In recent years, transmedia has come into the spotlight among those creating and using media and technology for children. We believe that transmedia has the potential to be a valuable tool for expanded learning that addresses some of the challenges facing children growing up in the digital age. Produced by the USC Annenberg Innovation Lab and the Joan Ganz Cooney Center, this paper provides a much-needed guidebook to transmedia in the lives of children age 5-11 and its applications to storytelling, play, and learning. Building off of a review of the existing popular and scholarly literature
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Becky Herr-StephensonMeryl AlperErin Reilly
The Science and Math Informal Learning Education (SMILE) pathway is serving the digital resource management needs of the informal learning community. The science and math inquiry experiences offered by science and technology centers, museums, and out-of-school programs are distinct from those found in formal classrooms. Interactive exhibits, multimedia presentations, virtual environments, hands-on activities, outdoor field guides, engineering challenges, and facilitated programs are just some of the thoughtfully designed resources used by the informal learning community to make science and math concepts come alive. With an organizational framework specifically designed for informal learning resources, the SMILE pathway is empowering educators to locate and explore high-quality education materials across multiple institutions and collections. The SMILE pathway is also expanding the participation of underrepresented groups by creating an easily accessible nexus of online materials, including those specifically added to extend the reach of effective science and math education to all communities. To promote the use of the SMILE pathway and the NSDL further, project staff are creating professional development programs and a robust online community of educators and content experts to showcase best practices tied to digital resources. Finally, to guarantee continued growth and involvement in the SMILE pathway, funding and editorial support is being provided to expansion partners, beyond the founding institutions, to add new digital resources to the NSDL.
The project team is developing a prototype of a web-based game utilizing the illustrations of chemical elements and science terms created by Simon Basher in his three books, The Periodic Table: Elements with Style!, Chemistry: Getting a Big Reaction!, and Physics: Why Matter Matters! The game will incorporate augmented reality (person-to-person gameplay with the support of the software) to teach grade 4 to 6 students science concepts, including an introduction to chemistry. The game will include curriculum support materials. Pilot research in Phase I will seek to demonstrate that the software prototype functions as planned, teachers are able to integrate it within the classroom environment, and students are engaged with the prototype.
Purpose: An estimated 5 to 8% of elementary school students have some form of memory or cognitive deficit that inhibits learning basic math. Researchers have identified several areas where children with math learning difficulties struggle. These include a strong sense of number facts to quickly and accurately perform operations on single digit numbers, the use of strategies to solve problems which have not yet been memorized, a sense to figure out whether or not an answer is reasonable, and self-monitoring to assess one's own efficacy and understanding. To support students with math learning difficulties in grades 1 to 4, this project team will develop a series of apps for touch-screen tablets that encourage single digit operational fluency, conceptual understanding, strategy awareness, and self-understanding.
Project Activities: During Phase I project in 2012, the research team developed a prototype of the single digit addition game, following an iterative process incorporating feedback from teachers and students having difficulty with math. Nineteen students participated in a pilot study, and the researchers found that the prototype functioned well and that users were engaged by the game. In Phase II, the team will build and refine the back end system, design and develop the teacher website, and create content for games in subtraction, multiplication, and division. Researchers will carry out a pilot test of the usability and feasibility, fidelity of implementation, and promise of the game to improve learning. Students in first to fourth grade identified by teachers as having the greatest difficulty with math will participate in the pilot study. Half of the 120 students participating in the pilot study will be randomly selected to play the game as a supplement to classroom learning whereas the other half will not have access. Students in the control group will be provided the games at the end of the study. Analyses will compare pre- and post-test math scores.
Product: The web-based game, MathFacts, will include a series of apps for touch-screen tablet computers to support math learning for 1st to 4th grade students with major or sometimes intractable learning difficulties. In the game, students will learn content through mini-lessons, engage with problems in practice and speed rounds, and then receive formative feedback on their performance. Students will use and manipulate blocks, linker tubes, number lines, and interact with engaging pedagogical agents such as parrots and sloths. Students will set goals, advance to more challenging levels, and engage in competition. The game will be self-paced and will provide individualized formative assessment scaffolding when students do not know the answer to a question. A teacher management system will support professional development and will produce reports to guide instruction. The intended outcomes from gameplay will include increased fluency, conceptual understanding, strategy awareness, self-assessment, and motivation of basic math.
Many science communication activities identify children as their main target. There are several reasons for this, even if, quite often, they are not expressed explicitly, as if children were a somehow “natural” public for science. On the contrary, we can observe a high level of complexity in the children agenda to engage with science, and in the science institution agendas for targeting children. But this does not seem to be followed but the same level of complexity in devising science engagement activities for children. The profound transformation of the scope and understanding of science
In the last two years SISSA Medialab designed, tested and evaluated two projects aiming at empowering children (in one case) and teenagers (in the other) to act as science journalists in order to promote a personal, critical attitude towards science and technology. The two groups produced a paper magazine and a blog, respectively, in a participatory process, in which adults acted as facilitators and experts on demand, but the youths were the leaders and owners of the products. Special care was taken to ensure inclusiveness, by involving in the project children and teenagers from any social
Children’s issues have become a greater priority on political agendas since the UN General Assembly adopted the Convention on the Rights of the Child (UNCRC). Each government has agreed to ensure that all those working with and for children understand their duties in relation to upholding children’s rights including the obligation to involve children in decisions that affect them (Article 12). Respecting children’s views is not just a model of good pedagogical practice, but a legally binding obligation. However, there is a limited awareness of Article 12, and how to actualise it. While many
In the editorial of this issue of JCOM, we underline how children are on one hand one of the main target group for science communication, and on the other hand a largely excluded group in the shift from a linear diffusion model to a dialogic model of science communication. In this series of comments, stimulated by the EU - FP7-Science in society project `SiS-Catalyst - 2013 children as change agents for science in society' (a four year programme aimed at crossing the science in society and the social inclusion agendas), we would like to explore methods and approaches that can ensure that, in
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Matteo MerzagoraTricia Alegra Jenkins
This pathways project would refine and test a game based on the Kinect technology gaming tool to teach seismology concepts in an informal education setting and how they apply to phenomenon in other STEM fields. The game will be developed as a companion tool to the "Quake Catcher Network" a low-cost network of seismic sensors in schools, homes and offices world-wide and tie-ins with seismology programs such as the great California ShakeOut with a participant base of 8.6 million. The project design would select three new learning modules, chosen by a group of scientists and educators, to incorporate into the game and evaluate player experience and knowledge gain. The activities will be conducted at a partner test site, an aquarium, frequented by area youth 8 - 12 years old. The focus of the effort is to add to the knowledge of how gaming can be used effectively in informal learning environments The game places the player as a scientist, allowing the player to make decisions about seismic station deployment strategies following an earthquake, installing the sensors and monitoring incoming data. The game has levels of difficulty and players accrue points by acting swiftly and correctly. Learning goals for the project include making abstract math concepts understandable; involve participants in data collection and the process of scientific investigation, plus demonstrate how scientists and mathematicians use tools of their fields to address real-world issues.
This full scale research and development collaborative project between Smith College and Springfield Technical Community College improves technical literacy for children in the area of engineering education through the Through My Window learning environment. The instructional design of the learning environment results from the application of innovative educational approaches based on research in the learning sciences—Egan's Imaginative Education (IE) and Knowledge Building (KB). The project provides idea-centered engineering curriculum that facilitates deep learning of engineering concepts through the use of developmentally appropriate narrative and interactive multimedia via interactive forums and blogs, young adult novels (audio and text with English and Spanish versions), eight extensive tie-in activities, an offline teachers’ curriculum guide, and social network connections and electronic portfolios. Targeting traditionally underrepresented groups in engineering—especially girls—the overarching goals of the project are improving attitudes toward engineering; providing a deeper understanding of what engineering is about; supporting the development of specific engineering skills; and increasing interest in engineering careers. The project will address the following research questions: What is the quality of the knowledge building discourse? Does it get better over time? Will students, given the opportunity, extend the discourse to new areas? What scaffolding does the learning environment need to support novice participants in this discourse? Does the use of narrative influence participation in knowledge building? Are certain types of narratives more effective in influencing participation in knowledge building? Evaluative feedback for usability, value effectiveness, and ease of implementation from informal educators and leaders from the Connecticut After School Network CTASN) will be included. The evaluation will include documentation on the impact of narrative and multimedia tools in the area of engineering education. Currently, there is very little research regarding children and young teen engagement in engineering education activities using narrative as a structure to facilitate learning engineering concepts and principles. The research and activities developed from this proposed project contributes to the field of Informal Science and Engineering Education. The results from this project could impact upper elementary and middle-school aged children and members from underrepresented communities and girls in a positive way.
Kinetic City After School is a project supported by a prior NSF award that has produced over 80 activities in areas typical of after school activities such as computer games/simulations, hands-on activities, active play, and art and writing. This pathways project, KC Empower, will redesign and test five activities of the 80 activities currently developed by Kinetic City using a new approach to increase the representation of children and youth with disabilities in informal science settings. The project will test how universal design principles can be integrated with new technologies, not available when most after school STEM content was created, to address the needs of students with disabilities. The technologies used in the redesign include advanced mobile platforms and applications; search engines that sift through audio, image and video files; gaming input devices that respond to body movements; and information restructuring that allows multiple representations of content. The project will test how universal design guidelines will work with new technologies, in the short-term providing hands-on activities more accessible to students with disabilities, while increasing access for all students. The project is expected to lead to a full scale development project that will update all modules in Kinetic City After School. The target audience is 3rd - 5th grade students. The hypothesis of the project is that designing for disability can strengthen activities designed to increase science knowledge. Rather than making accommodations for persons with disabilities, it is the environment and design that are disabled, and it is better educational practice to rethink the activity from the point of view of all learners, including those with disabilities. Thus the use of universal design will address how best to present material for all users while influenced by the challenges presented by disabled users. The project includes the Coalition for Science After School, the Center for Applied Special Technology and the Afterschool Alliance.
Researchers at the American Association of Variable Star Observers, the Living Laboratory at the Boston Museum of Science, and the Adler Planetarium are studying stereoscopic (three-dimensional or 3D) visualizations so that this emerging viewing technology has an empirical basis upon which educators can build more effective informal learning experiences that promote learning and interest in science by the public. The project's research questions are: How do viewers perceive 3D visualizations compared to 2D visualizations? What do viewers learn about highly spatial scientific concepts embedded in 3D compared to 2D visualizations? How are viewers\' perceptions and learning associated with individual characteristics such as age, gender, and spatial cognition ability? Project personnel are conducting randomized, experimental mixed-methods research studies on 400 children and 1,000 adults in museum settings to compare their cognitive processing and learning after viewing two-dimensional and three-dimensional static and dynamic images of astronomical objects such as colliding galaxies. An independent evaluator is (1) collecting data on museum workers' and visitors' perceived value of 3D viewing technology within museums and planetariums and (2) establishing a preliminary collection of best practices for using 3D viewing technology based on input from museum staff and visitors, and technology creators. Spatial thinking is important for learning many domains of science. The findings produced by the Two Eyes, 3D project will researchers' understanding about the advantages and disadvantages of using stereoscopic technology to promote learning of highly spatial science concepts. The findings will help educators teach science in stereoscopic ways that mitigate problems associated with using traditional 2D materials for teaching spatial concepts and processes in a variety of educational settings and science content areas, including astronomy.