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.
Field trips to science museums can provide students with educational experiences, particularly when museum programs emphasize scientific inquiry skill building over content knowledge acquisition. We describe the creation and study of 2 programs designed to significantly enhance students' inquiry skills at any interactive science museum exhibit without the need for advanced preparation by teachers or chaperones. The programs, called Inquiry Games, utilized educational principles from the learning sciences and from visitor studies of museum field trips. A randomized experimental design compared
A team of researchers and practitioners developed a museum program to coach families in the skills of scientific inquiry at interactive exhibits. The program was inspired by the increasing focus on scientific inquiry in schools and the growing number of open-ended exhibit designs in science museums. The development process involved major decisions in two arenas: which inquiry skills to teach, and what pedagogical strategies to use to teach them. After many rounds of refinement based on evaluation with families, the final program, called Inquiry Games, improved visitors' inquiry behavior in
The overall objective of this planning project was to examine the potential effectiveness of the Signing Science Pictionary (SSP) in increasing the ability of parents and their deaf and hard of hearing children to engage in informal science learning. To achieve this objective, research and development included four goals. 1) Design several SSP-based activities to help family members engage in informal science learning. 2) Examine the potential effectiveness of the SSP in increasing family member’s signed science vocabulary. 3) Find out about the potential effectiveness of the SSP in
Intuitive Company researchers and evaluators assessed four components of the DUST Alternate Reality Game for potential reusability: 1) QTE Environment during Collapse, 2) Brain/Health Scanner Mobile App, 3) Microbe Web App, 4) Star Map Web App. We assessed reusability based on five variables (facilitation, user identification, digital access, player type, and timing) along a continuum of informal to formal learning contexts, from museums to after school programs to formal classroom settings. Our assessment revealed that the: 1. QTE Environment during the Collapse is most replayable in its
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Brigham Young University, University of MarylandJes KoepflerNidhi JalwalVictor Yocco
This volume explores how technology-supported learning environments can incorporate physical activity and interactive experiences in formal and informal education. It presents cutting-edge research and design work on a new generation of "body-centric" technologies such as wearable body sensors, GPS tracking devices, interactive display surfaces, video game controller devices, and humanlike avatars. Contributors discuss how and why each of these technologies can be used in service of learning within K-12 classrooms and at home, in museums and online. Citing examples of empirical evidence and
This article describes a transmedia learning experience for early school-aged children. The experience represented an effort to transition a primarily television-based series to a primarily web-based series. Children watched new animation, completed online activities designed to promote STEM (science, technology, engineering, and math) exploration, and participated in (and reported on) offline activities that required them to investigate real-world phenomena. Children were expected to visit the website every weekday, for four weeks, as part of the experience. A single group pre-post test
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Concord Evaluation GroupJessica AndrewsChristine Paulsen
This document is a “think piece” about why and how informal science, technology, engineering, and math (STEM) education institutions could be placing amusing, novel experiences in people’s paths to create memorable STEM experiences embedded in their everyday lives. The report focuses on what we learned about creating interactive STEM exhibits in public spaces outside of a science center. That said, the content can inform hands-on learning experiences on other topics, as well, within the limits outlined.
Rockman et al (REA), in partnership with Marti Louw and the University of Pittsburgh Center for Learning in Out-of-School Environments (UPCLOSE), conducted a summative evaluation in Fall 2012-Spring 2013 of a temporary museum exhibition at the Carnegie Museum of Natural History (CMNH) in Pittsburgh, PA called, Stories in the Rock. The exhibition highlighted CMNH researchers’ documentation of ancient petroglyph sites in Saudi Arabia using GigaPan technology to capture high-resolution, zoomable images of the rock art. The exhibition centers around an activity called the Explorable Image, a
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University of Pittsburgh Center for Learning in Out-of-School EnvironmentsCamellia Sanford-Dolly
The Lemelson Center for the Study of Invention and Innovation at the Smithsonian’s National Museum of American History (NMAH) contracted Randi Korn & Associates, Inc. (RK&A) to conduct a formative evaluation for Places of Invention, an exhibition funded by the National Science Foundation. The study explored visitors’ use and interpretation of the prototypes (including barriers to use and interpretation), understanding of the relationships among people-place-invention and 21st century skills, and interpretation of what the Places of Invention exhibition is about. How did we approach this study
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Lemelson Center for the Study of Invention and InnovationRandi KornEmily CraigAmanda KrantzNational Museum of American HistorySmithsonian Institution
The project will develop and study the impact of science simulations, referred to as sims, on middle school childrens' understanding of science and the scientific process. The project will investigate: 1) how characteristics of simulation design (e.g., interface design, visual representations, dynamic feedback, and the implicit scaffolding within the simulation) influence engagement and learning and how responses to these design features vary across grade-level and diverse populations; 2) how various models of instructional integration of a simulation affect how students interact with the simulation, what they learn, and their preparation for future learning; 3) how these interactions vary across grade-level and diverse populations; and 4) what critical instructional features, particularly in the type and level of scaffolding, are needed. Working with teachers, the team will select 25 existing sims for study. Teachers and students will be interviewed to test for usability, engagement, interpretation, and learning across content areas. The goal will be to identify successful design alternatives and to formulate generalized design guidelines. In parallel, pull-out and classroom-based studies will investigate a variety of use models and their impact on learning. Ten new simulations will then be developed to test these guidelines. Products will include the 35 sims with related support materials available for free from a website; new technologies to collect real-time data on student use of sims; and guidelines for the development of sims for this age population. The team will also publish research on how students learn from sims.
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Katherine PerkinsDaniel SchwartzMichael DubsonNoah Podolefsky
This project will study two emerging and innovative technologies: interactive, dynamic simulations and touch-based tablet devices. The use of touch-based tablet technology (e.g., iPads) in the classroom is rapidly increasing, though little research has been done to understand effective implementation for learning science. Interactive simulations are now in use across K-16 levels of education, though what impact tablet devices have on the effective implementation of science simulations is not yet known. This project will explore this new frontier in education, over a range of contexts, providing new insight into effective interactive simulation design, classroom facilitation techniques, and the effects of tablet-based simulation use on underrepresented populations in STEM courses. Together, Dr. Emily Moore (PhET, UCB), a leader in interactive simulation design and classroom use, and Dr. Roy Tasker of the University of Western Sydney (UWS), a leader in chemistry education research, science visualizations, and teaching with technology, will research on the new technology frontier in science education - laying the groundwork for future investigations of foundational questions in technology use for learning science. This work has great potential to transform the future of science learning, making it both more engaging and more effective for diverse populations. The research findings will immediately impact 1) the design of new and existing PhET simulations - reaching millions of students and teachers using PhET simulations worldwide - and 2) the development of best practices guidelines for teachers using tablet technology to increase student learning, engagement, and participation in STEM disciplines.