Presentatie van het manuscript 'COVID 19 Conspiracy Thinking Across the World ' door Annemarie Walter en Hugo Drochon bij REPRESENT, Research Centre for the Study of Parties and Democracy van de Universiteit van Nottingham, op 24 maart 2021.
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Visual Thinking (VT) is concerned with the use of visual resources (diagrams, simple drawings, short texts) to represent, organize or communicate ideas or contents. VT aims to favor the understanding of concepts to `translate' to a visual representation a content or process. Lower thinking skills to remember and understand concepts are necessary as much as higher order skills to filter, manage and spatially organize contents. VT offers us a slower, but more effective, way to learn and teachers are increasingly using VT for educational purposes in their lectures. Within the VT techniques, we have set ourselves in the so-called canvas as a template that allows to visually structuring the fundamental elements of an entity or process. As an example of use in the educational field, the PBL canvas proposed by conecta13, describes a Project Based Learning process in nine steps (key competences, learning standards, evaluation method, final product, tasks, resources, ICT tools, grouping and organization and dissemination). On the other hand, we find the need to encourage Science, Technonoloy, Engineering and Mathematics (STEM) vocations, especially in women, given the decreasing interest in these areas (Science, Mathematics, Engineering and Mathematics) considered more arid and boring by students. This makes us to face a paradoxical crossroad, since much of the jobs of the future will be linked to these fields. It is therefore necessary to bring the methodology of scientific thinking closer to the students by presenting it in accessible ways. Here we propose a canvas that provides a visual structure to represent graphically the various steps of the scientific method. These steps include the systematic observation, formulation of hypothesis, design of the experiment to prove or discard them, to finally elaborate some conclusions leading to development of a theory. The canvas is used as a visual tool to support the design to summarize the results of the scientific experiment, to cover the different steps in a schematic way either with text or graphically. An empty template is provided as well as different examples of the canvas covered with experiments that can be carried out in different pre-university educational levels. In order to let this canvas become part of the public domain it is released under the Creative Commons Attribution-Share Alike license, so that anyone can use it, copy or modify by free, with the only condition of attributing the corresponding authorship and keeping the license open.
The methodology of biomimicry design thinking is based on and builds upon the overarching patterns that all life abides by. “Cultivating cooperative relationships” within an ecosystem is one such pattern we as humans can learn from to nurture our own mutualistic and symbiotic relationships. While form and process translations from biology to design have proven accessible by students learning biomimicry, the realm of translating biological functions in a systematic approach has proven to be more difficult. This study examines how higher education students can approach the gap that many companies in transition are struggling with today; that of thinking within the closed loops of their own ecosystem, to do good without damaging the system itself. Design students should be able to assess and advise on product design choices within such systems after graduation. We know when tackling a design challenge, teams have difficulties sifting through the mass of information they encounter, and many obstacles are encountered by students and their professional clients when trying to implement systems thinking into their design process. While biomimicry offers guidelines and methodology, there is insufficient research on complex, systems-level problem solving that systems thinking biomimicry requires. This study looks at factors found in course exercises, through student surveys and interviews that helped (novice) professionals initiate systems thinking methods as part of their strategy. The steps found in this research show characteristics from student responses and matching educational steps which enabled them to develop their own approach to challenges in a systems thinking manner. Experiences from the 2022 cohort of the semester “Design with Nature” within the Industrial Design Engineering program at The Hague University of Applied Sciences in the Netherlands have shown that the mixing and matching of connected biological design strategies to understand integrating functions and relationships within a human system is a promising first step. Stevens LL, Whitehead C, Singhal A. Cultivating Cooperative Relationships: Identifying Learning Gaps When Teaching Students Systems Thinking Biomimicry. Biomimetics. 2022; 7(4):184. https://doi.org/10.3390/biomimetics7040184
