P-ISSN 2527-5615 
E-ISSN 2527-5607 
 
Kalamatika: Jurnal Pendidikan Matematika 

Volume 6, No. 1, April 2021, pages 31-44 

                                                                             

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31 

THE NEWMAN PROCEDURE FOR ANALYZING STUDENTS’ ERRORS IN 

SOLVING SYSTEMS OF LINEAR EQUATIONS 

Veni Saputri1, Rizal Kamsurya2 

1STKIP Media Nusantara Citra, Jl. Raya Panjang, Jakarta Barat, Indonesia.  
veni.saputri@stkipmnc.ac.id 

2STKIP Media Nusantara Citra, Jl. Raya Panjang, Jakarta Barat, Indonesia . 
rizal_kamsurya@stkipmnc.ac.id 

ABSTRACT 

This study a im ed to a na lyze students’ errors in problem -solving a ctivities for systems of linea r equa tions. The 

descriptive qua lita tive method wa s a dopted a nd a pplied to obta in a nd process the resea rch da ta . Furthermore, 

resea rch subjects were selected using the purposive sa mpling technique. Three pa rticipa nts were chosen 

a ccording to their ma thematica l proficiency levels. Da ta  collection wa s conducted by tests to mea sure students ’ 

problem -solving a bilities a nd semi-structura l interviews to ga ther qua lita tive informa tion a bout students’ errors 

in solving systems of linea r equa tions. The interview results were a na lyzed using na rra tive a na lysis to obta in 

a ccura te conclusions a bout students' errors. Furthermore, the study found tha t (1) low-a bility students tend to 

perform  error a t the comprehension sta ge, (2) medium -a bility students a re likely to perform error a t the 

tra nsforma tion sta ge, a nd (3) high-a bility students tend to perform error a t the process skills sta ge. The 

solutions ba sed on the a bility level a re: (1) low-a bility students a re required to rea d the question ca refully, 

educa tors should empha size the problem -solving procedure, a nd students should strengthen their understa ndin g 

of the prerequisite lea rning content in problem -solving; (2) medium -a bility students ha ve to focus on the 

empha sis a nd development of their skills in understa nding the la ngua ge of a  problem a nd ba la nce with 

improving their understa nding of lea rning content a nd contextua l exercising; a nd (3) high-a bility students a re 

provided with exercises tha t ca n improve their counting speed a nd a ccura cy of the subject in resolving a  

problem. 

ARTICLE INFORMATION 

Keywords  Article History 
 

Students’ errors 

Problem Solving 

Newma n’s Error Ana lysis 
   

 

Submitted Aug 26, 2020 

Revised Apr 4, 2021 

Accepted Apr 5, 2021 

Corresponding Author 

Veni Sa putri 

STKIP Media  Nusa nta ra  Citra  

Jl. Ra ya  Pa njang, Ja ka rta Ba rat, Indonesia 

Ema il: veni.sa putri@stkipmnc.a c.id 

How to Cite 

Sa putri, V., Ka msurya , R. (2021). The Newma n Procedure for Ana lyzing Students’ Errors in Solving Systems 

of Linea r Equa tions. Kalamatika: Jurnal Pendidikan Matematika , 6(1), 31-44. 
 

https://doi.org/10.22236/KALAMATIKA.vol 6no1.2021pp31-44 

http://creativecommons.org/licenses/by-sa/4.0/
http://creativecommons.org/licenses/by-sa/4.0/
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mailto:veni.saputri@stkipmnc.ac.id
mailto:veni.saputri@stkipmnc.ac.id


32 KALAMATIKA, Volume 6, No. 1, April 2021, pages 31-44 

INTRODUCTION 

Mathematics learning is inseparable from mathematics problems. Each educator has a 

different teaching strategy for mathematics problem-solving. While problem-solving is the 

main challenge for students in mathematics learning (Abidin, 2015). A problem-solving will 

be difficult if the student does not have the algorithm or procedure to solve it (Bauer, Flatten, 

& Popović, 2017; Serin, 2020). Students have to use prior knowledge in solving problems to 

gain the new one (Hasbullah & Wibawa, 2017). This statement means that students must 

connect their previous knowledge with the problems and develop their completion. Problem-

solving ability is one of the must-have mathematical skills for students at school (Akbar et al., 

2017; Ramdan et al., 2018; Sumartini, 2016; Ulandari et al., 2019). Therefore, it requires 

further students’ errors analysis in solving problems. 

Students' problem analysis could solve a challenge in the teaching and learning process 

(Verschaffel, Greer, & De Corte, 2010). This error analysis is expected to identify the cause of 

the student's error and be a basis to overcome the learning obstacles. An error analysis 

procedure that could be used is Newman error analysis. A teacher developed Newman's error 

analysis in Australia in 1977. Newman defines five crucial activities in analyzing the error of 

solving a problem: reading, understanding, transformation, process skills, and encoding 

(White, 2010). Newman's procedure was used because it has easy and straightforward steps to 

identify students' errors and difficulties in problem-solving.  

Students' errors in mathematics problem-solving could vary. One of the factors is the 

basic mathematics understanding of each individual. Thus, the error analysis divides students 

into groups or categories that correspond to students' mathematics ability. The error 

descriptions could be reviewed from students’ initial mathematical ability: high, medium, and 

low. Afterward, it could also be described as the cause of errors based on each group's error. 

This statement corresponds to Ruseffendi (2006), which revealed that techniques for analyzing 

assessment results could be classified according to students’  proficiency level, level of 

understanding, and individual expertise. 

Based on the previous explanation, error analysis and solutions to students’ 

mathematics problem-solving challenge is required to achieve learning objectives.    

 

 



Saputri &Kamsurya      33 
 

METHOD  

This study utilized a qualitative approach with a case study method to depict and describe 

students' errors in problem-solving activities for a linear equation system topic. Sugiono (2012) 

suggested that the characteristic of qualitative descriptive research is to examine the original 

condition or the actual situation. A case study is a research strategy whereby researchers 

investigate an event, activity, process, or group of individua ls limited by time and activity using 

various data collection procedures based on time specified  (Creswell, 2014). Case studies could 

present in-depth and detailed perspectives of students' errors in problem-solving activities. Thus, 

the case study is appropriate to the purpose of this research. 

The samples of this study were 15 students of the Mathematics Education Program in 

College of Teacher Training and Education (STKIP) MNC who were selected purposively. 

The participants were selected based on their linear algebra examination scores. Next, one 

subject was chosen to represent each group of the low-ability, medium-ability, and high-

ability. In this study, the data collection was conducted through a test to measure students’ 

problem-solving abilities and a semi-structural interview to gather beneficial qualitative 

information related to students' errors in solving the linear equation system problem. The 

interview data were analyzed using narrative analysis to obtain accurate information about 

students' errors (Cohen, Manion, & Morrison, 2018).  

RESULTS AND DISCUSSION 

The study results are based on the test and interviews with research participants on the 

problem-solving process in a linear equation system. The problems designed for this study is 

as follows: 

A chemist mixes three glucose solutions with a concentration of 20%, 30%, and 45% t o 

produce 10 L of a glucose solution at a concentration of 38%. If the 30% solution volume used 

is 1 L more than twice the 20% solution used, specify each solution's volume. 

The following are the results of the error analysis towards the three levels of students' 

mathematical ability. 

The subject in the low-ability category (S1) 

The result of the subject's work might indicate the error of S1. S1’s answer is presented 

in Figure 1. 



34 KALAMATIKA, Volume 6, No. 1, April 2021, pages 31-44 

 

Figure 1. S1's Answer 

Based on Figure 1, the student did not understand what was meant or required in 

question, resulting in the subject's failure to solve the problem. Further, the results of the 

subject’s answer were verified with interviews based on Newman's procedure. 

R: “Please re-read this question!” 
S1: “A chemist mixes three glucose solutions with a concentration of 20%, 30%, and 45% 

to produce 10 L of a glucose solution at a concentration of 38%. If the 30% solution 
volume used is 1 L more than twice the 20% solution used, specify each solution's 
volume”. 

R: “Do you know the problem that should be solved?” 
S1: “Calculate the volume of each solution used. (Only repeated questions in the 

problem)” 
R: “Do you understand the problem?” 
S1: “I could not understand the problem, so I could not write the mathematical model.” 

R: “What formula should you use to solve the problem?” 
S1: “I do not know, I do not understand”. 

R: “Please, try to explain how you solved the problem!” 
S1: “I do not understand the problem, so I could not develop a solution in calculations. I 

wrote the answer by estimating the volume number of each solution”. 

R: “Why didn't you accurately calculate the calculation process”s. 
S1: “Because I could not understand the problem, I was confused”. 
R: “Do you understand the learning content of the linear equations system well?” 

S1: “Just a little. It is just that I sometimes have a lack of understanding about the word 
problem”. 

R: “What makes you difficult about the word problems?” 
S1: “It is difficult to understand the problem and transform it into a mathematical form”. 
 

The interview excerpt illustrates that the subject could not solve the linear equation 

system's problem well. The participant could not understand the context of the problem, 

resulting in difficulty developing a problem-solving solution. Furthermore, student’s error 

analysis results based on Newman's procedure are presented in Table 1.  



Saputri &Kamsurya      35 
 

Table 1. Error analysis on S1 
Type of error Expla na tion Interview results 

Reading It could not be investigated through student’s answers. Read the problem thoroughly and 
smoothly. 

Comprehension The subject rewrote the information contained in the question. The subject could not explain what was 
known, and the problem was in the 
mathematical form. 

Transformation It did not indicate a problem-solving strategy. 

 

The subject had difficulty in creating 

mathematical models. 
Process skills • The subject did not perform mathematical procedures. 

• The subject did not operate all the given information in t h e 
problem. 

The subject could not understand the 
problem's information, so he did not 
write the calculation process. 

Encoding • The subject solved the problem without any necessary 
calculations. 

• The volume unit was incorrect. 

The subject could not explain the written 

answer. 

 

Table 1 shows that the low-ability subject does not make an error in the reading aspect, 

but the main error is in the comprehension section. As a result, errors also occur in subsequent 

stages include transformation, process skills, and encoding. Comprehension error is caused by 

the subject's inability to understand the information in the problem so that the subject could 

not create mathematical models and devise a problem-solving strategy. Understanding the 

problem is essential for students because it can determine the next step to solve the problem 

(Dogan-Coskun, 2019). 

The interview shows that the subject did not correctly implement the problem-solving 

procedure. The participant had difficulty with word problems. However, this is contrary to 

pre-existing learning. The subject had been trained with word problems. He recognized that it 

is difficult to translate the word problem into a mathematical form. Kamsurya (2019) 

suggested that problems in mathematics learning can be presented in non-routine questions in 

the form of word problems, depictions of phenomena or events, illustrations of images or 

puzzles, and the use of social and scientific contexts. Besides, the subject slightly underst ood 

the learning content related to the topic. This statement is in line with Rachmawati (2017) and 

Widyastuti et al. (2017) that low-ability students have difficulty creating mathematical 

modeling of a problem. Students do not use all given information, confuse in determining the 

problem-solving strategy, and are unable to perform mathematical procedures. Students' 

inability to develop problem-solving strategies is a significant problem in mathematics 

learning nowadays (Thomassen & Stentoft, 2020).  

Low-capability students should find the solution to improve their learning outcomes by 

solving the problem carefully. The subject must also reinforce the prerequisite material 

understanding in resolving problem-solving. Furthermore, educators should emphasize the 



36 KALAMATIKA, Volume 6, No. 1, April 2021, pages 31-44 

problem-solving procedure to develop an appropriate teaching strategy.  In line with this 

statement, Y. M. Sari & Valentino (2017) argued that the solution for students who do error in 

understanding the problem is to ask students to read the question carefully and make questions 

about the problem "what to find or seek a solution" to strategize in problem-solving. 

Meanwhile, Rachmawati (2017) revealed that alternative solutions for low-ability students are 

by providing an in-depth understanding of the concept and insight into issues in the form of 

word problems by carefully teaching them to understand the problem given. 

The subject in the medium-ability category (S2) 

Subjects in this category could understand the problem and compile what is required in 

solving the problem, but the subject was unable to design a problem-solving strategy. It is seen 

in the S2’s answer in Figure 2. 

 

Figure 2. S2'S Answer 

S2's work was analyzed by the Newman procedure and alignment with the student's 

interview, as follows. 

R: “Please re-read this question!” 
S2: “A chemist mixes three glucose solutions with a concentration of 20%, 30%, and 45% 

to produce 10 L of a glucose solution at a concentration of 38%. If the 30% solution 

volume used is 1 L more than twice the 20% solution used, specify each solution's 
volume”. 

R: “Do you know the problem that should be solved”? 
S2: “Yes, I know that is counting the volume of each solution to create a new solution with 

a concentration of 38%. So I have to use what is already known in the problem to solve 

it”. 
R: “How do you solve the problem?” 



Saputri &Kamsurya      37 
 

S2: “First, I have to transform what is known into a mathematical form. However, I was 
confused about creating the model”. 

R: “Why were you confused?” 

S2: “I have created two mathematical models. However, when calculating using a linear 
equation system procedures, it apparently cannot be resumed”. 

R: “Why can it not proceed? Are there any missed steps in mathematical modeling?” 
S2: “I could not”. 

 

The interview excerpt shows that the S2 subject could understand the linear equation 

system's problem well. However, the S2 participant had difficulty creating a mathematical 

model based on the problems, resulting in an incorrect solution. The analysis of student’s 

errors based on the Newman procedure is found in Table 2.  

Table 2. Error analysis on S2 
Type of error Expla na tion Interview results 

Reading It cannot be investigated through the subject’s work results. Read the problem thoroughly and 
smoothly. 

Comprehension Students wrote down known and asked information in the 
mathematical model but were not yet perfect. 

The student was explaining what was 
known and the problem to determine the 

volume of each solution used. 
Transformation • The subject conducted an error in resolving the equations. 

• The subject did not use the linear equations system strategy 
properly because there was a shortage in drafting 
mathematical models. 

The subject had difficulty in creating 
mathematical models. 

Process skills • The subject misused mathematical operations. 

• The subject did not continue the calculation process. 

The subject made an error at the 
transformation stage, so he could not 
continue the calculation process. 

Encoding • The subject wrote the conclusion without going through the 
correct calculation process. 

• The subject did not use volume units. 

The answers did not convince the 

subject. 

 

Based on Table 2, S2 had difficulty in creating mathematical models. The medium-

ability student often has difficulties in mathematical modeling, determining problem-solving 

strategies, and applying mathematical procedures (Widyastuti et al., 2017). The main error 

conducted by S2, according to Table 2, is located in the transformation section. There was a 

shortage of mathematical models that should be regenerated. However, the subject was 

unaware of the error, so he succeeded in determining the problem-solving strategy.  

The interview results show that the subject could explain the problem and draft the 

mathematical model. The ability to explain and reasoning that supports mathematical problem-

solving is essential for students to solve problems (Rawani, Putri, & Hapizah, 2019). 

However, the subject showed his doubts in drafting the mathematical model of the question 

since he could not continue the calculation process using a linear equations system. After 

being given further questions, the participant was unaware of his error in drafting 

mathematical models. The interview results confirm that the S2’s error is in the part of the 



38 KALAMATIKA, Volume 6, No. 1, April 2021, pages 31-44 

transformation. The subject could understand the problem but could not compile the 

mathematical model as the first step to solve the problem. The error continued at the next 

stage, process skills, and encoding. Zakaria et al. (2010) also explained that the error of 

process skills always follows the transformation error. 

An alternative solution that can be given to a medium-capable subject is to improve the 

mastery of the learning content covering the concepts and provide students with some 

exercises related to word problems to understand problem-solving (Rachmawati, 2017) better.  

Furthermore, according to Zakaria et al. (2010), transformation error happens because the 

teacher does not emphasize students’ understanding of the mathematical language and skills. 

Based on this statement, the solution that could be offered to medium-capable subjects is to 

conduct mathematical learning that focuses on the emphasis and development of students’ 

abilities in understanding a problem's language and balanced with improved learning content 

mastery and contextual exercise (Erdoğan & Gül, 2020).  

Subjects in the high-ability category (S3) 

The S3's answer indicates that the subject could determine a problem-solving strategy 

but made an error in his calculation procedure, as seen in Figure 3. 

 

Figure 3. S3's Answer 

 

 



Saputri &Kamsurya      39 
 

Figure 3 shows the problem-solving process performed by S3. It appears that the 

subject did not continue the calculation process to obtain the result. After the interview  

section, the subject revealed that the time given to work on the problem was not enough, so he 

felt rushed to finish it. S3 expressed this situation in the following interview excerpt. 

R: “Please re-read this question!” 
S3: “A chemist mixes three glucose solutions with a concentration of 20%, 30%, and 45% 

to produce 10 L of a glucose solution at a concentration of 38%. If the 30% solution 
volume used is 1 L more than twice the 20% solution used, specify each solution's 

volume”. 
R: “Do you know the problem that must be solved?” 
S3: “Yes, I know; determine the volume of solution with a concentration of 20%, 30%, and 

45% to produce 10L concentration solution 38% with the provisions already known in 
the problem”. 

R: “Could you explain your answer? (While showing the results of the S3’s work)” 
S3: “I wrote an example to create a mathematical model. Then, I proceeded by converting 

one of the mathematical models into a more straightforward form. After that, I used a 

completion rule of linear equations system to get the result”. 
R: “did you get the result?” 

S3: “Not yet. I did not continue the calculations because I had not enough time. I was 
rushed because I needed more time to understand the problem at the beginning of the 
process”. 

The interview excerpt shows that the problem-solving stages of S3 subjects have been 

excellent and structured. S3 could analyze the linear equation system's problems well and 

create mathematical models to find solutions. However, the S3 was unable to gain the final 

result due to limited working time. Furthermore, the analysis of student ’s errors based on 

Newman Procedure is found in Table 3.   

Table 3. Error analysis on S3 
Type of error Expla na tion Interview results 

Reading It could not be investigated through the subject’s work results. Read the problem thoroughly and 
smoothly. 

Comprehension The subject performed mischief, wrote what was known, and 
asked. 

Explained the answer, what was known, 
and the problem, which is to determine 
the volume of each solution used. 

Transformation Subject wrote problem-solving strategy using a linear equations 
system, i.e., elimination and substitution. 

The subject had difficulty in creating 
mathematical models 

Process skills • The subject did not complete mathematical operations. 

• The subject did not gain the final result. 

The subject had a lack of understanding 
in the calculation process and a lack of 

time.  
Encoding The subject did not write conclusions. The result of the previous error so not 

asked. 

 

Table 3 describes in detail the work results and interview on S3. The participant's main 

error was in the Process Skills section, i.e., the subject did not complete the mathematical 



40 KALAMATIKA, Volume 6, No. 1, April 2021, pages 31-44 

operation in the problem-solving steps. This error affects the following process: the subject did 

not conclude at the end of the answer (Saputri, 2019).  

The error done by S3 was not very significant because the subject could understand the 

problem and determine the problem-solving strategy well. Nevertheless, the subject argued 

that the teacher should add  the time allocation. The subject also explained that understanding 

the problem took a longer time than creating the mathematical model. Kamsurya (2019) 

revealed that students could not complete the overall problem-solving process due to longer 

time in the early stages of completion, resulting in students not getting the final answer. It is 

also supported by Mahdayani (2016) and Novferma (2016), who wrote that the difficulty 

factor outside of the cognitive factors experienced by students in mathematical problem-

solving is that students feel anxious, rushed in work and claiming that they have insufficient 

time. Thus, an alternative solution that could be given to a high-ability subject is the teacher 

could provide problems as exercises that could improve the students' speed of counting and 

thoroughness in resolving a problem. 

CONCLUSION 

This study shows that low-level students' main errors took place at the comprehension 

stage. Students did not correctly implement the problem-solving procedure because they did 

not understand the problem given. In a medium-ability student, an error occurred at the 

transformation stage that students could understand the problem and compile what was 

required in the problem. However, they could not arrange a problem-solving strategy. The 

main error performed by high-ability students was less significant and happened in the process 

skills section. Students did not complete mathematical operations in the problem-solving steps 

because they had not enough time. 

Recommendations from the results of this study to minimize students’ error in the 

problem-solving process are: (1) Low-ability students are required to read the question 

carefully, educators should emphasize the problem-solving procedure, and students should 

strengthen the prerequisite learning concept understanding in problem-solving; (2) Medium-

ability students should focus on the emphasis and development of their skills in understanding 

the language of a problem and balanced with improving learning concept mastery and 

contextual training; and (3) High-ability students should conduct exercises that could improve 

their counting speed and thoroughness of the subject in resolving a problem. 



Saputri &Kamsurya      41 
 

ACKNOWLEDGMENTS 

The authors would like to thank LPPM STKIP Media Nusantara Citra for providing 

material support by letter No. 002/STPPN/LPPM/V/2020. We would also extend our thanks to 

the mathematics education lecturers for their encouragement to finish writing this article. 

 

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