Open Access proceedings Journal of Physics: Conference series


Southeast Asian Mathematics Education Journal 

Volume 12, No. 1 (2022) 

65 

 

Didactical Transposition within Reflective Practice of an Indonesian Mathematics 

Teacher Community: A Case in Proving the Pythagorean Theorem Topic 

1
Rudi Rudi, 

2
Didi Suryadi, & 

3
Rizky Rosjanuardi 

1
Lembaga Penjaminan Mutu Pendidikan Sulawesi Selatan, Makassar, Indonesia

 

2, 3
Pendidikan Matematika, Universitas Pendidikan Indonesia, Bandung, Indonesia 

Email: 
1
rudi.math@upi.edu  

 

Abstract 

Didactical transposition plays a pivotal role in implementing reflective practice of a 

mathematics teacher community. Didactical transposition is a systematic approach to examine 

and enhance learning materials. Didactical transposition within reflective practice is 

conducted collaboratively between teacher trainers and teacher participants to produce an 

effective didactical design in encountering student learning obstacles. Thus, the objective of 

this study is to portray didactical transposition process accomplished by teacher trainers and 

teacher participants in the implementation of teacher reflective practice in the community. 

This study employed a methodological framework known didactical design research. 

Didactical design research in accordance with a reflective framework consists of four phases 

which are preparation, design/reflective planning for action, design/reflective implementation 

in action, and design/reflective evaluation and reflection after action. Research participants 

encompassed a teacher trainer, thirteen teachers, and thirty students. Data collection 

procedures were completed by employing observation and documentation. This study resulted 

in a didactical design which was obtained through a didactical transposition process 

performed by teacher and teacher trainer participants. The study discovered that didactical 

design developed collaboratively through didactical transposition within reflective practice in 

community was proven effective in overcoming the obstacles of student learning due to 

learning materials. Research findings are expected to be a model of professional learning for 

mathematics teachers in the community. 

Keywords: Didactical transposition, reflective practice, mathematics teacher community, proving Pythagorean 

theorem.   

 

Introduction 

One of existing problems in mathematics learning is students’ difficulty. Several empirical 

studies uncovered that one of causes in students’ learning difficulty while learning 

mathematics is didactical obstacles (Carvalho, Silva, Lima, Coquet & Clément, 2004; Elia, 

Özel, Gagatsis, Panaoura & Özel, 2016). Other research findings revealed that teachers 

encounter difficulties in dealing with students’ didactical obstacles (Rudi, Suryadi, & 

Rosjanuardi, 2020 a, 2020b; Kuzniak & Rauscher, 2011). Didactical obstacles occur due to 

learning materials, curriculum, and design utilised by teachers (Brousseau, 2006; Artigue, 

Haspekian, & Corblin-Lenfant, 2014). Therefore, it is considered significantly required to 

ensure that mathematical knowledge encompassed in a learning design and delivered by 

teachers in a classroom is aligned with curriculum and scholarly knowledge.  

The didactical transposition concept is in accordance with a belief that knowledge requires 

transformation to be effectively applied for classroom teaching objectives. Didactical 

transposition emerged from the assumption that knowledge was initially invented not to be 

taught to someone else but to be utilized for purposeful ends (Kang & Kilpatrick, 1992) 

mailto:rudi.math@upi.edu


Didactical Transposition within Reflective Practice of an Indonesian  

Mathematics Teacher Community: A Case in Proving the Pythagorean Theorem Topic 

66 

 

causing knowledge to transform after undergoing a process of selection, design, production, 

and teaching in an educational institution (Chevallard & Bosch, 2020).  

The term ‘didactical transposition’ was initiated by Chevallard (1989). Chevallard and 

Bosch (2020) defined that didactical transposition encompasses four phases which are 

scholarly knowledge, knowledge to be taught, taught knowledge, and learned/available 

knowledge. The didactical transposition process possesses a vital role in the administration of 

a mathematics education program (Winslow, 2011; Arzarello, Robutti, Sabena, Cusi, Garuti, 

Malara, Martignone, 2014), in which, the mathematics education program prepares teacher 

candidates and builds the professionalism of in-service mathematics teachers.  

Reflective practice in community is a form of professional learning for in-service 

mathematics teachers. Referring to the framework of reflective practice by Grushka (2005), 

three stages of reflective practice are elaborated; reflection on action, reflection in action, and 

reflection for action. Regarding to the three stages, lesson study is a form of teacher 

professional learning implementing these reflective practice stages.  

Didactical transposition occupies a considerable position in implementing reflective 

practice by teacher communities. Didactical transposition is a systematic approach to 

scrutinize and develop learning materials (Artigue, 1994). Didactical transposition allows the 

teachers to examine whether learning materials conducted by teachers in the classroom are 

valid from the perspectives of learning design, students’ condition, curriculum and 

mathematical scholarly knowledge (Bosch & Gascón, 2006). Didactical transposition also 

enables the teaching practitioners to analyse whether teachers’ knowledge on learning 

materials is associated with scholarly knowledge (Arzarello et al., 2014). If mathematical 

knowledge acquired by students and teachers has been justified to be in accordance with 

scholarly knowledge and curriculum, it is expected that the obstacles and difficulties of 

students’ learning affected by learning materials can be reduced (Jamilah, Suryadi & Priatna, 

2020).  

One of problems associated with community reflective practice in Indonesia is that it has 

not yet been placed its concern on students’ learning obstacles and difficulties (Saito, Harun, 

Kuboki, Tachibana, 2006), hence, a method dealing with students’ learning obstacles and 

difficulties has not yet been discovered (Suratno, 2012). Learning material analysis and 

development through a teacher reflective practice community provides as an attempt not only 

in dealing with students’ learning obstacles and difficulties but also to enhance teachers’ 

knowledge in overcoming the obstacles and difficulties of students’ learning (Rudi, Suryadi 

& Rosjanuardi, 2020a, 2020b). Didactical transposition of reflective practice in mathematics 

teacher is expected to provide solutions to the current problems of reflective practice in 

mathematics teacher communities in Indonesia.  

Several empirical studies have implemented didactical transposition in examining 

mathematics education program. After Chevvallard initiated didactical transposition in 

mathematics education, Arzarello et al. (2014), developed Chevallard’s ideas into meta-

didactical transposition theory. The framework is applied in analysing didactical transposition 

process perceived from institutional dimension that is the university as a knowledge-

production institution and the school as knowledge-user institution. Then, Gilles (2020) 

implemented this theoretical framework in establishing collaboration between researcher and 

teacher community. Meanwhile, Shinno and Yanagimoto (2020) elaborated on the 



Rudi Rudi, Didi Suryadi, & Rizky Rosjanuardi 

67 

 

affirmative values of collaboration between pre-service and in-service teachers. Hausberger 

(2017) investigated the homomorphism concept in didactical transposition performed in 

university whereas Jamilah et al. (2020), scrutinised the didactical transposition within the 

education of mathematics pre-service teacher.  

However, the existing empirical studies on didactical transposition have not yet 

determined the method of didactical transposition process administered in a mathematics 

teacher community for reflective practice. In previous research, investigation of didactical 

transposition was more oriented towards researchers’ perspectives as the university 

representatives and teachers’ perspectives as school representatives. Meanwhile, in this study, 

the researchers were replaced by teacher trainers from a teacher competency development 

institution in Indonesia of which the major responsibility is facilitating the enhancement of 

education quality in Indonesia. The teacher trainer in this particular case was performed by 

widyaiswara or civil servants who are educating and training in-service teachers in Indonesia.  

The objective of this research is to identify the didactical transposition process of 

reflective practice in a mathematics teacher community. Didactical transposition was 

conducted by a teacher trainer and teacher participants in the community. In this study, an 

investigation of didactical transposition concerned on proving the Pythagorean theorem. The 

selection of this topic was in accordance with the fact which substantiating the Pythagorean 

theorem was considered the most difficult topic for students (Zaskis & Zaskis, 2016). As 

elaborated in the Indonesian mathematics curriculum for junior high school level, proving the 

Pythagorean theorem is the only basic competence which requires students to prove 

something. 

 

Methods 

This study employed methodological framework of didactical design research (DDR) 

developed by Suryadi (2015) and Suryadi, Prabawanto & Takashi (2017). DDR functions as 

a theoretical and methodological framework in implementing reflective practice. Suryadi, et 

al. (2017) broke down reflective practice into three stages based on the DDR framework. The 

three stages encompass prospective analysis (reflection for action) in the form of hypothetical 

didactical design, metapedadidactic analysis (reflection in action), and retrospective analysis 

(reflection after action). The three stages were developed by Rudi et al. (2020a, 2020b) by 

adding a stage which is reflective practice preparation. The application of the DDR 

methodological framework was due to a perspective that DDR functions to overcome 

students’ difficulty and update teachers’ knowledge through reflective practice (Rudi et al., 

2020a, 2020b). 

Research participants encompass a teacher trainer, thirteen mathematics teachers in junior 

high school also as members of a mathematics teacher community in a regency in South 

Sulawesi Province, Indonesia, and thirty students of grade eight in a state junior high school 

in Indonesia. Those participants were purposively selected. 

Data collection procedures were accomplished through a teacher trainer’s journal, 

observation, and document study. Data on scholarly knowledge and knowledge taught were 

collected from the teacher trainer’s journal. Meanwhile, data on taught knowledge and 

available/learned knowledge of the teacher trainer were obtained from observation towards 



Didactical Transposition within Reflective Practice of an Indonesian  

Mathematics Teacher Community: A Case in Proving the Pythagorean Theorem Topic 

68 

 

the learning process of mathematical content knowledge reinforcement performed by teacher 

participants in the community. Information in all stages of didactical transposition acquired 

by participants was gathered by employing observation techniques toward the learning of 

teacher participant in the community, while data on taught knowledge and available/learned 

knowledge of teacher participants were collected through observation during the learning 

process implementing the design.  

 

Results and Discussion 

Didactical Transposition by the Teacher Trainer  

The didactical transposition process by the teacher trainer employed the four stages 

developed by Chevallard (1989, 1992) encompassing scholarly knowledge, knowledge to be 

taught, taught knowledge, and learned/available knowledge.  

Scholarly knowledge is scientific knowledge enhanced and designed by university or other 

scientific institutions. Scholarly knowledge is available in reputable research results sections 

of journals, and books. The teacher trainer was accessing scholarly knowledge on proving 

Pythagorean theorem topic in literature such as books, articles, and scientific reviews from 

reputable scientific journals in digital form. Dissemination of the research findings as the 

university products in digitalisation has been progressing and becoming trends in various 

countries (Saarti & Tuominen, 2020; Moeini, Rahrovani & Chan, 2019). 

 

 

 

 

 
 

Figure 1. Didactical transposition in the implementation of reflective practice in a teacher 

community  
 

PREPARATION FOR REFLECTIVE PRACTICE 



Rudi Rudi, Didi Suryadi, & Rizky Rosjanuardi 

69 

 

Didactical transposition completed by the teacher trainer at the scholarly knowledge stage 

functioned to ensure that materials provided to teachers were in accordance with scholarly 

knowledge (Figure 1). At this stage, the teacher trainer implements didactical transposition to 

examine the used knowledge (Atalar & Ergun, 2018).  

Elisha Scott Loomis (1852-1940) gathered 371 methods of evidence and compiled them in 

a book published in 1927 (Ratner, 2009). Apart from Loomis’s book, there have been other 

books elaborating methods for proving the Pythagorean theorem. However, most of the books 

cite Loomis’s ideas. Not only in the form of books, but other proving methods are also 

published in the form of articles in reputable journals. According to a reprinted book on 

Loomis (1968), four types of methods can be applied in proving the Pythagorean theorem 

comprising of algebra proving which implements linear equation method, geometry proving 

which performs comparison of the area of geometric shapes, quaternionic proving applying 

vector operation, and dynamic proving concerning the correlation between mass and speed.  

The result of didactical transposition on the teacher trainer’s knowledge to be taught is 

displayed in Figures 2 and 3 below. 

 

 

 

 

 

 

 

 

Figure 2. Result of Didactical Transposition on the Knowledge to be Taught of Chou-pei 

Suan-ching Proving (Veljan, 2000). 

 

 

 

 

 

 

 

 

 

 

Figure 3. Result of Didactical Transposition on Knowledge to be Taught of James A. 

Garfield Proving (Veljan, 2000). 

Knowledge to be taught is a scholarly knowledge process resulting in curriculum-based 

knowledge (Bosch, & Gascón, 2006). Knowledge to be taught can be acquired through a 

literature review from textbooks (Jamilah, et al., 2020). In this research, the teacher trainer 

employed textbooks published by the teacher competency development institution in 

Indonesia. This fact unveils the institutional role within the reflective practice of teacher 

community. This idea is in accordance with the perspectives proposed by Chevallard (1992) 

            
  

 
 

          



Didactical Transposition within Reflective Practice of an Indonesian  

Mathematics Teacher Community: A Case in Proving the Pythagorean Theorem Topic 

70 

 

and Arzarello, et al. (2014), which asserted the significance of the institutional dimension in 

the development process of the mathematics education program.  

Regarding the teacher trainer’s analysis, it was presented that the proving methods by 

employing geometry and algebra were correlated with the curriculum and textbooks 

developed during the agenda of material reinforcement. The four proving methods were 

obtained from Bhaskara, Chou-pei Suan-ching, Tsabit Ibnu Qurra, and James A. Garfield. 

Chou-pei Suan-ching and James A. Garfield proving methods are displayed in the following 

Figures 4 and 5.  

The result of the didactical transposition accomplished by the teacher trainer on the taught 

knowledge as presented in Figure 4, the algebra proving of Chou-pei Suan-ching was 

encountering transposition to be a geometry proving. The teacher trainer provided different 

colors to the four right triangles. This idea tended to make the teacher participants easier in 

comprehending the shift/movement of the right triangles. Based on the result of didactical 

transposition in Figure 5, the teacher trainer produced a right triangle beside the trapezium. 

The result of the didactical transposition on taught knowledge becomes the basis in designing 

scaffolding for the teacher trainer and follow-up for teacher participants who possessed 

issues. 

 

 

 

 

 

 

Figure A  Figure B 

 

 

Figure 4. Result of Didactical Transposition on Taught Knowledge, 

Chou-pei Suan-ching Proving 

 

 

 

 

 

 

 

 

 

Area of trapezium method I = Area of triangle I + Area of 

triangle II + Area of triangle III 

Area of triangle I = ½ x a x b 

Area of triangle II = ½ x a x b  

(triangle II =triangle I) 

Area of triangle III = ½c x c = ½c
2
 

Meaning that area of trapezium I  

= ½ x a x b + ½ x a x b + ½ x c
2 

(axb = ab) 

= ½ (2 ab + c
2
) 

Area of trapezium method II  

= ½ (a+b) (a+b)  

= ½ (a+b)
2         

     

= ½ (a
2
+2ab+b

2
) 

Area of trapezium I =  

Area of trapezium II 

=> ½ (2 ab + c
2
) = ½ (a

2
 + 2ab + b

2
)   

(2 ab + c
2
) = (a

2
 + 2ab + b

2
)   

c
2
 = a

2
 + b

2
 (proven) 

Figure 5. Result of Didactical Transposition at the Taught Knowledge Stage  

Method 1 

The area of the rectangle in Figure A is the same as the area 

of the rectangle in Figure B. The area of the white rectangle 

in Figure A is the same as the area of the two white 

rectangles in Figure B. The area of the white rectangle in 

Figure A with c side is c
2
. The area of white rectangle in 

Figure B with a and b side is a
2
+b

2
.  

Hence, the conclusion is a
2
+b

2
 = c

2 

Method 2 

Area of square in fig.A = (a+b)2…..(1) 
The area of square in fig.A consists of 4 triangles = c

2
+4. ½ 

(a.b) …. (2) 

From (1) and (2), we can deduce: 

a
2
+2ab+b

2
 = c

2
+2ab, or 

 a
2
+b

2
 = c

2
 

 

 



Rudi Rudi, Didi Suryadi, & Rizky Rosjanuardi 

71 

 

Knowledge acquired as taught knowledge stage was implemented in the form of teaching 

materials which were employed in the material reinforcement activity. Not only did the 

teacher trainer assure the concordance of the materials with the scholarly knowledge, but 

he/she is also required to certify that those materials had been conformed to the teachers’ 

social environment and condition. During the reflective practice, the role of teacher trainer is 

associating scholarly knowledge and teacher characteristics (Szűcs, 2018). This proposition is 

also embedded in the idea that teachers must possess three types of basic knowledge when 

teaching consisting of mathematical knowledge, mathematical knowledge for teaching, and 

pedagogical knowledge (Sullivan, 2008). 

Learned/available knowledge was the didactical transposition stage based on the teacher 

participants’ knowledge produced during the learning process. Teacher participants 

responded to the situational design of Chou-pei Suan-ching proving by employing the 

geometry proving (Figure 6) and the algebra proving method (Figure 7). Meanwhile, teacher 

participants’ responses towards proving by James A. Garfield were comparable to the 

knowledge to be taught stage (Figure 8). The result of the didactical transposition of 

learned/available knowledge by the teacher trainer and the teacher participants is illustrated 

on the following Figures 6, 7, and 8.  

 
 

 

 

 

 

 

 

See Figure 1 and 2. 

The white area in Figure 1 is equal to 

white area in Figure 2. 

*The white area in Figure 1 is c
2
… (1) 

*The white area in Figure 2 is a
2
 + b

2
 

… (2) 

As the white area in Figure 1 and 2 are 

the same, equation from (1) and (2) is 

formulated as followed: 

C
2
 = a

2
 + b

2 
(proven) 

Figure 6. Result of Didactical Transposition at the Learned/Available Knowledge Stage 

 

 

 

 

 

 

 

 

 

Area of white rectangle = Area of white rectangle - 

Area of 4 triangles in Figure 2  

                     s 

               
 

 
    

                  
         

 

Figure 7. Result of Didactical Transposition at the Learned Available/Knowledge Stage  

 



Didactical Transposition within Reflective Practice of an Indonesian  

Mathematics Teacher Community: A Case in Proving the Pythagorean Theorem Topic 

72 

 

 

 

 

 

 

 

 

 

 

 

 

 

Area of trapezium ABCD= Area of triangle 

ABC + area of triangle CBE + area of triangle 

BED 

  
         

 
 
  

 
 
  

 
 
  

 
 

  
          

 
 
        

 
 

  
             

 
 
      

 
 

  
           

 
 
      

 
 

                   
           (proven) 
              

Figure 8. Result of the Teacher Participants’ Work in Didactical Transposition at the 

Learned/Available Knowledge Stage 

 

Didactical transposition accomplished by the teacher trainer in this research concentrated 

more on the development of university-constructed materials rather than on knowledge 

construction. Institutionally, the teacher trainer played a more significant role in completing 

duties and functions in the teacher competency development institution, compared to 

researchers accomplishing duties and functions in the university institution. This finding is 

unlike meta-didactical praxeology ideas which organise the researcher community as the 

representatives of university institutions (Taranto, Robutti & Arzarello, 2020). Meta-

didactical praxeology is a stage in investigating a Mathematics education program by 

implementing theoretical framework of meta-didactical transposition (Arzarello et al., 2014). 

 

Didactical Transposition by Teacher Participants  

Similar to the didactical transposition administered by the teacher trainer, the elaboration 

on the didactical transposition by teacher participants also adhered the four steps enhanced by 

Chevallard (1989) which consist of scholarly knowledge, knowledge to be taught, taught 

knowledge, and learned/available knowledge.  

Teacher participants performed didactical transposition at the design planning as reflection 

for action, the design implementation as reflection in action, and the evaluation of design 

reflection as reflection after action. Reflection for action (design planning) development of 

hypothetical learning trajectory (knowledge to be taught) was conducted through hypothetical 

didactical design development in overcoming students’ learning difficulties and obstacles 

(taught knowledge). Reflection on action (design implementation) was implemented through 

content knowledge analysis understood by students (learned/available knowledge). Reflection 

after action (design evaluation) was applied through investigation on taught knowledge and 

learned/available knowledge to produce empirical didactical design.  

Teacher participants elevated their scholarly knowledge during the material reinforcement 

agenda. This agenda was as a part of the reflective practice preparation in the teacher 

community. Previous discussion asserted that the material reinforcement is included in the 

learned/available knowledge stage in the didactical transposition conducted by teacher 

trainers. Therefore, the learned/available knowledge in the teacher trainer’s didactical 

transposition also functioned as the scholarly knowledge.  



Rudi Rudi, Didi Suryadi, & Rizky Rosjanuardi 

73 

 

Didactical transposition process at the knowledge to be taught step was accomplished by 

teacher participants while generating the hypothetical learning trajectory. In this meeting, 

teacher participants were discussing the learning objective, instructional theory, and its 

supporting activities. The formulation of activities was expected to acquire the learning 

objectives by concerning the local instructional theory plot. This idea is based on a 

perspective that research and curriculum development in mathematics education are 

intercorrelated and integrated, employing varied methodologies, considering correlation 

between children’s tasks and thoughts, and performing various learning trajectories 

(Clements & Sarama, 2004). An investigation of hypothetical learning trajectory correlates 

the knowledge development with pedagogical aspects such as the learning methodology 

(Simon & Tzur, 2004). This stage belongs to one of the lesson studies stages designed by 

Suratno (2012).  

 

 

 

 

 

 

 

 

 

 

Figure 9. Formulation of local instructional theory in proving the Pythagorean Theorem  

 

As presented at the formulation of the local instructional theory in Figure 9, teacher 

participants experienced didactical transposition while generating assumptions on student 

learning trajectory. The didactical transposition conducted by the teacher participants towards 

Scholarly Knowledge when proving the Pythagorean theorem contained transformation on 

shapes from still to moving images through learning multimedia or puzzles. In proving the 

method by James A. Garfield, the teacher participants also provided different colours to the 

three right triangles constructing the trapezium.  

The teacher participants’ didactical transposition at the taught knowledge stage was 

conducted when codifying the hypothetical didactical design. At this stage, the teacher 

participants developed the situational design, the prediction of students’ response, and the 

teacher anticipative prediction or assistance. The didactical transposition at the taught 

knowledge stage concentrated on the integration of the teacher participants’ content 

knowledge in accordance with the student learning difficulties and obstacles. The designing 

process is required to accommodate mathematical and didactical knowledge incorporating 

cognitive, interactional, and mediational aspects (Pino-Fan, Assis & Castro, 2015). At this 

stage, the material design is devised by adhering to the triangle interaction among teacher, 

material, and student (Rudi et al., 2020b). The formulation result of hypothetical didactical 

design accommodates situational design, student response, and assistance prediction, 

teachers’ follow-up.  

Students’ worksheets illustrated in Figures 10 and Figure 11 presented that the outcome of 

students’ knowledge construction was similar to what teachers possessed. Nevertheless, there 

PROVING PYTHAGOREAN THEOREM AND TRIPLES 

Puzzle PowerPoint 

media 

Algebra Proving Geometry 

Proving 

Algebra 

Proving 

Geometry 

Proving 



Didactical Transposition within Reflective Practice of an Indonesian  

Mathematics Teacher Community: A Case in Proving the Pythagorean Theorem Topic 

74 

 

was a difference in conducting the mathematical representation. Variety also appeared when 

students performed the process of proving the theorem by employing their own words. 

Students applied different language unlike the teachers’ prediction. It implied that the 

developed didactical design was adequately effective to overcome students’ learning 

difficulties and obstacles. It is corroborated by other research findings which state that the 

hypothetical learning trajectory increases teachers’ professionalism (Ekawati, Wintarti & 

Kurniasari, 2020; Ivars, Fernández, Llinares & Choy, 2018), and didactical design developed 

by concerning the hypothetical learning trajectory is effective enough to overcome students’ 

learning difficulties and obstacles (Diana & Suryadi, 2020).  

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 10. Students’ Worksheets at the Learned/Available Knowledge Didactical 

Transposition Stage 

5. Determine the area of the white rectangle in Figure 1 

and white rectangle in Figure 2. 

Area of white rectangle in Figure 1:  

c x c = c
2
 

Area of white rectangle in Figure 1:  

a x a = a
2
 

b x b = b
2
 

6. Determine the correlation between the area of white 

rectangle in Figure 1 and the two white rectangles in 

Figure 2. 

(answer) The area of rectangle in Figure 2 are the same, 

but in Figure 2, the rectangle is divided into 2. 

7. Explain in your own words how the above process 

proves that the squared hypothenuse side owns the 

same value as the total of the other squared sides.  

c
2
= a

2
 + b

2 

 

1. Take a look carefully at the PowerPoint display 

presenting the shifting movement of the four congruent 

right triangles. 

2. Based on the display, the shifting process can be 

illustrated in the following Figures. 

3. Determine the area of rectangle in Figure 1 and Figure 2. 

Area of rectangle in Figure 1: 

c x c 

Area of rectangle in Figure 2: 

b
2
 + a

2 

4. Find the area of the 4 triangles in Figure 1 and 4 triangles 

in Figure 2. 

Area of 4 triangles in Figure 1: 

½ x a x t 

½ x b x a x 4 

Area of 4 triangles in Figure 2: 

2 x b x a = 2ab 

 

 



Rudi Rudi, Didi Suryadi, & Rizky Rosjanuardi 

75 

 

Mathematical content knowledge is an essential component that teachers should acquire. 

This knowledge plays a pivotal role in developing instructional activities. Without reliable 

mathematical content knowledge, it is difficult to enhance other knowledge components 

(Rudi et al., 2020a). Hence, the design of reflective practice in this research accommodates 

material reinforcement as one of reflective practice preparations. It is different from the 

lesson study model developed by Suratno (2012) and Sari, Suryadi and Syaodih (2018) which 

does not include content knowledge reinforcement of teacher participants. The didactical 

transposition in the reflective practice established in this research refines the PMRI learning 

environment-based lesson study which emphasises the pedagogical aspect (Fauziah & Putri, 

2020).  

 

Figure 11. Students’ Worksheets at the Learned/Available Knowledge Didactical 

Transposition Step 

  

Conclusion 

Didactical transposition in the mathematics teacher community for reflective practice was 

accomplished by the teacher trainer and teacher participants. The teacher trainer involved in 

the didactical transposition practice formulated materials during the material reinforcement 

activities for mathematics teachers. Meanwhile, teacher participants conducted didactical 

transposition at the design planning as reflection for action, the design implementation as 

reflection in action, and the evaluation of design reflection as reflection after action.  

The didactical transposition in the mathematics teacher community for reflective practice 

implementing didactical design research was effective in overcoming the student learning 

obstacles. During the implementation of reflective practice, the teacher trainer and the teacher 

participants collaboratively developed the learning material design by referring to students’ 

learning obstacles. Collaboration between the teacher trainer and the teacher participants in 

the reflective practice is inseparable from the institutional dimension role. In this case, 

institution refers to the institution of teacher competence development as the agency housing 

teacher trainers and the schools as the agency accommodating teacher participants.  

 

 

 

 

 

 

 

 

 

 
    

 

 
   

 

 
    

 

 
      

 

 
   

    
 

 
    

 

 
      

 

 
   

 

 
    

 

 
   

 

 
   

         

 

 

 

Area of Triangle I, II, and III is equal to 

= L1 + L2 + L3 = area of trapezium 

 

 

 

 



Didactical Transposition within Reflective Practice of an Indonesian  

Mathematics Teacher Community: A Case in Proving the Pythagorean Theorem Topic 

76 

 

The didactical transposition in the mathematics teacher community for reflective practice 

established collaboration between teacher trainers and teacher participants to enhance 

mathematical and didactical knowledge of the mathematics teachers in effectively 

overcoming students’ learning obstacles and difficulties.  

Acknowledgements 

Deep gratitude is addressed to the Indonesia Endowment Fund for Education (Lembaga 

Pengelola Dana Pendidikan – LPDP) Ministry of Finance, Republic of Indonesia for 

providing funds for this research. We express sincere appreciation to the Mathematics 

Teacher Community in Takalar Regency and students of Takalar Junior High School, who 

were willing to be participants for this research.  

 

References 

Arzarello, F., Robutti, O., Sabena, C., Cusi, A., Garuti, R., Malara, N., & Martignone, F. 

(2014). Meta-didactical transposition: A theoretical model for teacher education 

programmes. In A. Clark-Wilson, O. Robutti, & N. Sinclair (Eds.), The mathematics 

teacher in the digital era (pp. 347–372). Springer, Dordrecht. 

https://doi.org/10.1007/978-94-007-4638-1_15 

Artigue, M. (1994). Didactical engineering as a framework for the conception of teaching 

products. Didactics of Mathematics as a Scientific Discipline, 13, 27–39.  

Artigue M., Haspekian M., & Corblin-Lenfant A. (2014) Introduction to the Theory of 

Didactical Situations (TDS). Advances in Mathematics Education (pp.46–65). Springer, 

Cham. https://doi.org/10.1007/978-3-319-05389-9_4 

Atalar, F. B., & Ergun, M. (2018). Evaluation of the knowledge of science teachers with 

didactic transposition theory. Universal Journal of Educational Research, 6(1), 298–

307.  

Bosch, M., & Gascón, J. (2006). Twenty-five years of the didactic transposition. ICMI 

Bulletin, 58, 51–65.  

Brousseau, G. (2006). Theory of didactical situations in mathematics: Didactique des 

mathématiques, 1970–1990 (Vol. 19). Springer Science & Business Media. 

Carvalho, G. S., Silva, R., Lima, N., Coquet, E., & Clément, P. (2004). Portuguese primary 

school children’s conceptions about digestion: Identification of learning obstacles. 

International Journal of Science Education, 26(9), 1111–1130. 

https://doi.org/10.1080/0950069042000177235 

Chevallard, Y., & Bosch, M. (2020). Didactic transposition in mathematics education. In S. 

Lerman (Ed.), Encyclopedia of Mathematics Education, 214–218. 

https://doi.org/10.1007/978-3-030-15789-0_48 

Chevallard, Y. (1989). On didactic transposition theory: Some introductory notes. In 

Proceedings of the International Symposium on Selected Domains of Research and 

Development in Mathematics Education, Bratislava, pp. 51–62.  

Chevallard, Y. (1992). A theoretical approach to curricula. Journal for Didactics of 

Mathematics, 13(2), 215–230. https://doi.org/10.1007/BF03338779 

https://doi.org/10.1007/978-3-319-05389-9_4


Rudi Rudi, Didi Suryadi, & Rizky Rosjanuardi 

77 

 

Clements, D. H., & Sarama, J. (2004). Learning trajectories in mathematics education. 

Mathematical Thinking and Learning, 6(2), 81–89.  

Diana, N., & Suryadi, D. (2020). Students’ creative thinking skills on the circle subject in 

terms of learning obstacle and learning trajectory. Journal of Physics Conference Series, 

1521(3), 032084. https://doi.org/10.1088/1742-6596/1521/3/032084    

Ekawati, R., Wintarti, A., & Kurniasari, I. (2020). Integrating the hypothetical learning 

trajectory with realistic mathematics to in-service teachers’ professional development. In 

International Conference on Research and Academic Community Services (ICRACOS 

2019). Atlantis Press.  

Elia, I., Özel, S., Gagatsis, A., Panaoura, A., & Özel, Z. E. Y. (2016). Students’ mathematical 

work on absolute value: Focusing on conceptions, errors and obstacles. ZDM, 48(6), 

895–907. https://doi.org/10.1007/s11858-016-0780-1 

Fauziah, A., & Putri, R. I. I. (2020). Developing PMRI Learning Environment through 

Lesson Study for Pre-Service Primary School Teacher. Journal on Mathematics 

Education, 11(2), 193–208. https://doi.org/10.22342/jme.11.2.10914.193-208 

Gilles, A. (2020). Collaboration between teachers and researchers: A theoretical framework 

based on meta-didactical transposition. In 25thICMI Study Teachers of Mathematics 

Working and Learning in Collaborative Groups. Lisbon, Portugal. Retrieved from 

https://hal.archives-ouvertes.fr/hal-02469014/document. 

Grushka, K. (2005). Artists as reflective self‐learners and cultural communicators: an 
exploration of the qualitative aesthetic dimension of knowing self through reflective 

practice in art‐making. Reflective Practice, 6(3), 353–366. 
https://doi.org/10.1080/14623940500220111 

Hausberger, T. (2017). The (Homo)morphism concept: Didactic transposition, meta-

discourse and thematization. International Journal of Research in Undergraduate 

Mathematics Education 3(3), 417–443. https://doi.org/10.1007/s40753-017-0052-7 

Ivars, P., Fernández, C., Llinares, S., & Choy, B. H. (2018). Enhancing noticing: using a 

hypothetical learning trajectory to improve pre-service primary teachers’ professional 

discourse. EURASIA Journal of Mathematics, Science and Technology Education, 

14(11), em1599. https://doi.org/10.29333/ejmste/93421 

Jamilah, J., Suryadi, D., & Priatna, N. (2020). Didactic transposition from scholarly 

knowledge of mathematics to school mathematics on sets theory. Journal of Physics: 

Conference Series, 1521, 032093. https://doi.org/10.1088/1742-6596/1521/3/032093.  

Kang, W., & Kilpatrick, J. (1992). Didactic transposition in mathematics textbooks. For the 

Learning of Mathematics, 12(1), 2–7. Retrieved from http://www.jstor.org/stable/40248035. 

Kuzniak, A., & Rauscher, J. C. (2011). How do teachers’ approaches to geometric work 

relate to geometry students’ learning difficulties? Educational Studies in Mathematics, 

77(1), 129–147. https://doi.org/10.1007/s10649-011-9304-7 

Loomis, E. S. (1968). The Pythagorean proposition. VA: National Council of Teachers of 

Mathematics. 

Moeini, M., Rahrovani, Y., & Chan, Y. E. (2019). A review of the practical relevance of IS 

strategy scholarly research. The Journal of Strategic Information Systems, 28(2), 196–

217. https://doi.org/10.1016/j.jsis.2018.12.003 

https://doi.org/10.1007/978-3-319-05389-9_4
https://hal.archives-ouvertes.fr/hal-02469014/document
https://doi.org/10.1007/978-3-319-05389-9_4
http://www.jstor.org/stable/40248035


Didactical Transposition within Reflective Practice of an Indonesian  

Mathematics Teacher Community: A Case in Proving the Pythagorean Theorem Topic 

78 

 

Pino-Fan, L. R., Assis, A., & Castro, W. F. (2015). Towards a methodology for the 

characterization of teachers’ didactic-mathematical knowledge. EURASIA Journal of 

Mathematics, Science and Technology Education, 11(6), 1429–1456. 

https://doi.org/10.12973/eurasia.2015.1403a 

Ratner, B. (2009). Pythagoras: Everyone knows his famous theorem, but not who discovered 

it 1000 years before him. Journal of Targeting, Measurement and Analysis for 

Marketing, 17(3), 229–242. https://doi.org/10.1057/jt.2009.16 

Rudi, R., Suryadi, D., & Rosjanuardi, R. (2020a). Teachers’ perception as a crucial 

component in the design of didactical design research-based teacher professional 

learning community in Indonesia. European Online Journal of Natural and Social 

Sciences, 9(3), 642–654. Retrieved from https://european-

science.com/eojnss/article/view/6089 

Rudi, R., Suryadi, D., & Rosjanuardi, R. (2020b). Teacher knowledge to overcome student 

errors in Pythagorean theorem proof: A study based on didactic mathematical knowledge 

framework. In Proceedings of the 7th Mathematics, Science, and Computer Science 

Education International Seminar, MSCEIS 2019. EAI Publishers. 

Saarti, J., & Tuominen, K. (2020). Openness, resource sharing and digitalization–an 

examination of the current trends in Finland. Information Discovery and Delivery, 49(2), 

97–104. https://doi.org/10.1108/IDD-01-2020-0006. 

Saito, E., Harun, I., Kuboki, I., & Tachibana, H. (2006). Indonesian lesson study in practice: 

Case study of Indonesian mathematics and science teacher education project. Journal of 

In-service Education, 32(2), 171–184. https://doi.org/10.1080/13674580600650872 

Sari, A., Suryadi, D., & Syaodih, E. (2018). A professional learning community model: A 

case study of primary teachers’ community in west Bandung. Journal of Physics: 

Conference Series, 1013(1), 012122. https://doi.org/10.1088/1742-6596/1013/1/012122 

Shinno, Y., & Yanagimoto, T. (2020). An opportunity for preservice teachers to learn from 

inservice teachers’ lesson study: Using meta-didactic transposition. In H. Borko, & D. 

Potari (Eds.), ICMI STUDY 25 Conference Proceedings: Teachers of Mathematics 

Working and Learning in Collaborative Groups, pp. 174–181. National and 

Kapodistrian University of Athens. 

Simon, M. A., & Tzur, R. (2004). Explicating the role of mathematical tasks in conceptual 

learning: An elaboration of the hypothetical learning trajectory. Mathematical Thinking 

and Learning, 6(2), 91–104. https://doi.org/10.1207/s15327833mtl0602_2 

Sullivan, P. (2008). Knowledge for teaching mathematics: an introduction. In International 

Handbook of Mathematics Teacher Education: Volume 1 (pp. 1–9). Brill Sense.  

Suratno, T. (2012). Lesson study in Indonesia: An Indonesia University of Education 

experience. International Journal for Lesson and Learning Studies, 1(3), 196–215. 

https://doi.org/10.1108/20468251211256410 

Suryadi, D. (2015). Penelitian Desain Didaktis (DDR) dan Kemandirian Berpikir. Seminar 

Nasional Pendidikan Matematika. Yogyakarta: Universitas Ahmad Dahlan. 

Suryadi, D., Prabawanto, S., & Takashi, I. (2017). A Reflective Framework of Didactical 

Design Research in Mathematics and Its Implication. Bandung: UPI. Retrieved from 

https://www.researchgate.net/publication/321747364_A_Reflective_Framework_of_Did

actical_Design_Research_in_Mathematics_and_Its_Implication.  

https://www.emerald.com/insight/search?q=Tatang%20Suratno
https://www.emerald.com/insight/publication/issn/2046-8253
https://www.researchgate.net/publication/321747364_A_Reflective_Framework_of_Didactical_Design_Research_in_Mathematics_and_Its_Implication
https://www.researchgate.net/publication/321747364_A_Reflective_Framework_of_Didactical_Design_Research_in_Mathematics_and_Its_Implication


Rudi Rudi, Didi Suryadi, & Rizky Rosjanuardi 

79 

 

Szűcs, I. Z. (2018). Teacher trainers’ self-reflection and self-evaluation. Acta Educationis 

Generalis, 8(2), 9–23.  

Taranto, E., Robutti, O., & Arzarello, F. (2020). Learning within MOOCs for mathematics 

teacher education. ZDM, 52(7), 1439–1453. https://doi.org/10.1007/s11858-020-01178-2 

Veljan, D. (2000). The 2500-year-old Pythagorean theorem. Mathematics Magazine, 73(4), 

259–272. https://doi.org/10.1080/0025570X.2000.11996853 

Winsløw, C. (2011). Anthropological theory of didactic phenomena: Some examples and 

principles of its use in the study of mathematics education. Un Panorama de TAD, CRM 

Docume, 117, 138. 

Zazkis, D., & Zazkis, R. (2016). Prospective teachers’ conceptions of proof comprehension: 

eevisiting a proof of the Pythagorean theorem. International Journal of Science and 

Mathematics Education, 14(4), 777–803.https://doi.org/10.1007/s10763-014-9595-0 

 

  



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