plane by separating it into several parts precisely, determine the 

formula to calculate the area of each square, and then use the formula of the square area in the 

solving process. The student accomplished the mathematical operations and solved algebraic 

problems systematically. The explanations from FI student were the same as the answer that is 

written on the paper. The answer to the following question matched the solution step when the 

written test. This showed that the FI student did not make an error in the problem-solving 

question of number 1. 

The excerpts of the interview results with FD student will be presented in Table 3. The 

results showed that FD student understood the elements that were asked in the question but 

was not able to describe it. As a result of not describing known elements, the FD student drew 

each part of the plane figures separately and drawn it as a rectangle. In the next step, the FD 

student determined the formula used to calculate the area of each square but was unable to 

apply the formula in the calculation process (C2 error). The effect of this C2 error, so FD 

student continued to make errors at P1 and P2, was unable to systematically accomplish the 

mathematical operations and systematically solve the problems. 

Table 3.  Excerpts of the results of interviews with FD student 
Resea rcher FD student 

Look at question number 1! From this problem, try to explain 
the elements that are known and asked! 

What the known is a picture (pointing to the plane figure in the problem). 
From this picture, what should be calculated is the area, sir. 

What do you have to do to determine the area of the plane? Divide (separated) sir. (students then draw it separately into several parts, 

but all parts are drawn in the rectangular form) 
Why does it have to be divided (separated)? So that we can calculate the area of each of these planes, sir. 
What formula should be used to calculate the area of each of 
these planes? 

Side x side, sir. 

Why is the formula side x side? (The student was silent), then directed by researchers that the picture is a 
square, not a rectangle. 

Try to calculate the area of each plane!           

                          

   
Try to explain why the area   is 2x, and  is 4y? This 2x is a large plane area, and 4y is a small plane area, sir. 

Try to determine the results of , and ! I do not know, sir. 

Look at this! If , then  Student answer:  

Try to write the area of the plane figure asked in the problem!  Student writes:  
 



Son, Darhim, & Fatimah     65 
 

In general, this study showed that FI students made fewer errors in solving algebraic 

problems than FD students. In line with the research results by Agoestanto, et al. (2019), 

students with the FI cognitive style had fewer errors in working on algebraic thinking skills 

than students with the FD cognitive style. The average of the algebraic problem-solving ability 

of FI students in the category was good, namely being able to describe the elements known, to 

identify the instructions that exist in algebraic problem, to understand the asked elements, to 

determine and to use the formula of solving the algebraic problems correctly, to do 

mathematical operations, and being able to solve the problems systematically, even though 

sometimes they did procedural errors. Consistent with the research results that FI students can 

fulfill all of the indicators problem-solving, although sometimes made an error in some 

indicators (Ulya & Retnoningsih, 2014., Anthycamurty et al., 2018). 

The algebraic problem-solving ability of FD students was still low because almost all 

FD students made all types of errors; specifically they were not able to describe the elements 

that are known, to identify the instructions that exist in the algebraic problem-solving question 

(name, the meaning of symbols, and properties), did not understand the asked elements, not 

able to determine and to use the formula in solving the algebraic problem correctly, not able to 

do mathematical operations and solve the algebraic problems systematically. Mostly, FD 

students' abilities were low, although occasionally, some FD students did not make errors for 

certain types of errors. 

The measurement of algebraic problem-solving ability in this study used Polya’s 

indicators, and FD students could not solve mathematics problems according to these 

indicators. This result line with the research done by Ulya & Retnoningsih (2014) and 

Anthycamurty et al. (2018); they said that FD students have not met almost all indicators of 

problem-solving based on Polya's indicators. They were not clear enough in making a device a 

plan and cannot accomplish the problem in all Polya steps (Hartanto & Mariani, 2019). 

The difference in algebraic problem-solving ability between FI and FD students 

occurred because FI and FD students' characteristics were inclined to be different. Students 

with FD cognitive style found difficulties in processing information and experienced 

struggling when information need to be manipulated in a different context. FD students' 

perceptions were weak when the context changed. Meanwhile, FI students tend ed to use 

internal factors as directions in processing information. FD students were more accepting the 



66 KALAMATIKA, Volume 6, No. 1, April 2021, pages 57-70 

existing structure due to lack of restructuring; they tend ed to follow existing goals and work 

with external motivation. They were more interested in external reinforcement such as praise, 

gifts, or external motivation from others. In the meantime, FI students were generally more 

independent, competitive, and confident in their abilities (Karaçam & Baran, 2015; Witkin, et 

al., 1977). They relied on their knowledge and experience, while FD students were more 

oriented to the outside world (external motivation) when solving problems (Volkova & 

Rusalov, 2016). 

In the process of learning mathematics in schools, one thing that must get attention is 

the difference in the tendencies of FI and FD students, especially FD students who have the 

problem-solving ability that tends to be lower than FI students. Mathematics teachers need to 

consider the learning models, strategies, approaches, and methods used in the learning process 

in facilitating the mathematical problem-solving ability of FD students. Furthermore, the 

important thing that needs to be examined in learning mathematics is to provide FD students 

opportunities to discuss more with their classmates. This will allow an increase in their 

problem-solving ability because it is supported by their characteristics, who are more likely to 

socialize and get together with the people around them (Karaçam & Baran, 2015., Volkova & 

Rusalov, 2016). These characteristics allow their problem-solving abilities to develop by 

providing opportunities for them to learn together. 

CONCLUSION 

Based on the research results and discussion above, it can be concluded that the 

algebraic problem-solving ability of FI students was better than FD students. This is seen 

based on the score of algebraic problem-solving ability of the FI students were dominant in the 

medium and high categories, while the scores of the algebraic problem-solving ability of the 

FD students were dominant in the medium and low categories. FI students were able to 

describe the elements that are known, identify the instructions that exist in algebraic problem-

solving question, understood the problem being asked, be able to determine and use the 

formula for algebraic solving-problems correctly, being able to accomplish mathematical 

operations and solve algebraic problems systematically. However, sometimes FI students 

made some procedural errors. Most FD students made errors on all types of errors, such as not 

being able to describe the known elements, identify the instructions in the algebraic problem 

(name and meaning of symbols, and properties), understand the problem asked, determine the 



Son, Darhim, & Fatimah     67 
 

formula and use it in solving algebraic problem correctly, do mathematical operations and 

solve algebraic problems systematically (technical). However, some FD students did not make 

these certain types of errors.  

Therefore, it is recommended to consider using learning models, strategies, 

approaches, and methods to facilitate the algebraic problem-solving ability of FI and FD 

students, especially FD students who have lower algebraic problem-solving ability than FI 

students. The teachers can minimize the differences in mathematical abilities between these 

two cognitive style groups. Besides, it is suggested that FI and FD students' algebraic 

problem-solving ability becomes the focus of attention. It is important to be characterized as a 

basis for further research. 

REFERENCES 

Abrams, J., & Belgrave, F. Z. (2013). Field Dependence. The Encyclopedia of Cross-Cultural 

Psychology, II(1), 1–3. https://doi.org/10.1002/9781 11833 9893.wbeccp221. 

Agoestanto, A., Sukestiyarno, Y. L., Isnarto, Rochmad, & Lestari, M. D. (2019). The Position 

and Causes of Students Errors in Algebraic Thinking Based on Cognitive Style. 

International Journal of Instruction, 12 (1), 1431-1444. 

Anderson, J, Milford, T., & Ross, S. P. (2009). Multilevel Modeling with HLM: Taking a 

Second Look at PISA. Quality Research in Literacy and Science Education: 

International Perspectives and Gold Standards, 263–286. 

Anthycamurty, C. C., Mardiyana, & Saputro, D. R. S. (2018). Analysis of Problem Solving in 

Terms of Cognitive Style. International Conference on Mathematics, Science and 

Education, 83, 1–5. https://doi.org/10.1088/1742-6596/983/1/012146. 

Badger, M., Sangwin, C. J., Hawkes, T. O., Burn, R. P., Mason, J., & Pope, S. (2012). 

Teaching Problem-Solving in Undergraduate Mathematics. Coventry, UK: Coventry 

University. 

Brown, J., & Skow, K. (2016). Mathematics: Identifying and Addressing Student Errors. In 

The Iris Center. United States of America: The Iris Center. 

Carraher, E., Smith, R. E., & De Lisle, P. (2017). Cognitive Styles. In E. Carracer & P. De 

https://doi.org/10.1088/1742-6596/983/1/012146


68 KALAMATIKA, Volume 6, No. 1, April 2021, pages 57-70 

Lisle (Editors), Leading Collaborative Architectural Practice (pp. 179–195). New 

Jersey: Jhon Wiley & Sons. 

Chariri, A. (2009). Landasan Filsafat dan Metode Penelitian Kualitatif. Semarang: 

Universitas Diponegoro. 

Chrysostomou, M., Tsingi, C., Cleanthous, E., & Pitta-Pantazi, D. (2011). Cognitive Styles 

and Their Relation to Number Sense and Algebraic Reasoning. Proceedings of the 

Seventh Congress of the European Society for Research in Mathematics Education, 

387–396. 

Creswell, J. W. (2012). Educational Research, Planning, Conducting and Evaluating 

Quantitative and Qualitative Research. USA: Pearson. 

Ganesen, P., Osman, S., Abu, M. S., & Kumar, J. A. (2020). The Relationship Between 

Learning Styles and Achievement of Solving Algebraic Problems Among Lower 

Secondary School Students. International Journal of Advanced Science and 

Technology, 29 (95), 2563-2574. 

García, T., Boom, J., Kroesbergen, E. H., Nunez, J. C., & Rodriguez, C. (2019). Planning, 

Execution, and Revision in Mathematics Problem Solving: Does the Order of the 

Phases Matter? Studies in Educational Evaluation Journal, 83–93. 

https://doi.org/10.1016/j.stueduc.2019.03.001. 

Hartanto, F. D., & Mariani, S. (2019). An Analysis of Mathematical Problem Solving Ability 

in Terms of Students’ Cognitive Style in Learning PBL Includes Ethnomat hematics. 

Unnes Journal of Mathematics Education Research, 8(1), 65–71. 

IEA. (2016). The TIMSS 2015 International Results in Mathematics. Retrieved from 

https://www.iea.nl/studies/iea/timss/2015/results. 

Karaçam, S., & Baran, A. D. (2015). The Effects of Field Dependent/Field Independent 

Cognitive Styles and Motivational Styles on Students’ Conceptual Understanding 

About Direct Current Circuits. Asia-Pacific Forum on Science Learning and Teaching, 

16(2), 1–19. 

Mefoh, P. C., Nwoke, M. B., & Chijioke, J. B. C. C. A. O. (2017). Effect of Cognitive Style 

https://doi.org/10.1016/j.stueduc.2019.03.001
https://www.iea.nl/studies/iea/timss/2015/results


Son, Darhim, & Fatimah     69 
 

and Gender on Adolescents’ Problem Solving Ability. Journal of Thinking Skills and 

Creativity, 25, 47–52. https://doi.org/10.1016/j.tsc. 2017.03.002. 

Mullis, I. V. S., Martin, M. O., Gonzalez, E. J., & Chrostowski, S. J. (2004). TIMSS 2003 

International Mathematics Report. In IEA. Retrieved from 

https://timss.bc.edu/timss2003i/mathD.html. 

NCTM. (2000). Principles and Standards for School Mathematics. United States of America: 

NCTM. 

OECD. (2019). PISA 2018 Results: What Students Know and Can Do. New York: OECD 

Publishing. 

Pithers, R. T. (2006). Cognitive Learning Style: A Review of the Field Dependent -Field 

Independent Approach. Journal of Vocational Education and Training, 54(1), 117–

132. https://doi.org/10.1080/13636820200 200191. 

Polya, G. (1957). How To Solve It: A New Aspect of Mathematical Method. 

https://doi.org/10.2307/j.ctvc773pk. 

Puspendik. (2017). Capaian Nilai Ujian Nasional Matematika SMP Tahun Ajaran 2016/2017. 

Retrieved from https://hasilun.puspendik.kemdikbud.go.id/. 

Puspendik. (2018). Capaian Nilai Ujian Nasional Matematika SMP Tahun Ajaran 2017/2018. 

Retrieved from https://hasilun.puspendik.kemdikbud.go.id/. 

Ulya, H., & Retnoningsih, A. (2014). Analysis of Mathematics Problem Solving Ability of 

Junior High School Students Viewed From Students’ Cognitive Style. International 

Journal of Education and Research, 2(10), 577–582. 

Volkova, E. V., & Rusalov, V. M. (2016). Cognitive Styles and Personality. Personality and 

Individual Differences, 99, 266–271. https://doi.org/10.1016/j.paid.2016.04.097.  

Witkin, H. A., & Goodenough, D. R. (1981). Cognitive Styles: Essence and Origins. Field 

Dependence and Field Independence. In Psychological issues. 

Witkin, H. A., Moore, C. A., Goodenough, D. R., & Cox, P. W. (1977). Field -Dependent and 

Field-Independent Cognitive Styles and Their Educational Implications. ETS Research 

https://doi.org/10.1016/j.tsc.%202017.03.002
https://timss.bc.edu/timss2003i/mathD.html
https://doi.org/10.2307/j.ctvc773pk
https://doi.org/10.1016/j.paid.2016.04.097


70 KALAMATIKA, Volume 6, No. 1, April 2021, pages 57-70 

Bulletin Series, 47(1), 1–64.