| 1. |
- Brandl, Matthias, et al.
(author)
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Narrative Didactics in Mathematics Education : Results from a University Geometry Course
- 2023
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In: Open Education Studies. - : De Gruyter Open. - 2544-7831. ; 5:1
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Journal article (peer-reviewed)abstract
- In a Swedish second semester course on Euclidean and non-Euclidean geometry in mathematics education at Karlstad University, a bridging teaching strategy comprising elements from Mathematics, Didactics, History, Literature, and Technology was applied by using the concept of Narrative Didactics and Digital Interactive Mathematical Maps developed by the Professorship for Didactics of Mathematics at the University of Passau, Germany. The complete assessment of the teaching strategy comprised both an evaluation of the technological and the narrative didactical scaffolding and was partly analysed previously concerning especially the technology acceptance aspect, while here we broaden and deepen the evaluation analysis of the application of narrative didactic elements. Regarding the latter, at the end of the course, students were asked to formulate a short historical-oriented narrative motivation for a school topic of own choice with the help of information provided by the timeline of the Mathematical Map. A representative example of these art-combining products is presented and evaluated according to elements of narrative didactics. Results indicate a fruitful, promising, and synergetic connection between different fields of Science, Technology, Engineering, the Arts, and Mathematics that can lead to a richer and more sustainable learning process in mathematics lessons both at university and school level.
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| 2. |
- Martorell, José Antonio Gordillo, et al.
(author)
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The Infinite Learning Chain. Flipped Professional Labs for Learning and Knowledge Co-Creation
- 2019
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In: Open Education Studies. - : Walter de Gruyter. - 2544-7831. ; 1, s. 151-176
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Journal article (peer-reviewed)abstract
- Nowadays universities and other classical research institutions are changing their role in knowledge creation. In general terms we can characterize this transition as the path from "Closed Science"to "Open Science"as a part of a deeper and structural phenomenon known as "knowledge democratization", where different stakeholders as students, makers and other tech and science enthusiasts are able to create knowledge learning from the researchers and cooperating with them. In this process, science engagement of these new actors is a key point to stimulate their creativity, get some important research skills learnt directly from the researchers and be able to apply these skills teaching others in a continuous "learning chain". In this article, we introduce some main features and preliminary results of an experiment called "The infinite learning chain"done in cooperation with Arduino, focused on sensing science and based in a real research project of Group of Atmospheric Science (GAS) called Luleå Environmental Monitoring Stations (LEMS). We debate some interesting questions related to the impact of the format in terms of science engagement, STEM skills acquisition and cooperative learning involvement. We used as "learning ecosystem"a professional Lab, the INSPIRE Lab a complete multidisciplinary facility for space and environmental research and exploration.
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| 3. |
- Vinerean-Bernhoff, Mirela, 1974-, et al.
(author)
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“Literally I Grew Up” Secondary–Tertiary Transition in Mathematics for Engineering Students beyond the Purely Cognitive Aspects
- 2023
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In: Open Education Studies. - : De Gruyter Open. - 2544-7831. ; 5:1
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Journal article (peer-reviewed)abstract
- High dropout rates in the first year of undergraduate studies are an expression of the secondary–tertiary transition problem and they seem to be particularly high in those degree programs where specialized mathematics courses are taught in the first year of study. Research shows that students’ difficulties during the transition period cannot be reduced to purely cognitive factors. In this article, we address the secondary–tertiary transition problem in mathematics for engineering students. Based on a questionnaire with focus beyond the purely cognitive aspects, a comparison of the transition problem at three European mid-sized universities is carried out, to identify common challenges and difficulties, as well as differences. The questionnaire concentrates on the four dimensions (personal, organizational, content related, and social) and corresponding critical requirements for a successful transition described in Trautwein, C., & Bosse, E. (2017). The first year in higher education – critical requirements from the student perspective. Higher Education, 73, 371–387. A group of 308 first-year engineering students partook in the study. In the presentation, we highlight students’ perceptions regarding the transition, changes, and challenges they experienced under the above-mentioned four dimensions and discuss similarities and differences between countries.
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