A Specific Kind of Representation: How Systematics May Ease Cognitive Overload

Özlem Cezikturk(1*)

(1) Marmara University
(*) Corresponding Author

Abstract

Multiple representations are beneficial for meaningful understanding. However, three or more representations may add to the cognitive overload of students, if not in interactive diagrams and dynamic geometry. How a well-known representation consisting of more than 3 or more representational registers may overcome the problem of cognitive overload without being too complicated. In this study, an old but well-structured representation that was used even over 40 years was analyzed. The critical points of a function, asymptotes, x / y-intercepts, inflection points, and graphing can be identified easily. It is prepared in the form of a table and the factors of the first derivative of the function and the second derivative and their roots indicate the function’s increasing and decreasing intervals and its graph. This representation is very systematic and it acts like a method to draw the function’s graph with no-fault possible. Yet, besides being used for many years, is still used for courses like Calculus, etc. We argue that cognitive overload theory cannot alter this representation due to its systematic nature. In content analysis, some examples of this representation are shared via the reader, and some qualitative aspects about it are analyzed. Finally, its systematicity, well-structured nature, and nature in reducing extraneous cognitive load are emphasized. The important thing here is that it is very strategic not to lose some representations for the sake of new ones if their value is already known but not discussed too much.

Keywords

Multiple representations; Cognitive Overload Theory; Systemic thinking

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References

Akçabay, A. (1961). Cebir III (Fen Kolu) Remzi Kitabevi: İstanbul.

Baykara, S. (1942). Matematik (D.D. Yolları Teknik eleman kurslarında okutulmak üzere tertip edilmiştir), Demiryolları Matbaası: İzmir.

Bogomolov, N.V. (1986). Mathematics for Technical Schools: A practical approach, MIR Publishers: Moscow.

Çanakçı, O. (2006). ÖSS Matematik 5, Karekök Yayınları: İstanbul.

Çeziktürk-Kipel, Ö. & Özdemir, A. Ş. (2016). Wasan Geometrisi Öğretiminin van Hiele Geometrik, Düşünce Düzeyleri ile uygulaması ve öğretmen adaylarının öğrenme durumlarına etkileri. Avrasya Eğitim ve Literatür Dergisi, 4(2), 17-27., Doi: 10.17740 (Yayın No: 3305290)

Çeziktürk- Kipel, Ö., Aras, İ. , Zengin, M., Ayrancıoğlu, A., Aslan, S. (2019). Öğretmen adaylarının hazırladığı ünitelerdeki matematik temsil analizi. UEYAK 2019 (Tam Metin Bildiri/Sözlü Sunum)(Yayın No:5556968)

İncikabı, S. & Biber, A.Ç. (2018). Ortaokul matematik ders kitaplarında yer verilen temsiller arası ilişkilendirmeler, Kastamonu Education Journal, 26,3,729-740:doi:10.24106/kefdergi:415690.

Jong, T. (2010). Cognitive Load Theory; Educational research and instructional design: Some food for thought, Instructional Science, 38- 105-134.

Maani, K.E. & Maharaj, V. (undated). Links between systems thinking and complex problem solving, Further evidence, The University of Auckland: New Zealand.

Michelmore, N. & White, P. (2007). Abstraction in mathematics Learning (Editorial) Mathematics Education Research Journal, 19,2,1-9.

Orhun, N. (2012). Graphical understanding in mathematics education: derivative functions and students’ difficulties, Procedia and behavioral Sciences, 55, 679-685-4.

Paivio, A. (2006). Dual Coding Theory and Education, Draft chapter presented on the conference on “Pathways to Literacy Achievement for High Poverty Children”, 1-21.

Pino, Fan., L.R. , Guzman, I., Duval, R. & Font, F. (2015). The theory of registers of semiotic representation and the onto-semiotic approach to mathematical cognition and instruction: Linking looks for the study of mathematical understanding, Proceedings of the 39th Psychology of Mathematics Education Conference, 4, 33-40, Australia: PME.

Sezer, S. (1986). Lycee mathematics course notes, Erenkoy High Lycee for Girls, İstanbul.

Sweller, J., (1988). Cognitive load during problem-solving: Effects on learning, Cognitive Science, 12, 257-285.

Sweller, J.(1999). Instructional Design in Technical Areas, Camberwell, Victoria, Australia: Australian Council for Educational Research.

Tanın, T. (1962). Geometri dersleri: Lise III Fen Kolu(7. Baskı). İnkilap ve Aka Kitabevleri.

Tanrıöver, N. & İldeniz, A. R. (1994). Ders geçme ve kredi sistemine göre liseler için Analitik Geometri 2: Ders Kitabı, Yıldırım Yayınları.

Thomas, M. D. Weir, Hass, J. & Heil, C. (2014) Thomas’ Calculus 13th Edition. Pearson.: Boston.

Van Hiele, P. M. (1986). Structure and Insight. A Theory of Mathematics Education. London: Academic Press.

Wittman, E. C. (2021). Developing mathematics Education ins in systemic process, Connecting Mathematics and Mathematics Education: Collected papers on mathematics education as a design science, Chp 9, (191-208). Springer Publications.

DOI: 10.23917/varidika.v1i1.17556

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