Sebuah Kajian Pustaka:


Journal of Mathematics Education p-ISSN 2089-6867 

Volume 8, No. 1, February 2019 e–ISSN 2460-9285 
 

  https://doi.org/10.22460/infinity.v8i1.p99-108  

  

99 

UNDERGRADUATE STUDENTS SELF-CONCEPT AND 

THEIR MATHEMATICS PROCEDURAL KNOWLEDGE:  

THE RELATIONSHIP 
 

Muhammad Win Afgani*
1
, Didi Suryadi

2
, Jarnawi Afgani Dahlan

3
 

1 
Universitas Islam Negeri Raden Fatah 
2,3 

Universitas Pendidikan Indonesia 

 

 

Article Info  ABSTRACT 

Article history: 

Received Sept 11, 2018 

Revised Feb 10, 2019 

Accepted Feb 27, 2019 

 

 This study aimed to explain the relationship between self-concept and 
mathematics procedural knowledge among undergraduate students of 

mathematics education. This study investigated the affective and cognitive 

aspect of students in the learning of mathematics. The method in this study 

surveyed with non-probability sampling technique. The subjects were 133 

undergraduate students of mathematics education from public and private 

university in Palembang, Indonesia. 66 of them were undergraduate students 

in public university. The rest of them were undergraduate students in a 

private university. The instruments that were used are questionnaire of self-

concept and essay test of mathematics procedural knowledge. The result 

from the Spearman Rank Correlation showed Sig. = 0.006 < 0.05. From that 

result, we conclude that there is a significant relationship between 

undergraduate students’ self-concept and their mathematics procedural 

knowledge. 

Keywords: 

Self-Concept, 

Mathematics Procedural 

Knowledge, 

Relationship. 

 

Copyright © 2019 IKIP Siliwangi.  

All rights reserved. 

Corresponding Author: 

Muhammad Win Afgani,  

Department of Mathematics Education, 

Universitas Islam Negeri Raden Fatah, 

Jl. Prof. K. H. Zainal Abidin Fikri KM. 3.5 Palembang 30126, Indonesia. 

Email: muhammadwinafgani_uin@radenfatah.ac.id 

How to Cite: 

Afgani, M. W., Suryadi, D., & Dahlan, J. A. (2019). undergraduate students self-concept and their 

mathematics procedural knowledge: the relationship. Infinity, 8(1), 99-108. 

 

1. INTRODUCTION 

The relation of affective and cognitive aspect to students in learning mathematics is 

an interesting issue to discuss. That issue involve not only about how students learn 

mathematics, but also how his/her psychology when learn it. Assessment that only 

observes cognitive dimension is not enough yet to describe students’ mathematics 

achievement (Suryanto, 2008). Affective dimension also needs to be observed to students, 

because the characteristic can give an image to a teacher about students’ psychology, such 

as attitude when he/she faces mathematics subject. Positive attitude to mathematics is an 

important part of mathematics education (Reyes, 1984). One of the affective aspects that 

describes an individual and relates to his/her cognitive dimension is self-concept 

(Ghazvini, 2011). 



 Afgani, Suryadi, & Dahlan, Undergraduate students self-concept and their mathematics procedural …  100 

Self-concept is the way of individual views about he/she abilities in various 

aspects, such as academics, athletics, and social interactions. In social life, individual 

behavior corresponds to his/her self-concept. It determines individual reaction to people 

surrounding him/her (Mishra, 2016). According to Shavelson & Bolus (1982), self-concept 

can be categorized as two, that is, academic self-concept and non-academic self-concept. 

Self-concept that views from academic can be defined as academic self-concept. An 

academic self-concept is an individual psychological relate to belief about his/her ability in 

academic (e.g. mathematics) (Flowers, Raynor Jr, & White, 2013). Individual experiences 

in academic achievement related to the ways that he/she has learned to view his/herself and 

his/her relationships with others people. That individual view refers to his/her academic 

self-concept (Oluwatosin & Bamidele, 2014). According to Fin & Ishak (2014), an 

individual non-academic self-concept also influences his/her academic achievement, but 

indirectly. They explained that academic self-concept as a mediator between non-academic 

self-concept and academic achievement. 

There are many aspects relate to individual self concept, that are, physical 

characteristic, individual concern, social identity, individual personality (Reyes, 1984), 

view of the future (Barongo & Nyamwange, 2013; Deshmukh, 2015; Lone & Lone, 2016; 

Rajeswari & Kalaivani, 2016), the influence of others who become role models (Andinny, 

2015), and the influence of surrounding environment (Singh, 2015). Self-concept in 

academic, especially mathematics, according to Reyes (1984), Students’ view of the 

mathematics is an important aspect in learning mathematics. 

The studies that concern to the relationship between self-concept and mathematics 

achievement have been investigated by Ayodele (2011), Seaton et al. (2014), Andinny 

(2015), Jamaldini et al. (2015), Singh (2015) and Timmerman, Van Luit, & Toll (2017). 

They argued that there is a relationship between both variables. On the other previous 

studies, there is no correlation between self-concept and academic achievement (Yahaya & 

Ramli, 2009; Afuwape, 2011; Berg & Coetzee, 2014; Nalah, 2014; Yengimolki, 

Kalantarkousheh, & Malekitabar, 2015). That result also occurred to Adebule (2014), 

Awai & Ogori (2016) studies’ in mathematics. We argued that inconsistence phenomenon 

because of mathematics achievement in their studies was unclear about what mathematical 

ability that they observed. 

Students’ academic achievement, according to Zulnaidi & Zamri (2017), can be 

interpreted as students learning ability. There are many aspects of learning ability in 

mathematics, that are conceptual, procedural, problem-solving, communication, reasoning, 

and representation ability. To make that problem clear, we investigated self-concept and 

mathematical procedural ability. We defined mathematical procedural ability as procedural 

knowledge in mathematics. We focused on that ability because it is fundamental that 

students should have in learning mathematics. Zulnaidi & Zamri (2017) stated that students 

need to acquire procedural knowledge at least. Mathematics procedural knowledge as a 

knowledge that knows about the symbols in a system and its structure and knows about the 

rules or procedures to solve mathematics problem (Star & Stylianides, 2013; Joersz, 2017; 

Zulnaidi & Zamri, 2017). 

Mathematics procedural knowledge is a part of mathematics understanding. 

Mathematical understanding, according to Skemp (1976), consists of instrumental and 

relational understanding. A student that has instrumental understanding, if he/she can apply 

mathematics formula to a problem, whereas a student that has relational understanding, if 

he/she knows a mathematics rule, apply it, and the reason. It shows that instrumental 

understanding corresponds to procedural knowledge or action conception in APOS theory 

perspective (Afgani, Suryadi, & Dahlan, 2017). Mathematics procedural knowledge that 

was measured in this study is about calculus preliminary materials that are, simplification 



 Volume 8, No 1, February 2019, pp. 99-108

 

 

101 

and factorization of algebra form in R system, quadratic equation, inequality, absolute 

value, linear equation, and function. One of the example of the items is "Determine the 

linear equation that through (2, -5) and perpendicular with 2x – 4y = 3". A solution of that 

mathematics problem requires mathematics procedural knowledge of students. Firstly, they 

must transform the equation to become y = ax + b. the new equation shows that "a" is a 

gradient of the first line. The gradient that perpendicular to the first line is negative 

reciprocal of "a". Finally, they must substitute it and (2, -5) to a formula of the linear 

equation through a point with gradient is known and it produces only one answer. The 

procedure to solve that mathematics problem connects with some mathematics concept. 

This means that students also need to know mathematics concepts. In this situation, 

students must know the concepts that are needed to solve it so that they can operate the 

procedure completely. According to Kusuma & Masduki (2016), a student cannot choose a 

right procedure to solve mathematics problem due to he/she does not know the concepts 

that appropriate to solve the problem. In mathematical procedural ability, students only 

need to know or remember a mathematics concept and apply it and he/she does not have to 

understand the concept very well. 

As the previous explanation, there is an inconsistence result about students’ self-

concept and their mathematics achievement. In this study, we still investigated both 

variables, but the scope of mathematics achievement is focused on mathematics procedural 

knowledge. The research question is tried to answer; is there a relationship between self-

concept and mathematics procedural knowledge among undergraduate students of 

mathematics education. 

 

2. METHOD 

The method was used in this study is survey. The subjects were 133 undergraduate 

students of mathematics education from public and private university in Palembang, 

Indonesia. They were chosen through non-probability sampling. 66 of them were 

undergraduate students in public university which consists of 12 males and 54 females. 

The rest of them were undergraduate students in private university which consist of 9 

males and 58 females.  

The instruments that were used are questionnaire of self-concept and essay test of 

mathematics procedural knowledge. Self-concept instrument was developed from 

instruments that were used by Ferla, Valcke, & Cai (2009), Matovu (2012), Flowers et al. 

(2013) in form Likert scale. We used that form, because it easy to understand respondents’ 

perception (Subedi, 2016). We developed the instrument to be appropriated with the 

condition to undergraduate students of mathematics education that take calculus of 

differential class. For test instrument, we used problems referenced from calculus book.  

Before we applied both instruments to field test, we did validity and reliability test to the 

instruments. The respondents are non-experiment subject. According to Subedi (2016), 

Likert scale can be assumed as a set of data arranged in sequential category and 

continuous. The data can be treated as interval data, so according to Joshi et al. (2015) 

implied that the validity test from interval data can use Pearson product moment and the 

reliability test use Cronbach's Alpha. Hence, the validity and reliability test in this study 

used both formulas and the result presented in Table 1. 

 

 

 

 



 Afgani, Suryadi, & Dahlan, Undergraduate students self-concept and their mathematics procedural …  102 

Table 1. The Results of Validity and Reliability Test 

Instrument 
Type of 

Instrument 

Number 

of items 

Number of 

Respondents 

Critical 

Value 

of 

Pearson 

( = 

0.05) 

Cronbach's 

Alpha 

Value 

Number 

of Valid 

Items 

Self Concept Non-Test 43 65 0.244 0.92 42 

Mathematics 

Procedural 

Knowledge 

Test 16 40 0.312 0.88 14 

 

The result from Table 1 showed that one item of the non-test instrument and two 

items of test instrument were invalid because the correlation values were less than each of 

its critical value of Pearson. It because there was several respondents obtain same total 

score, but score of the items was different. That means a validity of the items was less 

convince (Arikunto, 2012). Hence, only 42 items of self-concept questionnaire and 14 

items of mathematics procedural knowledge test were valid and reliable. 

The procedures to investigate self-concept and mathematics procedural knowledge 

of undergraduate students of mathematics education are, Firstly, We collected the data of 

both variables. We examined mathematics procedural knowledge about calculus 

preliminary to the subjects during 2 hours. After they finished it, they were requested to fill 

self-concept questionnaire. The data of the questionnaire in this study were treated as 

interval according to Joshi et al. (2015), because the result of construct validity test from 

four experts in mathematics education implied each item is arranged logically, 

interconnected, coherent, and measure different elements from aspects of self-concept. 

Secondly, we processed the data. Because type of both data vairiables was interval, we 

converted the score from both variables become value ranging 0 – 100. The formula is 
             

            
    . Ideal score for the self-concept questionnaire was 168 and mathematics 

procedural knowledge test was 54. After that, we seek the average and standard deviation 

value of self-concept score in terms of overall. We categorized the average value of 

students’ self-concept and their mathematics procedural knowledge become 5 categories, 

that are, very good (81 – 100), good (61 – 80), good enough (41 – 60), adverse (21 – 40), 

and very adverse (0 – 20). To test the hypothesis, there is a relationship between self-

concept and mathematics procedural knowledge among undergraduate students of 

mathematics education, we do correlation test. 

The data analysis that was used in this study is descriptive statistic to categorize the 

data and Pearson product-moment to test the correlation between self concept and 

mathematics procedural knowledge among undergraduate students of mathematics 

education. To assist all that analysis, we used SPSS 16.0. 

 

3. RESULTS AND DISCUSSION 

Descriptively, the results of data analysis showed that mean value of students’ self-

concept is 82.63 with standard deviation is 6.39. From 0 – 100 scale, it means that 

students’ self-concept was categorized good. This result is also supported by a study of 

Suryanto (2008). Mean value of students’ mathematics procedural knowledge is 21.31 with 

standard deviation is 14.94. It means that students’ mathematics procedural knowledge was 

categorized adverse. According to Barongo & Nyamwange (2013), the result reveals 



 Volume 8, No 1, February 2019, pp. 99-108

 

 

103 

incongruence between students self-concept with their mathematics procedural knowledge. 

It will congruence if both aspects in the same category.   

To answer the research question, is there a relationship between students’ self-

concept and their mathematics procedural knowledge, firstly, we did preliminary analysis 

test to both variables. From Table 2, the normality test of Self-Concept (SC) value has sig. 

= 0.200 > 0.05 and Mathematics Procedural Knowledge (MPK) value has sig. = 0.002 < 

0.05. It means distributions of the data are normal, except MPK value. 

Table 2. Summary of Normality Test of Self Concept and Mathematics Procedural 

Knowledge Value 

Variable Skewness Kurtosis Statistic Sig. 

SC 0.123 - 0.661 0.068 0.200 

MPK 1.266 2.558 0.101 0.002 

 

 

For the homogeneity test between public and private university, the Sig. value of 

SC was 0.746 and the Sig. value of MPK value was 0.448. It shows that both sig. value > 

0.05. It means that the data is homogenous variance. The result is summarized in Table 3. 

Table 3. Summary of Homogeneity test of Self Concept and Mathematics Procedural 

Knowledge Value 

Variable Levene statistic Sig. 

Self Concept 0.105 0.746 

Mathematics Procedural Knowledge 0.580 0.448 

 

From that result, to test the hypothesis there is a significant relationship between self-

concept and mathematics procedural knowledge of undergraduate students of mathematics 

education used Spearman rank correlation. 

Table 4. Summary of Relationship between Self-Concept and Mathematics Procedural 

Knowledge Value 

Variable N Mean 
Standard 

Deviation 

Coefficient 

Correlation 
Sig. 

SC 133 82.63 6.39 
0.238 0.006 

MPK 133 21.31 14.94 

 

The result from Table 4 showed that Sig. = 0.006 < 0.05. It means there is a 

significant relationship between students’ self-concept and their mathematics procedural 

knowledge. Furthermore, the correlation coefficient showed 0.238 and its determination 

coefficient was 5.66%. It means that the correlation between both variables is positive but 

low, moreover student self-concept only influenced his/her mathematics procedural 

knowledge equal to 5.66% and the rest by other variables. This result also equivalents with 

Timmerman et al. (2017) study. According to Andaya (2014), self-directed learning, 

attitude towards mathematics, motivation, and time spend in learning mathematics were 

the other factors that can influence students’ success in mathematics. The results of the 

study had shown that there is a significant relationship between students’ self-concept and 

their mathematics procedural knowledge. The result could be convinced, because type of 

both data variables is not different. This result was relevant to the study of Leonard & 

Supardi (2010). They reported that students’ self-concept influence his/her mathematics 

learning outcome, because positive view, perception, and his/her confidence will improve 



 Afgani, Suryadi, & Dahlan, Undergraduate students self-concept and their mathematics procedural …  104 

mathematics learning outcome. Othman & Leng (2011) reported little different from the 

previous study. They claimed that students’ self-concept relate to his/her academic 

achievement, but weak. From our analysis, that because an academic achievement involve 

many school subjects area. In line with Leonard & Supardi, Ayodele (2011) implied that 

students’ self-concept relate to his/her mathematics performance moderately, that because 

students thought or felt about, attitude, perception to mathematics was moderately positive.  

In Seaton et al. (2014) perspective, academic self-concept has reciprocal relation 

with achievement. According to Andinny (2015), self-concept influence mathematics 

performance in form extends an opportunity to students to solve a mathematics problem. 

Jamaldini et al. (2015), and Singh (2015) also reported that students’ self-concept relate to 

his/her academic achievement in mathematics. Singh (2015) added an argumentation that 

self-concept was a consequence from high achievement. It means students’ academic 

ability influence his/her self-concept. More detail, Timmerman et al. (2017) reported that 

the correlation between math self-concept with math achievement was weak in 

measurement and relations subject and moderate in numbers and scale subject. He argued 

that students’ attitude and perception about his/her mathematical ability is a main factor of 

self-concept that influence students’ math achievement.  That means the result of this study 

supports the result of previous study, because students’ mathematics achievement can be 

observed through their mathematical abilities. One of that ability is mathematics 

procedural knowledge. In this study, it covered simplification and factorization of algebra 

form in R system, quadratic equation, inequality, absolute value, linear equation, and 

function. Nevertheless, the result also showed the correlation between both variables was 

low and incongruence. It means that student with high self-concept does not certainly have 

high mathematics achievement. This is because undergraduate students’ self-concept was 

categorized good, whereas their mathematics procedural knowledge was categorized 

adverse. In this study, most of the undergraduate students difficult to solve mathematics 

problems related to linear equation and function. 

 

4. CONCLUSION 

Based on the result of this study, we conclude that there is a significant relationship 

between self concept and mathematics procedural knowledge. Besides that, this study has a 

few limitations. First, the sample was used non-probability sampling and a number of 

samples were too limited, so the conclusion cannot be generalized to all undergraduate 

students majoring mathematics education in Palembang, Indonesia. Second, both 

instruments only valid and reliable to sample has characteristic that resembles the sample 

involved in this study. For next studies, we recommended to investigating self-concept and 

others mathematical ability or relation between mathematics procedural knowledge and 

others affective aspect to an amount of representative samples. So that, the relationship 

between affective and cognitive dimension in mathematics education can explain clearly. 

 

ACKNOWLEDGEMENTS 

Author extends gratitude to Prof. Dr. Kasinyo Harto, M.Ag. and Prof. Dr. Aflatun 

Muchtar, MA. which have given opportunity and scholarship, so that author could 

participate as student in Universitas Pendidikan Indonesia. Last but not least, author render 

thanks and gives respect very grateful to all other individuals who have supported author to 

writing this paper. 

 



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105 

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