Southeast Asia Mathematics Education Journal 

Volume 13, No 1 (2023) 

19 

 

Analysis of Metacognition Ability to Solve Mathematics Problem 

1Fani Yunida Anggraheni, 2Kismiantini & 3Ariyadi Wijaya 
1 Magister of Mathematics Education, Universitas Negeri Yogyakarta, Indonesia 

 2Departement of Statistics, Universitas Negeri Yogyakarta, Indonesia 
 3Departement of Mathematics Education, Universitas Negeri Yogyakarta, Indonesia 

1anggrahenify94@gmail.com 

 

Abstract  

In this study, two components of metacognition were examined, namely metacognitive 

knowledge and metacognitive skills. This study aims to analyse the students’ metacognitive 

abilities based on predetermined indicators, by looking at the relationship between the 

performance of metacognition knowledge and metacognition skill. The study discovers that 

the students with low, medium, and high scores perform differently. The conclusion is that 

students who have metacognition knowledge do not necessarily have metacognition skills or 

abilities. The conclusion is that students who have metacognition knowledge do not 

necessarily have metacognition skills or abilities. 

 

 

Keywords: Metacognition, Metacognition Knowledge, Metacognition Skill. 

 

 

Introduction  

Learning is a process that helps students achieve goals actively. These goals are divided into 

three areas: 1) cognitive domains in the form of intellectual knowledge and skills; 2) affective 

domains in the form of student feelings and assessments; 3) psychomotor domains in the form 

of driving or perception skills (Brookhart & Nitko, 2013). The cognitive domain is divided into 

two dimensions, namely the process of cognition and knowledge. The process of cognition 

includes remembering, understanding, applying, analysing, evaluating, and creating. On the 

other hand, the dimensions of knowledge include factual, conceptual, procedural, and 

metacognition (Anderson et al., 2021). Metacognition is one aspect that influences the learning 

process both directly and indirectly, as well as in mathematics.  

Metacognition is a combination of ‘meta’ and ‘cognition’. Meta is a prefix that means after, 

together with, or outside (National Research Council, 2005). Cognition is a subconscious, 

intuitive, and affective experience and feeling based on information processing, emotions, 

awareness, and behaviour (Rickheit & Strohner, 1998). Metacognition refers to one’s 

awareness of the process and the ability to control it (Ovan et al., 2018). Metacognition is a 

skill that can be developed by learning, practicing, and applying a successful approach (Conley, 

2014). Metacognition is defined as ‘thinking about thinking’ or ‘cognition about cognition’ 

which is the ability to self-reflect from ongoing cognitive processes, something unique to 

individuals, and which plays an important role in human consciousness (Amin & Sukestiyarno, 

2015).  

The component of metacognition can be divided into metacognitive knowledge, 

metacognitive experiences, and metacognitive skills (Efklides, 2009). Metacognitive 

knowledge is a part of the knowledge that is stored in memory as a cognitive process with 

various cognitive tasks, goals, actions, and experiences (Flavell, 1979). Metacognitive 



Analysis of Metacognition Ability to Solve Mathematics Problem 

20 

 

knowledge can also be interpreted when we store memories and then retrieve memories. It is a 

process of a task, in which we think about when, why, and what strategies can be used to 

complete the tasks that are given so that information can be sorted according to the needs 

(Efklides, 2009). Metacognitive knowledge stages consist of awareness, regulation (Hacker et 

al., 2009), and planning (Veenman et al., 2004). Awareness is an activity to receive information 

given from questions, regulation is an activity to choose and write information needed to solve 

a problem, and planning is an activity to give an idea or writing in the form of a plan to complete 

a task.  

Metacognitive experience is an intentional cognitive or the form of affective experience that 

accompanies and alludes to intellectuals (Flavell, 1979), which is defined as a form of cognitive 

monitoring when completing information related to tasks or processes. Metacognitive 

experience consists of metacognitive feelings, metacognitive judgment/estimates, and special 

knowledge of online assignments (Efklides, 2009). The metacognitive experience stages 

consist of monitoring and self-control (Baker & Brown, 2001). Monitoring can estimate the 

difficulty of a particular problem, whereas self-control is being able to determine the value of 

the completion done.  

Metacognitive skill is defined as the ability to control actions and use the right strategy when 

applying the strategy consciously and automatically by ensuring that the thinking conforms to 

what is desired and results in line with its objectives (Efklides, 2009). The metacognitive skill 

stages consist of strategies (Flavell, 1979), processes (Hacker et al., 2009), evaluations 

(Purnomo et al., 2017), and goals (Flavell, 1979). Strategies are activities that determine the 

formula or strategy used to solve the problem, the process is an activity that logically solves 

problems following the chosen strategy, and evaluation is an activity that draws conclusions 

according to the problem and reflects whether it can be solved in different ways, and the goal 

is to achieve objectives following the plan. 

Solving mathematical problems will grow the ability of metacognition knowledge and skills. 

Performing metacognition involves generating strategies to solve problems, implementing 

strategies, and checking whether the answers obtained correspond logically to the problems 

identified (Walle et al., 2019). By doing mathematics it means discovering patterns and 

relationships, thinking ways, or defining a mathematical sentence (Rahmah, 2018). This 

requires an analysis of metacognitive abilities, namely metacognitive knowledge and skills, to 

solve mathematical problems to find out how many metacognition abilities students can 

explore in solving mathematical problems. 

However, currently, the education system in Indonesia does not give sufficient attention to 

the metacognition process, especially in terms of student assessment. The assessment only 

measures work steps and results, while the process of overview and recheck is rarely done.  

Therefore, this study aims to analyse the ability of students to see work outcomes based on 

predetermined indicators and examine the relationship between the performance of 

metacognition knowledge and metacognition skill. Metacognitive knowledge includes 

regulation and planning, while metacognitive skill consists of strategies, processes, evaluating, 

and goals. Regulation is an activity in the form of observation of metacognition activities to 

control the process, for example, looking for and determining information related to the topic 

(Purnomo et al., 2017). Planning is an activity that involves thinking about the tasks, looking 

at experience, and thinking about what will happen next, for example, summarizing notes about 



Fani Yunida Anggraheni, Kismiantini, Ariyadi Wijaya 

21 

 

the steps to be taken (Larkin, 2006). Strategy, processes, evaluating, and goals are activities to 

determine patterns or related formulas, implement process structures, evaluate the process and 

examine targets (Flavell, 1979). 

 

Methods 

This research is descriptive analysis research using qualitative methods. The aim of 

qualitative research is data collection, analysis, and creation of a representation that can be 

shared with others. 

Research Design, Site, and Participants  

The research subjects are mathematics students on “Mathematics Power” subjects that are 

aimed at determining the ability of metacognition possessed in solving mathematical problems. 

The subjects consisted of 6 students with code names AR, ASM, AD, SH, PAY, and MR. 

 

 

Figure 1. Research procedures 

 

As shown in Figure 1, the initial stage in the research is developing the questions instrument. 

The questions that were asked consisted of two questions that were used to analyse the students’ 

metacognition abilities. After compiling the questions, the next step is to validate the research 

instruments by the validator and then enter the stage of data collection. Data collection was 

done by distributing the questions to students completed within a predetermined time limit. 

Table 1 shows the indicators and assessment scores of metacognition ability. 

 

Table 1  

Indicators and assessment scores of Metacognition Ability  

Components of Metacognition 

Ability 
Indicators Assessment 

Scores 

Metacognitive 

Knowledge 

Regulation Select and write down the information needed to 

solve the problem 

1 

Planning Provide an overview of the completion plan 2 

Metacognitive 

Skills 

Strategies determine the formula or strategy used 2 

Process Solve the problem logically according to the 

chosen strategy 

3 

Evaluating Make conclusions according to the problem 3 

 Recheck the questions given in a different way 1 

Goal Solve questions in accordance with the goals to be 

achieved 

1 

Data Collection and Analysis 

Data analysis is then performed after the test, which aims to describe each student’s 

metacognition abilities. Then from the analysed results, we do the categorization of 

metacognition abilities. The categorized answers are low, medium, and high levels so it is 



Analysis of Metacognition Ability to Solve Mathematics Problem 

22 

 

necessary to analyze a total of six answers. Students are categorized as ‘low’, if in they make 

errors in the regulation and planning steps in solving questions. Students are categorized as 

‘medium’ if they are correct in the regulation steps of the process but have not conducted an 

evaluation so they have not achieved the goal. Students are categorized as ‘high’ if they solve 

the questions correctly from the regulation steps to evaluating that achieves the goals. The 

conclusions are then drawn based on the result of the analysis. The questions are:  

1. It takes a boat 2.5 hours to travel down a river from point A to point B, and 3.5 hours to 

travel up the river from B to A. How long would it take the same boat to go from A to B in 

still water (minutes)? 

2. The difference between Ani’s and Budi's money is 7500. If 10% of Ani is money given to 

Budi, then Budi's money becomes 80% of Ani's original money. How much money do they 

have in total? 

 

Results and Discussion 

This section provides several examples of student's work and the analysis of their 

metacognitive knowledge and possessed metacognitive skills.  

 

Findings from Analysis of Problem 1 

Analysis of problem 2 shows the work of students with the lowest, medium, and highest 

scores. 

 

Solution: 

A→B following the current = 2.5 hours 

A→B following the current = 3.5 hours 

speed = distance/time       time = distance/speed 

A to B goes with the flow 

𝑡𝑖𝑚𝑒 =
𝑑𝑖𝑠𝑡𝑎𝑛𝑐𝑒

𝑠𝑝𝑒𝑒𝑑
  

2.5 =
𝑑

𝑠
− 𝑐  

2.5 + 𝑐 =
𝑑

𝑠
  

So
𝑑

𝑠
= 2.5 + 0.5 = 3 

B to A goes with the flow 

𝑡𝑖𝑚𝑒 =
𝑑𝑖𝑠𝑡𝑎𝑛𝑐𝑒

𝑠𝑝𝑒𝑒𝑑
+ 𝑐𝑢𝑟𝑟𝑒𝑛𝑡  

 3.5 =
𝑑

𝑠
+ 𝑐 

3.5 = 2.5 + 𝑐 + 𝑐  
3.5 − 2.5 = 2𝑐  
1

2
= 𝐴  

when going with the flow the time will decrease by half an 

hour = 30 minutes.  

When against the current the time will increase by half an 

hour = 30 minutes at the same average speed. so that if in 

calm water (without current), the distance from A to B will 

be traveled within 3 hours = 180 minutes 

Figure 2. Student AR’s solution for Problem 1. 

 

Based on the results of student AR’s solution on the process of metacognitive knowledge, 

the student did not write the required information in full accordingly and provided an overview. 

In the metacognitive skill process, a student is not yet correct in writing the formula or strategy 

used so an error occurs in the process of solving a problem. The AR student did not write other 

ways on the results of his work so the conclusions obtained show inaccurate results. The AR 



Fani Yunida Anggraheni, Kismiantini, Ariyadi Wijaya 

23 

 

student failed to complete the questions in line with the goals that should be achieved. Then 

the score obtained by students is 5.  

 

 

Solution: 

A→B 

B→A 

2.5 hours = 150 minutes 

3.5 hours = 210 minutes 

s
v

t
 =  

boat speed

v current speed

 distance

p

a

v

s

=

=

=

 

A B →  ...(1)
150

p a

s
v v+ =  

B A −  ...(2)
210

p a

s
v v− =  

of 1 and 2 obtained 

150

210

p a

p a

s
v v

s
v v

+ =

− =

 

185

3150
p

v =  

1
...(3)

175
s=  

2
150 210

1

2 150 210

p

p

s s
v

s s
v

= +

 
= + 

 

 

from equation 3 obtained 

175

175
175 minutes

1

p

s s
v

t

s
t

s

= =

= =

 

Figure 3. Student ASM’s solution for Problem 1. 
 

He wrote down VAB = VP + VA, VBA = VP - VA and drew a graphic form as a plan to be 

completed. In the metacognitive skills process, he wrote the process of solving a problem can 

be logically solved. However, the ASM student did not recheck the results of the work he 

obtained in other ways, so the answer he gets is a single one. He did not write the conclusions 

he obtained from a settlement. Based on the results of the work obtained, the question was 

completed by AR following the goals that should be achieved but did not show the evaluation 

process. The evaluation process that has not been carried out does not re-check the results of 

work in other ways and does not draw conclusions. Then the score obtained by students is 9. 



Analysis of Metacognition Ability to Solve Mathematics Problem 

24 

 

 

Solution: 

known: t (trip from A to B) = 2.5 hours 

t (trip from A to B) = 2.5 hours 

let : boat speed = x 

 boat current = y 

asked: how long on the same boat going from A to B 

answer: .s v t= → we already know in physics 

( ) ( )

, ,

2.5 3.5

2.5 2.5 3.5 3.5

2.5 3.5 3.5 2.5

6

6

6

A B A B B A B A
v t v t

x y x y

x y x y

x x y y

x y

x y

x
y

→ → → →
=

+ = −

+ = −

− = − −

− = −

=

=

 

 

 

.
s

s v t t
v

= → =  

to find out how long on the same boat going from A to B, 

we use the formula st
v

=  

( ) 2.5

2.5
6

6
2.5

6

7
2.5

6

7 5 35 11
2 2 hours 55 minutes

6 2 12 12

s
t

v

x y
t

x

x
x

t
x

x x

x

=

+
=

 
+ 

 
=

+
= 

= 

=  = = =

 

Figure 4. Student AD’s solution for Problem 1. 
 

Based on the results of the work of student AD’s solution to the process of metacognitive 

knowledge, she wrote the required information in full accordingly and provided an overview 

of the complete plan. The plan is to write down the speed when assisting with the flow and not 

the flow. In the metacognitive skill process, she wrote the exact strategies used to obtain a 

reasonable answer. The AD student re-check the results of the work that she obtained by 

making statements about the results that she obtained by comparing if influenced by the flow. 

She also drew conclusions from the settlement that she obtained. Based on the results of the 

work obtained, The AD student completed the questions in accordance with the goals that 

should be achieved and met the completion criteria in accordance with the ability of 

metacognition. Then the score obtained by students is 13.  

 

 

 

This is logical when the boat 

length from A to B is 2 hours 55 

minutes because it means the 

journey from A to B is assisted by 

the current to 2.5 hours, without 

being assisted 2 hours 55 minutes 



Fani Yunida Anggraheni, Kismiantini, Ariyadi Wijaya 

25 

 

Findings from Analysis of Problem 2 

Analysis of problem 2 shows the work of students with the lowest, medium, and highest 

scores. 

 

 

Figure 5. Student SH’s solution for Problem 2. 

 

Based on the results of the work of student SH’s solution to the process of metacognitive 

knowledge, the student did not write the required information in full as per the questions. The 

SH Student made plans by writing the initial clues of B + (10%)A = (80%)A and A – B = 7500. 

In the metacognitive skill process, the student wrote the formula or strategy used correctly so 

that the process of solving a problem can be s logically solved. However, the SH student did 

not recheck the results of the work he obtained and she did not conclude the completion she 

obtained. Based on the results of the work that the SH student obtained, the problem was 

completed in accordance with the objectives that should be achieved. However, she did take 

all the completion steps such as not writing the required information, not writing other 

completion steps as evidence of completion and not concluding the results. The score obtained 

by students is 9.  

 

 

Solution: 

Known: let: Anis’s money = x 

 Budi’s money = y 
7500...(1)

10% 80%

0.1 0.8 ...(2)

x y

x y x

x y x

− =

+ =

+ =

 

Asked: the amount of their money…? 

The answer: 

from equations 1 and 2 are obtained 
7500

0.1 0.8

x y

x y x

− =

+ =
 

7500 25000

  17500

y = +

=

 

so the total amount of 

their money  
25000 17500

       42500

x y+ = +

=

 

so the amount of their 

money Rp42.500 

1.1 7500 0.8

1.1 0.8 7500

0.3 7500

7500
     25000

0.3

x x

x x

x

x

= +

− =

=

= =

 

 

Figure 6. Student PAY’s solution for Problem 2. 



Analysis of Metacognition Ability to Solve Mathematics Problem 

26 

 

 

Based on the results of the work of student PAY’s solution on the process of metacognitive 

knowledge, the student completed the information required and wrote a completion plan in the 

form of writing equation 1 and equation 2. In the metacognitive skill process, the student wrote 

the formula or strategy used to solve a problem logically. However, the PAY student does not 

re-check the results of the work she obtained in such a way that the completion conclusion was 

obtained without re-checking. Based on the results of the work obtained, the PAY student 

completed the questions in accordance with the objectives to be achieved but did not check 

other solutions to the questions in the form. Then the score obtained by students is 12.  

 

 

 

Solution: 

The difference between Ani's and Budi’s money is 7500. 

Then Budi’s money becomes 80% of the original money. 

How much money? 

7500A B− = this means A > B (Ani has more money 
than Budi) 

Anis’s money 10%A=  of Ani’s money is given to 

Budi and Anis’ money 10%A A= −  

The Budi’s money B= because Budi gets an additional 

10% of Anis’s money, Budi’s money 10%B A= +  
There is a statement: 

Budi’s money = 80% of Anis’s original money 

Now: 10% 80%B A A+ =  

Obtained: 70% 75000B A A B=  − =  
70% 7500

30% 7500

30
7500

100

25000

7500

7500

25000 7500

17500

A A

A

A

A

A B

A B

B

B

− =

=

=

=

− =

− =

− =

=

 

So their money  

= A+ B 

= 25000+17500 

= 42500 

2nd way 
70%

70%
Then 

100%

7500

 

100% 70%
7500

100% 70%

170%
        7500

30%

        42500   

B A

B

A

A B

So

A B

=

=

 − =

+
+ = 

−

= 

=

 

 

 

Figure 7. Student MR’s solution for Problem 2. 

 

Based on the results of the work of student MR’s solution on the process of metacognitive 

knowledge, the student wrote down the required information in full according to the questions 

and drew up a plan for systematically solving it. In the metacognitive skill process, the student 

wrote a formula or strategy used appropriately so that the process of solving problems can be 

logically solved. The MR student rechecks his work by using a different way to find the results. 

Thus, it is obtained that the previous answer with the second way is the same. Based on the 

results of the work obtained, the MR student completed the questions in accordance with the 

goals to be achieved and met the completion criteria according to the metacognition ability. 

Then the score obtained by students is 13.  



Fani Yunida Anggraheni, Kismiantini, Ariyadi Wijaya 

27 

 

Based on the above description of students’ solutions, there is a noticeable difference in the 

students’ metacognitive abilities. Moreover, a study also stated that mathematics learning 

students have different levels (Lestari et al., 2019). The level consists of levels students read, 

wrote, and determined the strategy. Medium-level students planned and corrected the mistakes, 

while high-level students implement the best strategies, analyze, and represent. The research 

by Izzaati and Mahmudi (2019) also showed different levels of metacognition that students 

with medium and low levels did not well aspects of planning, monitoring, and evaluating 

compared to high levels. Blumer and Keton’s (2014) research discussed that with high 

metacognition abilities, it will have high performance. Meanwhile, Amin and Sukestiyarno 

(2015) showed that students’ metacognition abilities related to cognitive skills. The ability of 

metacognition will affect metacognition skills, students who have high metacognition abilities 

will have high metacognition skills.  

Metacognition knowledge and metacognition skills are two aspects that are interrelated and 

important in the learning process (Hartman, 2001). Students’ metacognitive skills are 

influenced by their knowledge. Students lacking the ability of metacognitive knowledge, the 

ability of students is metacognitive skills will be wrong too, and the ability of metacognitive 

knowledge is thus very influential on the ability of metacognitive skills.  

 

Conclusion 

This is evident in student work outcomes where all aspects of metacognition abilities are 

met by the lowest, medium and highest students. As far as metacognitive knowledge ability is 

concerned, namely in the regulatory aspect, students can determine the information in the 

problem but if the strategy used is wrong or wrong then the next process is also wrong. Another 

drawback is that students often do not double-check with different methods or ways to ensure 

the results are met.  

The limitations in this study are the relatively small subjects and there are only two problems 

in the study. Further research is suggested to include a sufficient number of subjects and several 

problem models. Despite the limitations, this research is expected to contribute to the studies 

on metacognition. 

 

Acknowledgements 

The researchers would like to thank those who helped in the process of completing the 

article.  

 

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