Over the next 10 years, we anticipate that personal, portable, wirelessly-networked technologies will become ubiquitous in the lives of learners — indeed, in many countries, this is already a reality. We see that ready-to-hand access creates the potential for a new phase in the evolution of technology-enhanced learning (TEL), characterized by "seamless learning spaces" and marked by continuity of the learning experience across different scenarios (or environments), and emerging from the availability of one device or more per student ("one-to-one"). One-to-one TEL has the potential to "cross
Knowledge and learning exist as byproducts of social processes such as those that take place in communities of practice. We describe two frameworks for understanding and building online knowledge-building communities, or online communities of practice that enhance collective knowledge. First, the C4P framework is described as a way of understanding how knowledge is created and disseminated by participants in a community of practice. Second, we discuss ways in which technology provides added value for learning in these environments using the DDC (Design for Distributed Cognition) framework, and
In this article, we describe a preliminary study that integrates research on engineering design activities for K-12 students with work on microworlds as learning tools. Here, we extend these bodies of research by exploring whether - and how - authentic recreations of engineering practices can help students develop conceptual understanding of physics. We focus on the design-build-test (DBT) cycle used by professional engineers in simulation-based rapid modeling. In this experiment, middle-school students worked for 10 hr during a single weekend to solve engineering design challenges using
To date, the major emphasis of educational technology researchers has been the development and use of educational technologies within school settings. Noticeably absent has been research and considerations that focus on the home as a computer-based learning environment and potential connections between school and home learning. Given the increasing prevalence of computers in homes, the authors argue for an explicit research focus on the various ways that computers in homes can be used to create rich learning environments or extend school-based learning environments. To that end, this article
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Yasmin KafaiBarry FishmanAmy BruckmanSaul Rockman
This paper illustrates the intensified engagement that youth are having with digital technologies and introduces a framework for examining digital fluency – the competencies, new representational practices, design sensibilities, ownership, and strategic expertise that a learner gains or demonstrates by using digital tools to gather, design, evaluate, critique, synthesize, and develop digital media artifacts, communication messages, or other electronic expressions. A primary goal of this paper is to identify promising perspectives through which learning is conceptualized, and to share the
Following on the outcomes of an NSF-funded conference to this project's principal investigator, a team of educators, scientists, and communication experts from the University of Massachusetts Lowell, University of Massachusetts Boston, Hofstra University, the Boston Museum of Science and other professionals is implementing a full-scale development project to investigate the impact of an Out-of-Home Multi-Media (OHMM) exhibit on adults riding Boston's subway system (the "T"). The project's goal is to design, implement, and study the efficacy of an OHMM model for free-choice science learning about our changing climate. A rotating exhibit of twelve specially designed placards, posters, as well as virtual, web-based learning resources linked to the exhibit content will potentially engage over 420,000 adult riders per day along two of the T's four lines. Wireless access throughout light rail systems and the rise of smart phones represent a confluence of factors making an innovative form of engagement possible. The work is positioned to test this new model for informal science education and potentially could be expanded in Boston and into other cities around the country.
This poster was presented at the 2014 AISL PI Meeting held in Washington, DC. It discusses the second season of SciGirls, a multimedia project designed to encourage and empower more girls to pursue careers in STEM.
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Twin Cities Public TelevisionRita Karl
Northeastern University will design, test, and study GrACE, a procedurally generated puzzle game for teaching computer science to middle school students, in partnership with the Northeastern Center for STEM Education and the South End Technology Center. The Principal Investigators will study the effect of computer generated games on students' development of algorithmic and computational thinking skills and their change of perception about computer science through the game's gender-inclusive, minds-on, and collaborative learning environment. The teaching method has potential to significantly advance the state of the art in both game-based learning design and yield insights for gender-inclusive teaching and learning that could have broad impact on advancing the field of computer science education. Development and evaluation of GrACE will consist of two, year-long research phases, each with its own research question. The first, design and development, phase will focus on how to design a gender-inclusive, educational puzzle game that fosters algorithmic thinking and positive attitude change towards computer science. The content generator will be created using Answer Set Programming, a powerful approach that involves the declarative specification of the design space of the puzzles. The second phase will be an evaluation that studies, by means of a mixed-methods experimental design, the effectiveness of incorporating procedural content generation into an educational game, and specifically whether such a game strategy stimulates and improves minds-on, collaborative learning. Additionally, the project will explore two core issues in developing multiplayer, collaborative educational games targeted at middle school students: what typical face-to-face interactions foster collaborative learning, and what gender differences exist in how students play and learn from the game. The project will reach approximately 100 students in the Boston area, with long-term goals of reaching students worldwide, once the game has been tested with a local audience. Results of the project will yield a new educational puzzle game that can teach algorithmic thinking and effect attitude change regarding computer science. Through the process of creating a gender-inclusive game to teach computer science, it will provide guidelines for future educational game projects. Beyond these individual project deliverables, it will improve our understanding of the potential for procedural content generation to transform education, through its development of a new technique for generating game content based on supplying educational objectives.
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Northeastern UniversityGillian SmithCasper Harteveld
Informal Community Science Investigators (iCSI) creates a network of four geographically diverse informal science institutions working together on strategies to engage youth ages 10-13 through location based augmented reality (AR) games played on smartphones. These high-interest, kid-friendly games will be used by families visiting the institutions and by youth who enroll in more intensive summer camp programs. Using AR games, participants will engage in playful but scientifically-grounded investigations drawing on each institution's research, exhibits, and natural spaces. For example, a botanical garden might engage young visitors through AR games with themes related to native and invasive species, while a zoo might create a game experience focusing on illegal wildlife trade. Participants in the iCSI summer camp program will have more intensive experiences, including work with the host institution's scientists, opportunities to develop original augmented reality games, and experiences with game-related service learning and citizen science programs. For both target groups (families and campers), the location specific games build understanding of both the institution's mission and the broader realm of scientific research and application. The project will test the notion of participants as "learner hero," the link between game play and the individual's development of competency, autonomy and the relationship to real world experience, in this case through community action on the subject of the game developed. To that end, participants will be encouraged to extend their involvement through related investigations on site and participation in community activities and projects that can be done at home. Social media tools such as Facebook and web sites managed by the host institutions will provide recognition for this extended engagement, helping participants maintain ties to the program. Additionally, program resources provide assistance to adult family members in nurturing and sustaining youth interest in STEM activities and careers. A major effort of the project will be development of a new software infrastructure called TaleBlazer for the augmented reality game that will enable teachers and students to develop their own game that incorporates real data collection and scientific model building. The new platform will enhance the game play platform MITAR developed with NSF funding.
This poster was presented at the 2014 AISL PI Meeting in Washington, DC. It describes the first year partnership to design and implement a social networking platform and digital badges with two science center programs.
This poster highlights the learning outcomes and research questions of the Advancing Informal STEM Learning Through Scientific Alternate Reality Games project. It was presented at the 2014 AISL PI Meeting.
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Brigham Young UniversityDerek HansenKari Kraus
This poster from the 2014 AISL PI Meeting summarizes the work done in the first year of a two-year project looking at using an indoor positioning system to (1) automate the collection of timing and tracking data for visitor research and (2) enable location-aware applications that enhance the visitor experience inside a museum.