A recent report by the Association for Computing Machinery estimates that by decade's end, half of all STEM jobs in the United States will be in computing. Yet, the participation of women and underrepresented groups in post-secondary computer science programs remains discouragingly and persistently low. One of the most important findings from research in computer science education is the degree to which informal experiences with computers (at many ages and in many settings) shape young people's trajectories through high school and into undergraduate degree programs. Just as early language and mathematics literacy begins at home and is reinforced throughout childhood through a variety of experiences both in school and out, for reasons of diversity and competency, formal experiences with computational literacy alone are insufficient for developing the next generation of scientists, engineers, and citizens. Thus, this CAREER program of research seeks to contribute to a conceptual and design framework to rethink computational literacy in informal environments in an effort to engage a broad and diverse audience. It builds on the concept of cultural forms to understand existing computational literacy practices across a variety of learning settings and to contribute innovative technology designs. As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds new approaches to and evidence-based understanding of the design and development of STEM learning in these settings. This CAREER program of research seeks to understand the role of cultural forms in informal computational learning experiences and to develop a theoretically grounded approach for designing such experiences for youth. This work starts from the premise that new forms of computational literacy will be born from existing cultural forms of literacy and numeracy (i.e., for mathematical literacy there are forms like counting songs -- "10 little ducks went out to play"). Many of these forms play out in homes between parents and children, in schools between teachers and students, and in all sorts of other place between friends and siblings. This program of study is a three-phased design and development effort focused on key research questions that include understanding (1) how cultural forms can help shape audience experiences in informal learning environments; (2) how different cultural forms interact with youth's identity-related needs and motivations; and (3) how new types of computational literacy experiences based on these forms can be created. Each phase includes inductive research that attempts to understand computational literacy as it exists in the world and a design phase guided by concrete learning objectives that address specific aspects of computational literacy. Data collection strategies will include naturalist observation, semi-structured, and in-depth interviews, and learning assessments; outcome measures will center on voluntary engagement, motivation, and persistence around the learning experiences. The contexts for research and design will be museums, homes, and afterschool programs. This research builds on a decade of experience by the PI in designing and studying computational literacy experiences across a range of learning settings including museums, homes, out-of-school programs, and classrooms. Engaging a broad and diverse audience in the future of STEM computing fields is an urgent priority of the US education system, both in schools and beyond. This project would complement substantial existing efforts to promote in-school computational literacy and, if successful, help bring about a more representative, computationally empowered citizenry. The integrated education plan supports the training and mentoring of graduate and undergraduate students in emerging research methods at the intersection of the learning sciences, computer science, and human-computer interaction. This work will also develop publically available learning experiences potentially impacting thousands of youth. These experiences will be available in museums, on the Web, and through App stores.
The University of Pittsburgh's Center for Learning in Out-of-School Environments, the Carnegie Museum of Natural History, and the Robotics Institute at Carnegie Mellon University are building an open access cyberlearning infrastructure that employs super high-resolution gigapixel images as a tool to support public understanding, participation, and engagement with science. Networked, gigapixel image technology is an information and communication technology that creates zoomable images that viewers can explore, share, and discuss. The technology presents visual information of scientifically important content in such detail that it can be used to promote both scientific discovery and education. The purpose of the project is to make gigapixel technology accessible and usable for informal science educators and scientists by developing a robotic imaging device and online services for the creation, storage, and sharing of billion-pixel images of scientifically important content that can be analyzed visually. Project personnel are conducting design activities, user studies, and formative evaluation studies to support the development of a gigapan technology platform for demonstration and further prototyping. The project builds on and leverages existing technologies to provide informal science education organizations use of gigapixel technology for the purpose of facilitating three types of activities that promote participatory learning by the public--Public Understanding of Science activities; Public Participation in Scientific Research activities; and Public Engagement in Science activities. The long-terms goals of the work are to (1) create an accessible database of gigapixel images that informal science educators can use to facilitate public-scientist interactions and promote participatory science learning, (2) characterize and demonstrate the affordances of networked gigapixel technologies to support socially-mediated, science-focused cyberlearning experiences, (3) generate knowledge about how gigapixel technology can enable three types of learning interactions between scientists and the public around visual data, and (4) disseminate findings that describe the design, implementation, and evaluation of the gigapixel platform to support participatory science learning. The project's long-term strategic impacts include guiding the design of high-resolution images for promoting STEM learning in both informal and formal settings, developing an open educational resource and science communication platform, and informing informal science educators about the use and effectiveness of gigapixel images in promoting participatory science learning by the public.
The Cyberlearning and Future Learning Technologies Program funds efforts that support envisioning the future of learning technologies and advance what we know about how people learn in technology-rich environments. Development and Implementation (DIP) Projects build on proof-of-concept work that shows the possibilities of the proposed new type of learning technology, and PI teams build and refine a minimally-viable example of their proposed innovation that allows them to understand how such technology should be designed and used in the future and that allows them to answer questions about how people learn, how to foster or assess learning, and/or how to design for learning. This project is building and studying a new type of online learning community. The WeatherBlur community allows kids, teachers, scientists, fishermen/fisherwomen, and community members to learn and do science together related to the local impacts of weather and climate on their coastal communities. Members of the community propose investigations, collect and share data, and learn together. WeatherBlur is designed to be a new form of knowledge-building community, the Non-Hierarchical Online Learning Community. Unlike other citizen science efforts, there is an emphasis on having all members of the community able to propose and carry out investigations (and not just help collect data for investigations designed by expert scientists or teachers). Prior research has demonstrated important structural differences in WeatherBlur from other citizen science learning communities. The project will use social network analysis and discourse analysis to measure learning processes, and Personal Meaning Mapping and embedded assessments of science epistemology and graph interpretation skills to examine outcomes. The measures will be used to explore knowledge-building processes and the scaffolds required to support them, the negotiation of explanations and investigations across roles, and the epistemic features that drive this negotiation process. The work will be conducted using an iterative design-based research process in which the prior functioning WeatherBlur site will be enhanced with new automated prompt and notification systems that support the non-hierarchical nature of the community, as well as tools to embed assessment prompts that will gauge participants' data interpretation skills and epistemic beliefs. Exponential random graph modeling will be used to analyze the social network analysis data and test hypotheses about the relationship between social structures and outcomes.
The Next Generation Science Standards (NGSS) identify an ambitious progression for learning energy, beginning in elementary school. To help the nation's teachers address this challenge, this project will develop and investigate the opportunities and limitations of Focus on Energy, a professional development (PD) system for elementary teachers (grades 3-5). The PD will contain: resources that will help teachers to interpret, evaluate and cultivate students' ideas about energy; classroom activities to help them to identify, track and represent energy forms and flows; and supports to help them in engaging students in these activities. Teachers will receive the science and pedagogical content knowledge they need to teach about energy in a crosscutting way across all their science curricula; students will be intellectually engaged in the practice of developing, testing, and revising a model of energy they can use to describe phenomena both in school and in their everyday lives; and formative assessment will guide the moment-by-moment advancement of students' ideas about energy. This project will develop and test a scalable model of PD that will enhance the ability of in-service early elementary teachers to help students learn energy concepts by coordinating formative assessment, face-to-face and web-based PD activities. Researchers will develop and iteratively refine tools to assess both teacher and student energy reasoning strategies. The goals of the project include (1) teachers' increased facility with, and disciplined application of, representations and energy reasoning to make sense of everyday phenomena in terms of energy; (2) teachers' increased ability to interpret student representations and ideas about energy to make instructional decisions; and (3) students' improved use of representations and energy reasoning to develop and refine models that describe energy forms and flows associated with everyday phenomena. The web-based product will contain: a set of formative assessments to help teachers to interpret student ideas about energy based on the Facets model; a series of classroom tested activities to introduce the Energy Tracking Lens (method to explore energy concept using multiple representations); and videos of classroom exemplars as well as scientists thinking out loud while using the Energy Tracking Lens. The project will refine the existing PD and build a system that supports online implementation by constructing a facilitator's guide so that the online community can run with one facilitator.
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TEAM MEMBERS:
Sara LacyRoger TobinNathaniel BrownStamatis VokosRachel ScherrKara GrayLane SeeleyAmy Robertson
This is the final report of the Open University’s RCUK-funded Public Engagement with Research Catalyst, ‘An open research university’, a project designed to create the conditions in which engaged research can flourish. The report describes an evidence-based strategy designed to embed engaged research within the University’s strategic planning for research and the operational practices of researchers. This programme of organisational change was informed by action research, working collaboratively with researchers at all levels across the institution to identify and implement strategies that
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TEAM MEMBERS:
Richard HollimanAnne AdamsTim BlackmanTrevor CollinsGareth DaviesSally DibbAnn GrandRichard HoltiFiona McKerlieNick MahonyNick Mahony
Family groups comprise a significant percentage of the museum visitor population, and many programs are created specifically for young learners (Borun, 2008). One such learning environment is that of planetaria, where both live and pre-recorded programs are presented to introduce concepts in Earth and Space Science to young children. Pacific Science Center’s Preschool Trip to the Moon live, interactive planetarium program was used as a context for exploring families’ motivations for attending a planetarium show, their reactions to the show, and in particular what children learned from the show
This document contains a summary of notes from an Open Space session on Media, Technology, and Informal Learning from the 2014 AISL PI Meeting. It includes a list of active AISL projects related to media.
There are a number of places evaluators can share their reports with each other, such as the American Evaluation Association’s eLibrary, the website informalscience.org, and organizations’ own websites. Even though opportunities to share reports online are increasing, the evaluation field lacks guidance on what to include in evaluation reports meant for an evaluator audience. If the evaluation field wants to learn from evaluation reports posted to online repositories, how can evaluators help to ensure the reports they share are useful to this audience? This paper explores this question through
Informal science education creates opportunities for the general public to learn about complex health and science topics. Tissue engineering is a fast-growing field of medical science that combines advanced chemistries to create synthetic scaffolds, stem cells, and growth factors that individually or in combination can support the bodies own healing powers to remedy a range of maladies. Health literacy about this topic is increasingly important as our population ages and as treatments become more technologically advanced. We are using a science center planetarium as a projection space to
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Anna WilsonLaura GonzalezJohn Pollock
Public Television station WQED/Pittsburgh, in partnership with five medical research and clinical centers, proposes to develop, test and distribute a national biomedical video education program based on "The Universe Within," a planned PBS series. The project is intended to bring scientists and clinicians into closer contact with pre-college students to study human body systems and increase career interest in the life sciences. Designed to improve science education and literacy, the project will also enhance overall appreciation of achievements in biomedicine. Using advanced television, photographic and animation techniques, the project will create a collection of educational tools for use by science and health teachers as well as by scientific investigators and clinicians. These modules will demonstrate how most of the body's primary systems function and how they can be kept healthy. The approach will combine visual and print curriculum materials with the personal presence of medical scientists, thus providing an opportunity for students to develop interest, critical thinking and problem-solving skills. This flexible educational package can be updated as important new changes occur in medical science, thus extending the life of costly materials. In addition, through multiple narration tracks, the video elements can be customized for various levels of age and grade instruction.
The investigators address a major educational challenge by introducing a novel format and content for science education, (a) building on past successes; (b) combining development and dissemination at a new level; and (c) centered around an interactive planetarium show aimed to inform the public on an emerging scientific discipline and medical field: Tissue Engineering. For achieving a multitude of goals, the investigators propose the establishment of a unique partnership in scientific and medical education, bringing together university researchers, clinical leaders, science center experts, and students, educators and community representatives at all levels. The project is catalyzed by the Pittsburgh Tissue Engineering Initiative, a non-profit organization dedicated to the promotion of tissue engineering and its application to improving people's lives. The main goals fall in three categories, as follows: Education: - To communicate scientific information about the human body (principles of function will be emphasized over specific facts or terminology by focusing on a limited but fundamental set). -To convey the excitement and importance of tissue engineering research. The show will utilize engaging interactive demonstrations of tissue functions and illustrate the medical uses and potential of this field. Innovation: - To enhance the educational experience. The developers will use group-interactive technology as a tool for education by engaging participants as participants in the processing functions of the body. A special visualization/interactivity laboratory will be used where prototype interactive scenarios will be tested using focus groups, consultants and representatives of the target audiences. Dissemination: - To insure national distribution to other planetaria. The presentation system will utilize portable interactive technology (to be developed). It will be deployed to planetaria throughout the country, coordinated by the Association of Science and Techology Centers (ASTC). - To engage the target audience in the development process. Content development will be achieved by a consortium of leading research universities and medical centers, with input from a panel of worldclass experts. Visualization, interactivity and sound technologies will be developed in Pittsburgh, in a unique collaboration between the arts and sciences, based on past successes. Evaluation activities will be extensive, as will the range and targets of the spin-off educational materials. The Carnegie Science Center planetarium itself will serve in achieving group immersive visualization, akin to virtual reality, for improving target audience involvement. The expected outcome is a new way of delivering educational content, and a better understanding of the emerging field of tissue engineering by the general public.
This evaluation examines visitor engagement at the “Science On a Sphere” (SOS) exhibit at Pacific Science Center, Seattle, WA. Evaluators varied characteristics of the data presentation—such as topic presented, presence of a question prompt, and image rotation—and measured the resulting visitor engagement for each of the different treatments. Furthermore, the evaluation examined visitors’ interest in the SOS exhibit, as well as the extent to which visitors connect the exhibit to surrounding exhibits. This study examines different treatments to the SOS exhibit to determine the presentation
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University of Washington | Pacific Science CenterDylan HighDanielle AcheampongEllie KleinwortTravis Windleharth