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International Journal of Technology and Design Education

Erschienen in:

01.11.2013

An exploratory study on how primary pupils approach systems

verfasst von: Marja-Ilona Koski, Marc de Vries

Erschienen in: International Journal of Technology and Design Education | Ausgabe 4/2013

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Abstract

This paper presents a study of systems thinking among 27 primary pupils (8–10 years old) and their teacher. The study included a pre-test for the teacher and the pupils, lesson planning, the actual lesson and a post-test for the pupils. The research focused on finding an answer to three questions: (1) do pupils see a system as a structure consisting of main- and subparts, (2) what are the inputs and outputs that they consider to be important for a system, and (3) can they define the boundaries of a system. Analysis revealed that the pupils showed some understanding of machines consisting of parts with different functions, or that a sequence of steps is required to complete a process. Systems, however, were mainly described in terms of what the user can experience, instead of what the machine itself does. The concept of input was more obvious to the pupils than output. It appears that setting boundaries to systems was a challenging task because what a system does and what a user does seemed to overlap. Nevertheless, by including basic principles of systems thinking, the teacher was able to introduce alternatives to approach the problems discussed during the lesson. Even though systems thinking was rather limited in a broader sense, the pupils were able to reach beyond basic descriptions, and they used new practices to explain and label artefacts.

Vorheriger Artikel Representations of technology in the “Technical Stories” for children of Otto Witt, early 20th century Swedish technology educator

Nächster Artikel Learning through creating robotic models of biological systems

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Arndt, H. (2006). Enhancing systems thinking in education using systems dynamics. Simulation, 82(11), 795–806.CrossRef

Assaraf, O. B.-Z., & Orion, N. (2005). Development of system thinking skills in the context of earth science system education. Journal of Research in Science Teaching, 42(5), 518–560.CrossRef

Barak, M., & Williams, P. (2007). Learning elemental structures and dynamic processes in technological systems: A cognitive framework. International Journal of Technology and Design Education, 17, 323–340.CrossRef

Bauer, J. M., & Herder, M. P. (2009). Designing socio-technical systems. In A. Meijers (Ed.), Philosophy of technology and engineering sciences (pp. 601–630). Amsterdam: Elsevier.CrossRef

Boersma, K., Waarlo, A. J., & Klaassen, K. (2011). The feasibility of systems thinking in biology education. Journal of Biological Education, 45(4), 190–197.CrossRef

Booth Sweeney, L (2011). Thinking about systems. http://lindaboothsweeney.net/ last Accessed in 29 Sep, 2011.

Booth Sweeney, L., & Sterman, J. D. (2007). Thinking about systems: Student and teacher conceptions of natural and social systems. System Dynamics Review, 23(2/3), 285–312.CrossRef

de Vries, M. J. (2005). Teaching about technology. An introduction to the philosophy of technology for non-philosophers. Dordrecht: Springer.

Fox-Turnbull, W. (2012). Funds of knowledge in technology education. In T. Ginner, J. Hallström, & M. Hultén (Eds.), PATT 26 Conference, technology education in the 21st century (pp. 179–187). Sweden: Stockholm.

Ginns, I. S., Norton, S. J., & McRobbie, C. J. (2005). Adding value to the teaching and learning of design and technology. International Journal of Technology and Design Education, 15, 47–60.CrossRef

International Technology Education Association. (2007). Standards for Technological Literacy: Content for the Study of Technology, Third Edition. Reston, US: International Technology Education Association. Retrieved from http://www.iteaconnect.org/TAA/PDFs/xstnd.pdf.

Kali, Y., Orion, N., & Eylon, B.-S. (2003). Effect of knowledge integration activities on students’ perception of the earth’s crust as a cyclic system. Journal of Research in Science Teaching, 40(6), 545–565.CrossRef

O’Connor, J., & McDermott, I. (1997). The art of systems thinking—essential skills for creativity and problem solving. London: Thorsons.

Ossimitz, G. (1997). Development of systems thinking skills using system dynamics modeling tools. http://wwwu.uni-klu.ac.at/gossimit/sdyn/gdm_eng.htm last Accessed in 29 Sep, 2011.

Richmond, B. (1993). Systems thinking: Critical thinking skills for the 1990s and beyond. System Dynamics Review, 9(2), 113–133.CrossRef

Senge, P., Cambron-McCabe, N., Lucas, T., Smith, B., Button, J., & Kleiner, A. (2000). Schools that learn. A fifth discipline field book for educators, parents, and everyone who cares about education. London: Nicholas Brealey Publishing.

Sterman, J. D. (2002). All models are wrong: Reflections on becoming a systems scientist. System Dynamics Review, 18(4), 501–531.CrossRef

Svensson, M., Zetterqvist, A., & Ingerman, Å. (2012). On young people’s experience of systems in technology. Design and Technology Education: An International Journal, 17(1), 66–77.

Tiberghien, A. (1997). Learning and teaching: Differentiation and relation. Research in Science Education, 27(3), 359–382.CrossRef

von Bertalanffy, L. (1979). General system theory. New York: George Braziller.

Westra, R. (2008). Learning and teaching ecosystem behaviour in secondary education—systems thinking and modelling in authentic practices (Doctoral dissertation). Utrecht: Freudenthal Institute for Science and Mathematics Education.

Titel: An exploratory study on how primary pupils approach systems
verfasst von: Marja-Ilona Koski
Marc de Vries
Publikationsdatum: 01.11.2013
Verlag: Springer Netherlands
Erschienen in: International Journal of Technology and Design Education / Ausgabe 4/2013
Print ISSN: 0957-7572
Elektronische ISSN: 1573-1804
DOI: https://doi.org/10.1007/s10798-013-9234-z

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