Design of Technology-Enhanced Learning

This chapter lays contextual foundations for the study and application of technology-enhanced learning design. Key drivers for the integration of technology into learning are identified, including the intrinsic desire to improve learning outcomes, the development of student digital learning skills, curriculum and syllabus specifications, professional requirements, providing greater access to learning, and catering to student dispositions. The need for a critical approach is established, for instance, by avoiding misconceptions such as ‘digital natives’ and ‘technological determinism.’ A ‘scholarship of teaching’ perspective that uses research evidence as a basis for technology-enhanced learning design is selected as the means for further inquiry.

This chapter introduces the Technology Pedagogy and Content Knowledge (TPACK) model as it relates to technology-enhanced learning design. The key features of the framework are unpacked, along with a brief examination of what TPACK looks like in practice. Approaches to developing TPACK capacity are considered, with learning-by-design emerging as the most promising technique. Issues relating to TPACK are also critically discussed, including those relating to measurement and the capacity of the framework to support educational design practice.

This chapter critically examines the implications of different pedagogical perspectives, approaches, and strategies for the design and implementation of technology-enhanced learning. The key tenets of different pedagogical perspectives are unpacked, including behaviorism, cognitivism, constructivism, socio-constructivism, and connectivism, with reference to how technology can be used to instantiate them. A range of different pedagogical approaches, including collaborative learning, problem-based learning, inquiry-based learning, constructionist learning, design-based learning, and games-based learning are discussed in relation to the use of technology and the previously identified pedagogical perspectives. Pedagogical strategies at a more instantaneous level are also considered, as are the goals of technology-enhanced learning in terms of promoting authentic and meaningful learning. The critical role of the teacher when applying pedagogies using technology, as well as associated issues, are discussed throughout.

This chapter provides an overview of two generally applicable frameworks relating to the use of technology-enhanced learning – ‘affordances’ and multimedia learning effects. First, the concept of ‘affordances’ as action potentials of technologies is identified as a way to think through technology-enhanced learning design possibilities, so as to help make technology selection decisions. Second, multimedia learning effects including the multimedia effect, the modality effect, the redundancy effect, the split-attention effect, and the personalization effect are presented as a scientific basis for understanding how to create cognitively effective learning experiences using text, images, sound, and video. Both affordances and multimedia learning effects are characterized as ongoing areas of research that are somewhat related, with the successful utilization of each depending on critical application by the designer.

Having considered various types of pedagogy as well as technology affordances and multimedia learning principles, this chapter focuses on issues surrounding the representation and sharing of content using technology. Anderson & Krathwohl’s (2001) Taxonomy of Learning, Teaching and Assessing is examined as a means of conceptualizing different types of thinking processes in a way that can be applied across discipline areas. The representational requirements of different subject areas (English, mathematics, science, history, geography, and computing) are explored by means of examples, with reference to the role of technology and the range of possible tasks that may be utilized. Assessment issues as they relate to the representation of content are also considered. The broader contextual shift toward open education and sharing is discussed, including key drivers such as learning object repositories, open educational resources, Creative Commons licensing, and massive open online courses.

This chapter unpacks ‘design thinking’ as it relates to educational design, and highlights how developments in the field of Learning Design may be of assistance to educators. Design is defined as a creative, scientific, and complex process, underpinned by several design thinking qualities. Teaching, it is argued, should be positioned as a design science, based on its nature, practice, and intentions. Learning to design is characterized as a challenging pursuit that is supported through practice, refection, examples, and expert guidance. Based on the literature, the pursuit of designing for learning is explained as a process involving the creation of accessible and aligned designs that cater to students in order to achieve desired learning outcomes. Educational design models by Laurillard, Siemens, and Conole are contrasted and evaluated in order to critically reflect on the general utility of such models. The field of Learning Design is introduced as a discipline area that aims to help educators develop and share great teaching ideas. Six approaches that support the description and sharing of learning designs are briefly described (technical standards, pattern descriptions, visualizations, visualization tools, pedagogical planners, and the Learning Activity Management System) so as to illustrate how the Learning Design field has evolved and how educators can capitalize upon it. Directions forward are recommended, which center around reflection, collaboration, and a design orientation.

This chapter provides a comprehensive review of research and developments relating to the use of Web 2.0 technologies in education. As opposed to early educational uses of the Internet involving publication of static information on web pages, Web 2.0 tools offer a host of opportunities for educators to provide more interactive, collaborative, and creative online learning experiences for students. The chapter starts by defining Web 2.0 tools in terms of their ability to facilitate online creation, editing, and sharing of web content. A typology of Web 2.0 technologies is presented to illustrate the wide variety of tools at teachers’ disposal. Educational uses of Web 2.0 technologies such as wikis, blogs, and microblogging are explored, in order to showcase the variety of designs that can be utilized. Based on a review of the research literature the educational benefits of using Web 2.0 technologies are outlined, including their ability to facilitate communication, collaborative knowledge building, student-centered activity, and vicarious learning. Similarly, issues surrounding the use of Web 2.0 tools are distilled from the literature and discussed, such as the possibility of technical problems, collaboration difficulties, and plagiarism. Two case studies involving the use Web 2.0 tools to support personalized learning and small group collaboration are detailed to exemplify design possibilities in greater detail. Finally, design recommendations for learning and teaching using Web 2.0 are presented, again based on findings from the research literature.

Social networking platforms such as Facebook have infiltrated the lives of many students, and as such it is natural to consider how they can be effectively used to enhance learning. This chapter provides a comprehensive review of social networking in education from a design perspective. Social networking is defined based on Boyd & Ellison’s seminal definition of connected profiles, and is distinguished from social media for the purposes of investigation. Facebook, Edmodo, and other social networking platforms are briefly described, before summarizing the wide variety of social networking usage reported in the research literature. The various benefits of social networking in education are distilled from the literature, including their capacity to facilitate community building, collaboration, reflection, and expedient access to learning. Issues surrounding the educational use of social networking are also organized into themes, for instance privacy concerns, distraction, cyber-safety, and technical constraints. The implications of findings from the social networking literature are synthesized into learning design and implementation recommendations. The chapter concludes with a discussion of open questions and areas for further investigation.

Mobile devices, through their capacity to enable anytime-anywhere learning as well as capture, annotate and share multimedia, offer entirely new ways for students to learn. This chapter provides review of mobile learning with a particular focus on learning design. First various definitions and characteristics of mobile learning are examined in order to establish a common understanding of its boundaries and meaning. Example uses of mobile learning in schools and higher education are described as a way to provide a more concrete understanding of design possibilities. Benefits of mobile learning are unpacked, as distilled from the literature, including the ability to provide flexible, accessible, authentic, personalized, ubiquitous and seamless learning. Mobile learning issues are also examined, including technical problems, cognitive load issues, distraction, equity and safety. A primary school science and a university pre-service teacher education vignette are described so as to offer a more in-depth illustration of what mobile learning can look like and achieve in practice. Finally, mobile learning research findings and observations are synthesized into recommendations, to inform and guide evidence-based mobile learning design practices. Opportunities for future research and investigation are also discussed.

The ability for learners to interact online via their avatars in a 3-D simulation space means that virtual worlds afford a host of educational opportunities not offered by other learning technology platforms, but their use also raises several pertinent issues that warrant consideration. This chapter reviews the educational use of virtual worlds from a design perspective. Virtual-world definitions are explored, along with their key educational characteristics. Different virtual-world environments are briefly contrasted, including Second Life, Active Worlds, Open Sim, and Minecraft. A wide variety of virtual-world uses in schools and universities are examined so as to understand their versatility. Key educational benefits of virtual worlds are distilled from the literature, such as the ability to facilitate 3-D simulations, role-plays, construction tasks, and immersive learning. Emergent issues surrounding the use of virtual worlds are also analyzed, including cognitive load, safety, and representational fidelity. One higher education and one school level vignette are provided in order to offer more detailed insight into the use of virtual worlds in practice. Recommendations for learning design and implementation are presented, based on the thematic analysis of contemporary virtual-worlds research.

This chapter synthesizes findings from the reviews of education using Web 2.0, social networking, mobile learning, and virtual worlds, in light of the earlier chapters on context, technology, pedagogy, content, and design. Benefits and issues associated technology-enhanced learning are generalized, with an important finding being the quite different ways that different technologies contribute to each. Twenty technology-enhanced learning design principles are derived from abstracting the Web 2.0, social networking, mobile learning, and virtual worlds literature. The benefits, issues, and technology-enhanced learning design principles are then related to one another by virtue of 13 clusters of concerns, namely pedagogy, access, communication, content representation, collaboration, motivation and engagement, vicarious learning and reflection, digital learning capabilities, assessment and feedback, student-centered learning, learning communities, protecting students, and teacher support. The analysis enables the general learning technology literature to be linked to concrete examples and evidential sources, so that educators and researchers can construct a deep and connected understanding of technology-enhanced learning design.

This chapter aims to establish a positive vision for the technology-enhanced learning design field. It commences by summarizing the current state of technology-enhanced learning research, as established by the previous analysis, in order to clarify the foundations upon which the field can build. The future of learning technology is considered, in the first instance, by extrapolating trends in information and communication technologies throughout history. This process showcases how the most impactful technologies are those that bring information closer to us, support sharing, and offer more visceral learning experiences. The nature of learning technology trends occurring in recent Horizon Reports, for instance, gesture-based computing, augmented reality, Massive Open Online Courses, and table computing, are analyzed and explained in terms of Roger’s Diffusion of Innovation Theory and Gartner’s Hype Cycle. This leads to identifying teachers as the critical lynch pin in order for society to derive greatest educational benefit from the exponential advances in technology. Consequently, support for educators is argued as essential. Into the future the learning technology field will only optimize its progress if educators and researchers work together to understand design issues and possibilities. Directions forward for educators and researchers are proposed, emphasizing a research-driven, pedagogically focused, creative, and collaborative approach to technology-enhanced learning design.