From the article: "Abstract, technology-enhanced learning can be used to replicate existing teaching practices, supplement existing teaching or transform teaching and/or learning process and outcomes. Enhancing workplace learning, which is integrated into higher professional education, with technology, calls for designing such transformations. Although research is carried out into different kinds of technological solutions to enhance workplace learning, we do not know which principles should guide such designs. Therefore, we carried out an explorative, qualitative study and found two such design principles for the design of technology-enhanced workplace learning in higher professional education. In this research, we focused on the students' perspective, since they are the main users of such technology when they are learning at the workplace, as part of their study in becoming lifelong learning, competent professionals."
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From the article: "The goal of higher professional education is to enable students to develop into reflective practitioners, having both a firm theoretical knowledge base as well as appropriate, professional attitudes and skills. Learning at the workplace is crucial in professional education, because it allows students to learn to act competently in complex contexts and unpredictable situations. Reflection on learning during an internship is hard to interweave with the working process, which may easily result in students having little control over their own learning process while at work. In this study, we aim to discover in what way we can effectively use technology to enhance workplace learning, by synthesizing design propositions for Technology- Enhanced Workplace Learning (TEWL). We conducted design-based research which is cyclic in nature. Based on preliminary research, we constructed initial design propositions and developed a web-based app (software program for mobile devices) providing interventions based on these propositions. In a pilot study, students from different educational domains used this app to support their workplace learning. We evaluated the initial design propositions by carrying out both a theoretical and a practical evaluation. With the insights obtained from these evaluations, we developed a next version of the design propositions and improved the app accordingly. The research result is a set of design propositions for TEWL. For daily practice, the developed web-based app is available for re-use and further research and development."
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De implementatie van blended learning – waarbij fysiek leren wordt gecombineerd met online leren – staat bij veel onderwijsinstellingen hoog op de agenda, om activeren, intensiveren, flexibiliseren, differentiëren en/of personaliseren mogelijk te maken (Bos, 2022). Als gevolg hiervan krijgt de online leeromgeving binnen onderwijsinstellingen een steeds nadrukkelijkere rol. Om te komen tot betekenisvol leren in deze online leeromgeving (vaak in de vorm van een leermanagementsysteem, ook wel LMS genoemd), is het belangrijk dat studenten hierin actief aan de slag gaan met de aangeboden onderwijsinhoud en geïnteresseerd en gemotiveerd zijn om dit te (gaan) doen (Michael, 2006; Alhazmi & Rahman, 2012; Derboven et al., 2017; Grant-Smith et al., 2019). Echter, in de praktijk blijkt dat lang niet altijd sprake is van deze gewenste student engagement. Bijlage 1: Dit artikel geeft de resultaten weer van een onderzoek naar mogelijkheden om student engagement in het LMS te vergroten. Deze resultaten zijn tevens samengevat in twee overzichtelijke infographics. Bijlage 2: Infographic 1 omvat het gehele overzicht van de (mogelijk) te implementeren ontwerpprincipes. Bijlage 3: Infographic 2 bevat een stappenplan voor docenten om hun LMS te analyseren en te optimaliseren (laaghangend fruit).
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The central aim of this thesis was to increase understanding of designing vocational learning environments at the school–work boundary. Four studies were conducted, focusing on learning environment designs at the school–work boundary and on design considerations of the actors involved in their construction, both from the world of school and the world of work.
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Educational institutions and vocational practices need to collaborate to design learning environments that meet current-day societal demands and support the development of learners’ vocational competence. Integration of learning experiences across contexts can be facilitated by intentionally structured learning environments at the boundary of school and work. Such learning environments are co-constructed by educational institutions and vocational practices. However, co-construction is challenged by differences between the practices of school and work, which can lead to discontinuities across the school–work boundary. More understanding is needed about the nature of these discontinuities and about design considerations to counterbalance these discontinuities. Studies on the co-construction of learning environments are scarce, especially studies from the perspective of representatives of work practice. Therefore, the present study explores design considerations for co-construction through the lens of vocational practice. The study reveals a variety of discontinuities related to the designable elements of learning environments (i.e. epistemic, spatial, instrumental, temporal, and social elements). The findings help to improve understanding of design strategies for counterbalancing discontinuities at the interpersonal and institutional levels of the learning environment. The findings confirm that work practice has a different orientation than school practice since there is a stronger focus on productivity and on the quality of the services provided. However, various strategies for co-construction also seem to take into account the mutually beneficial learning potential of the school–work boundary.
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Learning environment designs at the boundary of school and work can be characterised as integrative because they integrate features from the contexts of school and work. Many different manifestations of such integrative learning environments are found in current vocational education, both in senior secondary education and higher professional education. However, limited research has focused on how to design these learning environments and not much is known about their designable elements (i.e. the epistemic, spatial, instrumental, temporal and social elements that constitute the learning environments). The purpose of this study was to examine manifestations of two categories of integrative learning environment designs: designs based on incorporation; and designs based on hybridisation. Cross-case analysis of six cases in senior secondary vocational education and higher professional education in the Netherlands led to insights into the designable elements of both categories of designs. We report findings about the epistemic, spatial, instrumental, temporal and social elements of the studied cases. Specific characteristics of designs based on incorporation and designs based on hybridisation were identified and links between the designable elements became apparent, thus contributing to a deeper understanding of the design of learning environments that aim to connect the contexts of school and work.
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Research into the relationship between innovative physical learning environments (PLEs) and innovative psychosocial learning environments (PSLEs) indicates that it must be understood as a network of relationships between multiple psychosocial and physical aspects. Actors shape this network by attaching meanings to these aspects and their relationships in a continuous process of gaining and exchanging experiences. This study used a psychosocial-physical, relational approach for exploring teachers’ and students’ experiences with six innovative PLEs in a higher educational institute, with the application of a psychosocial-physical relationship (PPR) framework. This framework, which brings together the multitude of PLE and PSLE aspects, was used to map and analyse teachers’ and students’ experiences that were gathered in focus group interviews. The PPR framework proved useful in analysing the results and comparing them with previous research. Previously-identified relationships were confirmed, clarified, and nuanced. The results underline the importance of the attunement of system aspects to pedagogical and spatial changes, and of a psychosocial-physical relational approach in designing and implementing new learning environments, including the involvement of actors in the discourse within and between the different system levels. Interventions can be less invasive, resistance to processes could be reduced, and innovative PLEs could be used more effectively.
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This paper examines how the learning environment in primary education can be enhanced by stimulating the use of innovative ICT applications. In particular, this discussion focuses on mind tools as a means of leveraging ICT for the development of cognitive skills. The stimulating effect of mind tools on the thinking skills and thinking attitudes of students is examined. The various types of mind tools and a number of specific examples are closely examined. We consider how mind tools can contribute to the establishment of an ICT-rich learning environment within the domain of technology education in primary schools. We illustrate two specific applications of such mind tools and discuss how these contribute to the development of thinking skills.
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De implementatie van blended learning – waarbij fysiek leren wordt gecombineerd met online leren – staat bij veel onderwijsinstellingen hoog op de agenda, om activeren, intensiveren, flexibiliseren, differentiëren en/of personaliseren mogelijk te maken (Bos, 2022). Als gevolg hiervan krijgt de online leeromgeving binnen onderwijsinstellingen een steeds nadrukkelijkere rol. Om te komen tot betekenisvol leren in deze online leeromgeving (vaak in de vorm van een leermanagementsysteem, ook wel LMS genoemd), is het belangrijk dat studenten hierin actief aan de slag gaan met de aangeboden onderwijsinhoud en geïnteresseerd en gemotiveerd zijn om dit te (gaan) doen (Michael, 2006; Alhazmi & Rahman, 2012; Derboven et al., 2017; Grant-Smith et al., 2019). Echter, in de praktijk blijkt dat lang niet altijd sprake is van deze gewenste student engagement. Deze resultaten zijn samengevat in twee overzichtelijke infographics. Bijlage 1: Infographic 2 bevat een stappenplan voor docenten om hun LMS te analyseren en te optimaliseren (laaghangend fruit). Bijlage 2: Infographic 1 omvat het gehele overzicht van de (mogelijk) te implementeren ontwerpprincipes. Bijlage 3: Dit artikel geeft de resultaten weer van een onderzoek naar mogelijkheden om student engagement in het LMS te vergroten.
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