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Kalamatika: Jurnal Pendidikan Matematika 

Volume 5, No. 2, November 2020, pages 119-132 

                                                                             

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119 

ERRORS ANALYSIS OF STUDENTS IN SOLVING VOLUME OF THE 

SOLID OF REVOLUTION PROBLEM IN TERM OF CRITICAL 

THINKING ASPECTS  

Betty Kusumaningrum
1
, Muhammad Irfan

2
, Zainnur Wijayanto

3
 

1
Universitas Sarjanawiyata Tamansiswa, Jl. Batikan UH III, Umbulharjo, Yogyakarta, Indonesia 

betty.kusumaningrum@ustjogja.ac.id  
2
Universitas Sarjanawiyata Tamansiswa, Jl. Batikan UH III, Umbulharjo, Yogyakarta, Indonesia 

muhammad.irfan@ustjogja.ac.id 
3
 Universitas Sarjanawiyata Tamansiswa, Jl. Batikan UH III, Umbulharjo, Yogyakarta, Indonesia 

zainnurw@ustjogja.ac.id 

 

ABSTRACT 

Students of mathematics education need to have a good understanding in solving integral calculus problems, but 

often have difficulty in understanding the subject material. The difficulties can be seen from the mistakes made 

by students when solving the problems. This article aims to analyze the errors of students in learning integral 

calculus especially in the subject of volume of the solid of revolution in terms of critical thinking aspects. This 

research is a qualitative descriptive study involving twenty-four of 6th-semester students of mathematics 

education at a private university in Yogyakarta. The research subjects were chosen purposively by considering: 

student errors in determining the volume of the solid of revolutions with integral techniques in terms of critical 

thinking aspect. The findings of this study indicate, student errors in determining the function of integrals, write 

down the rules of integral writing, misunderstanding in algebraic concepts, adding constants C , write down limits 
and sigma notations, determine integration methods, determine boundaries integration, writing x in integral 
sign, and error in determining the radius of the solid of revolution. 

 

ARTICLE INFORMATION 

Keywords  Article History 

Critical thinking 

Error analysis  

Problem-solving 

The volume of the solid of revolution 
 

Submitted Mei 4, 2020 

Revised Aug 21, 2020 

Accepted Aug 21, 2020 

Corresponding Author 

Betty Kusumaningrum  

Universitas Sarjanawiyata Tamansiswa  

Jl. Batikan UH III, Tahunan, Umbulharjo, Yogyakarta, Indonesia 
Email: betty.kusumaningrum@ustjogja.ac.id 

How to Cite 

Kusumaningrum, B., Irfan, M., & Wijayanto, Z. (2020). Errors Analysis of Students in Solving Volume of the 

Solid of Revolution Problem in Term of Critical Thinking Aspects. Kalamatika: Jurnal Pendidikan Matematika, 

5(2), 119-132. 

https://doi.org/10.22236/KALAMATIKA.vol5no2.2020pp119-132 

http://creativecommons.org/licenses/by-sa/4.0/
http://creativecommons.org/licenses/by-sa/4.0/
http://creativecommons.org/licenses/by-sa/4.0/
mailto:betty.kusumaningrum@ustjogja.ac.id
mailto:2muhammad.irfan@ustjogja.ac.id
mailto:betty.kusumaningrum@ustjogja.ac.id


120 KALAMATIKA, Volume 5, No. 2, November 2020, pages 119-132 

INTRODUCTION 

Mathematics education students need a good understanding of solving mathematical 

problems, but often have difficulty in understanding the subject material. The difficulties can be 

seen from the mistakes made by students when solving the problems. A problem occurs when a 

student wants to achieve goals state but has no obvious method (Mayer & Wittrock, 1996). 

Problems can occur because there is a discrepancy between the situation and the objectives to 

be achieved (Irfan, 2017; Widodo, 2013). The problem can be interpreted as an unknown entity 

and the solution needs to be found (Anggo, 2011). In mathematics, problems are usually 

presented in the form of mathematics problems (Widjajanti, 2009; Widodo, Purnami, & 

Prahmana, 2017). But not all mathematical problems are a problem for students. A mathematical 

problem becomes a problem for students if they want to solve the problem, but have no idea to 

solve it (Widodo & Sujadi, 2015). If students immediately know how to solve it correctly, it 

cannot be a problem for them (Widodo & Turmudi, 2017). 

Not only students but also everyone must be having problems because problems and 

problem-solving are part of the process of maturity that must be passed by everyone (Anggo, 

2011). Problem-solving required students to apply and to integrate many mathematical concept s 

as well as making a decision (Tambychik & Meerah, 2010). Therefore, problem-solving in 

mathematics education is important to be instilled in students so they can be accustomed to 

solving problems well, both problems in mathematics, in other fields of study, or in more 

complex daily life (Effendi, 2012; Pardimin & Widodo, 2016; Widodo, Turmudi, Dahlan, 

Istiqomah, & Saputro, 2018). Problem-solving is a high intellectual activity because students 

are required to use their knowledge and skills to solve unusual problems (Arigiyati & Istiqomah, 

2016). The ability to solve mathematical problems is the ability to overcome the problems that 

were not clear to answer (Widodo, Darhim, & Ikhwanudin, 2018). Mathematical problem 

solving can be used as a means of sharpening careful, logical, and critical reasoning (Widjajanti, 

2009). By thinking critically, people can easily make rational decisions (Haryani, 2011). 

The ability to think critically of each person varies depending on the intensity of those 

people in developing critical thinking skills. This ability becomes important to be accustomed 

by everyone because if there is a problem they can provide solutions to solve the problems with 

rational and carefulness (Amir, 2015). So, critical thinking is a process that aims to make some 

decisions as a form of problem’s solution with full consideration. The ability to think critically 



Kusumaningrum, Irfan, & Wijayanto     121 
 

can be seen from the indicators of critical thinking. There are five indicators of critical thinking 

ability, namely: (1) Analyzing, is the ability to decompose a structure into components, (2) 

Synthesize, is the ability to combine parts into new arrangements, (3) Solve problems, is the 

ability to apply concepts, (4) conclude, is the ability to obtain new understanding, and (5) 

evaluating, is the ability to judge based on certain criteria (Santoso, 2009). Researchers use those 

indicators to identify student errors in solving integral calculus problems. Indicators of critical 

thinking are presented in Table 1. 

Table 1. Indicators of Critical Thinking 

Indicators of Critical Thinking 

(Santoso, 2009) 

Indicators of Critical Thinking That Used to Identify Student Errors in 

Solving Integral Calculus Problems 
Analyzing Identify the characteristics of the concept 

Synthesize Compare another concept 

Solve problems Identify the concept that used in making a decision 

Conclude  Provide an assessment/explanation of the concept 

Evaluating Evaluate the decisions that have been taken 

 

Subject material in Mathematics Education Study Programs mostly requires critical 

thinking skills, one of them is Integral Calculus. Integral calculus is a course that must be taken 

by all mathematics education students and needs to be mastered broadly and deeply. However, 

there are still many students who have difficulty in understanding the subject material, 

especially in the volume of the solid of revolution. Midterm Examination scores for 6th-semester 

students on the problem of the volume of the solid of revolution can be seen in Figure 1.  

 

Based on the recapitulation of the Midterm Examination scores of 6th-semester students 

in the academic year 2016/2017 and 2017/2018, it was found that students who answered 

correctly on the problem of the volume of the solid of revolution did not reach 50%. This shows 

4
5

%

4
7

%

Academic year 2016/2017 Academic year 2017/2018

Figure 1. Midterm Exam Result 



122 KALAMATIKA, Volume 5, No. 2, November 2020, pages 119-132 

that most of the Mathematics Education students had difficulty in those subject material.  

Regard to mathematics learning difficulties, the results of other studies show that error 

students are to determine the upper and lower limits of integration (Wahyuni, Kurniawan, 

Waluya, & Cahyono, 2019), not yet mastered the substitution integral & partial integrals 

(Nursyahidah & Albab, 2017), have not been able to distinguish the concept of definite integral 

& indefinite integral, calculation errors in determining the value of sigma (Rahimah, 2012), 

errors in applying the methods, errors in determining the right function, careless in multiplying 

positive and negative numbers, errors in squaring a function, difficulty in representing the image 

(Rimo, 2018), unable to determine the basic formula of the volume of the solid of revolution, 

errors in determining the points (abscissa and ordinate), and inaccuracy in operating algebra 

(Ahmad, 2019). 

It is important to know those student errors, so in the future students will no longer have 

difficulties in understanding the volume of the solid of revolution material subject. Overcome 

the difficulties of students can be done by analyzing or identifying student errors in solving the 

problem of the volume of the solid of revolution. This study aims to analyze the errors of 

students in solving the problem of the volume of the solid of revolutions in terms of critical 

thinking aspects. Researchers need to conduct this research because there is no previous research 

that discusses the analysis of student errors when solving the problem of the volume of the solid 

of revolution in terms of critical thinking aspects.  

METHOD 

 This research was conducted in a private university in Yogyakarta and involved 38 

students on 6th-semester of the Mathematics Education Study Program in the academic year 

2018/2019 whose take Integral Calculus courses. All of them are asked to solve problems on 

determining the volume of the solid of revolution bounded by curves  and lines  

at the integrating limit [0.4] and rotated around the x-axis to be done in 20 minutes. Then, 

researchers check the student’s answers. After checking student answers, researchers count the 

number of students who answered right, wrong, and those who did not answer. The researchers 

focused on the incorrect answer because we want to know the mistakes in determining the 

volume of the solid of revolution. 

After that, researchers analyze all of incorrectly answered by recording all the errors 

made by students in determining the volume of the solid of revolution. Those student’s error 

2
2
 xy 1y



Kusumaningrum, Irfan, & Wijayanto     123 
 

that has been recorded then analyzed based on aspects of critical thinking. The researchers then 

calculate the percentage of students’ error that have been grouped based on the critical thinking 

aspects using this formula: 

𝑃𝑒𝑟𝑐𝑒𝑛𝑡𝑎𝑔𝑒(%) =  
𝐸

𝑇
 𝑥 100 % 

where,  

𝐸: the number of student’s errors in each type 

𝑇: the number of students who make mistakes overall 

RESULT AND DISCUSSION  

All of 6th-semester students who learn Integral Calculus (as many 38 students) asked to 

solve one problem of the volume of the solid of revolution to be done in 20 minutes. The 

problem that needs to be done is presented in Figure 2. 

 

Test results of 38 students were categorized based on the correct, incorrect, and no 

answer. Researchers then counting the number of students who answered right, wrong, and those 

who did not answer. The number of students who answered right, wrong, and did not answer 

are presented in Table 2. 

Table 2. Percentage of Student Answers  
Category The number of students in each category 

Correct 12 

Incorrect 24 

No answer 2 

 

Based on Table 2 it is known that there were 24 students who answered incorrectly. It 

indicates that there are still many students who have difficulty in understanding the subject 

material.  

Translation 

Problem: determine the volume of the rotating object which is bounded by the curve 𝑦 = 𝑥 2 +
2 and the line y = 1 at the integration boundary [0,4] and rotated about the x-axis. 

Figure 2. The Problem of The Volume of The Solid of Revolution 



124 KALAMATIKA, Volume 5, No. 2, November 2020, pages 119-132 

After that, researchers analyze all of incorrect answered based on the aspects of critical 

thinking. Researchers provide examples of analyzing incorrect answered of 3 research subjects. 

The mistakes of research subjects can be seen in the picture that has been marked with a red 

box.  

1. Research Subject 1 (S1) 

 
Figure 3. Errors by Subject 1 

From figure 3, it can be seen that Subject 1 (S1) has identified the concept used to solve 

the problem. S1 identifies the concept of volume of the solid of revolution from the tube volume 

(S1 uses the tube volume approach). The process of identifying concepts in making a decision 

is based on the similarity between the shape of the tube and the solid of revolution. Students 

who are able to identify problems and provide the correct and concise answers are students with 

high levels of problem-solving (Perbowo, Hadi, & Haryati, 2020). 

It’s actually true to use the volume of the tube to get the volume of the solid of revolution, 

but you have to know the shape of the solid of revolution formed. If the slice of the solid of 

revolution forms a plate, the volume of the solid of revolution can be analyzed using the disc 

method, where: 

       (1) 

Whereas if the slice of the solid of revolution forms a ring, it can be calculated using the 

ring method, where: 

xrrV  ][
2

1

2

2
       (2) 

Equations (1) and (2) are rotary volume equations that resemble the tube volume 

equations, namely: 

       (3) 

S1 seems unable to reduce the volume of the solid of revolution from the volume of the 

tube, which means that S1 has been able to identify the concepts that used in making decision 

but has not re-evaluated the a decision that has been taken whether it is appropriate to calculate 

xrV 
2



trV
2





Kusumaningrum, Irfan, & Wijayanto     125 
 

the volume of the solid of revolution when calculating it with . The formula for the 

volume of the solid of revolution should be written . As a consequence, S1 make a 

mistake in determining the function which should be integrated of . In 

addition, S1 unable to compare another concept, namely the concepts of definite integrals and 

indefinite integrals. It can be seen from the addition of constants in the answers given. It is a 

definite integral problem that did not need to add constants . 

 

2. Research Subject 2 (S2) 

 
Figure 4. Errors by Subject 2 

In solving the problem, Subject 2 (S2) identified the concept of the volume of the solid 

of revolution also using the concept of a tube volume as seen in figure 4. S2 uses the tube volume 

approach to solve the problem. The results of this identification are used in making a decision 

so S2 determines the volume of the solid of revolution using the formula:  

       (4) 

Based on the test results it can be seen that S2 has not evaluated the steps taken whether 

the volume of the solid of revolution is integrated by the ring method or disc method. The 

volume of the solid of revolution should be integrated using the ring method where:  

  

      (5) 

tx  )2(
2



xrr  )(
2

2

2

1


xx  ))1()2((
222



C

C

xxVp

trV





22

2

)2(



xrrV  ][
2

1

2

2


xxVp

xrrVp





))1()2((

)(

222

2

2

2

1







126 KALAMATIKA, Volume 5, No. 2, November 2020, pages 119-132 

In addition, S2 did not look back at the integration limits that requested in the problem. 

The integrating boundary that corresponds to the problem is , but S2 integrates it at the 

boundary . 

Another error made by S2 was an error in write down the rules of integral writing (Figure 

2 No. 2). The correct integral writing sequence is: 

 = ∑ 𝜋 … … … …𝑛𝑖=1 ∆𝑥 

 = lim
𝑛→∞

∑ 𝜋𝑛𝑖=1 … … … … ∆𝑥      (6) 

 = ∫ 𝜋 … … … … 𝑑𝑥
1

0
 

But, S2 writes: 

 = ∑ 𝜋 … … … …𝑛𝑖=1 ∆𝑥 

 = lim
𝑛→∞

𝜋 … … … … ∆𝑥      (7) 

 = ∫ 𝜋 … … … … ∆𝑥
1

0
 

In this case, S2 was unable to identify the characteristics of the concept. S2 was unable 

to identify how the process of forming integrals. In this section, S2 also unable to compare and 

apply the concept of limits and sigma notation to subject material that has been studied 

previously. S2 also did not evaluate the answers written. This can be seen from the writing still 

in the step that has an integral sign. 

 = ∫ 𝜋 … … … … ∆𝑥
1

0
      (step 5) 

       (step 6) 

      (step 7) 

This occurs in the initial steps after the existence of the integral sign in step 5 and step 

6, but in step 7 already written . 

 

 

 

 

 

 

 

 

]4,0[

]1,0[

f
V

f
V

f
V

f
V

f
V

f
V

f
V

xV
f

 
1

0
........

 
1

0

1

0
............... dxdxV

f


dx



Kusumaningrum, Irfan, & Wijayanto     127 
 

3. Research Subject 3 (S3) 

 
Figure 5. Errors by Subject 3 

Based on figure 5, Subject 3 (S3) also identified the concept of the solid of revolution 

volume using the tube volume approach. In the problem, there was a concept of algebra that 

must be understood by students namely  = , it means that each radius should be 

squared first and then subtracted. But what S3 did is subtract first and then squaring the results.  

S3 also had unable to identify the characteristics of the integral concept where the 

integral sign can appear after the sigma and limit notation, in other words, can be written in: 

 = ∑ 𝜋 … … … …𝑛𝑖=1 ∆𝑥 

 = lim
𝑛→∞

∑ 𝜋𝑛𝑖=1 … … … … ∆𝑥      (8) 

 = ∫ 𝜋 … … … … 𝑑𝑥
1

0
 

S3 also did not evaluate what he had done. It can be seen from t he error in writing the 

radius of the solid of revolution ( r ). The things that requested in the problem was to determine 

the volume of the solid of revolution bounded by curves  and lines , but S3 wrote  

. S3 basically understood that the problem was solved by the ring method that there 

was a reduction in the radius. S3 did not understand the concept of algebra. The process of 

evaluating (re-checking) the answers can be done from the sta ge of identifying the concept of 

solving the problem (Irfan, 2018). It can be seen on the test results that S3 adds constants  

even though the problem given is a definite integral problem that there are no constants . S3 

had unable to compare another concept, namely the concept of a definite integral and indefinite 

integral. 

Then, researchers recording all the errors made by students in determining the volume 

of the solid of revolution. Those student’s error that has been recorded then analyzed based on 

f
V xrr  )(

2

2

2

1


f
V

f
V

f
V

2
2
 xy 1y

1
2
 xr

C

C



128 KALAMATIKA, Volume 5, No. 2, November 2020, pages 119-132 

aspects of critical thinking. The types of student’s error based on critical thinking aspects were: 

1) Identify the characteristics of the concept, namely: misrepresents formed the solid of 

revolution, misunderstand in algebraic concepts, and write down the rules of integral writing; 

2) Compare another concept, namely: adding constants C , and write down the limits and sigma 

notation; 3) Identify the concept that used in making a decision, namely: determine the 

integration methods; 4) Evaluate the decisions that have been taken, namely: determine the 

function to be integrated, determine boundaries integration, write down in the integral sign, 

and determine the radius of the solid of revolution.  

The next step is researchers calculate the percentage of error for each type. For example 

the number of students who make mistake in represents formed of the solid of revolution as 

many as 15 students. Meanwhile, the numbers of students who answered incorrectly in 

determining the volume of the solid of revolution as many as 24 students, so the percentage of 

error in represents formed the solid of revolution is 
15

24
 𝑥 100% = 62,5%. The percentage of 

student errors in term of critical thinking are presented in Table 3. 

Table 3. Percentage of Students Error in Term of Critical Thinking Aspect 

 

It can be concluded that the most mistakes made by students are in drawing the solid of 

revolution formed, it means that there are still many students who cannot draw the solid of 

revolutions as requested in the problem. Another error that has the highest percentage is to use 

an inaccurate integration method and determine the right function to be integ rated. The three 

highest percentage errors are related to each other. If a student is still wrong in drawing the solid 

of revolution, it will be making a mistake in determining the methods and functions to be 

integrated. 

The findings of this study were in line with the earlier research in which students also 

have difficulties in solving the problem of the volume of the solid of revolution. The difficulties 

x

Indicators of Critical Thinking Ability Students Error Percentage of Error (%) 
Identify the characteristics of the concept  Misrepresents formed the solid of revolution 62,5  

Misunderstand in algebraic concepts  20,8  

Write down the rules of integral writing 25  

Compare another concept  Adding constants 𝐶 37,5  
Write down the limits and sigma notation 29,2  

Identify the concept that used in making a 

decision 

Determine the integration methods  58,3  

Evaluate the decisions that have been taken Determine the function to be integrated 54,2 

Determine boundaries integration 33,4  

Write down in the integral sign 41,7  

Determine the radius of the solid of 

revolution 

45,8  

x



Kusumaningrum, Irfan, & Wijayanto     129 
 

types are understanding the concept, calculation accuracy, and drawing representations. In 

understanding the concept, students had difficulty in applying the methods, to determine the 

upper and lower limits of integration, and to determine the right function to be integrated. In the 

calculation accuracy, students did multiply positive and negative numbers carelessly, and 

inaccurate in squaring a function. In the representation of images, students were difficult to 

describe the area bounded by the curve given to the problem (Rimo, 2018). Other studies 

describe the students' error in calculating the area and the volume of the solid of revolution using 

a definite integral, namely errors in drawing a parabolic graph and lines, operating algebraic 

shapes, and determining the volume of the solid of revolution rotating 360 0 against the x-axis 

(Salmina, 2017). Other mistakes made by students in solving integral problems were in 

determining the upper and lower limits, did not understand the integration technique, and only 

remembering the formula without understanding its meaning (Wahyuni et al., 2019). Student 

mistakes can be used as a guide to determine the extent to which students understand the subject 

material that has been given. 

 

CONCLUSION 

 Based on this research, it can be concluded that in term of critical thinking skills, students 

made mistakes in determining the formulation of the volume of the solid of revolution, write 

down the rules of integral writing, in understand algebraic concepts, adding constants C , write 

down limits and sigma notation, determine integration methods, determine boundaries 

integration, write down x  in the steps that had an integral sign, and errors in determining the 

radius of the solid of revolution. This study allows further research on the factors that cause 

errors in solving the volume of the solid of revolution problem, what any abilities that are needed 

besides critical thinking skills, and how the role of the lecturer in reducing student errors in 

solving the volume of the solid of revolution problem. 

 

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