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.
The Experiential Science Education Research Collaborative (XSci) at the University of Colorado Denver has established a museum educator/theater network of eight museums around the country, pairing larger with smaller institutions. The Association of Science-Technology Centers, the NASA Astrobiology Institute, and the Astronomical Society of the Pacific and several other organizations also are collaborators. The primary audience is informal science educators; secondary audiences are museum and science center visitors. The Science Theater Education Programming System (STEPS) is a technology the allows educators to create their own media-enhanced live theatrical presentations of science programs that include dynamic content, interactive virtual characters, and multiple plot-lines and endings to shows. The initial set of theater programs focus on astrobiology, along with a suite of training programs and communication formats for educators. The STEPS technology allows these programs to be delivered both on site and via outreach, depending on the goals of each organization. An in-depth research component is examining the impact of the project\'s designed community of practice structure utilizing team leadership theory in terms of professional identity construction for participating informal educators. Deliverables include: the museum partnership network, the STEPS system and programs, professional development tutorials and workshops, evaluation of the programs, and research products, among others.
The Global Viewport for Virtual Exploration of Deep-Sea Hydrothermal Vents is a Track 2 project using spherical display systems to educate the public about the global significance of vents in the world's oceans and in the dynamic processes of Earth as a whole. The project is a collaboration between the Woods Hole Oceanographic Institution and the Ocean Explorium at New Bedford Seaport, members of the Magic Planet Community and Science On a Sphere® (SOS) Network, respectively. The proximity of the two institutions enables a unique evaluation of the learning attained with a stand-alone spherical display vs. live presentations with an SOS. The new content for spherical display systems will address key principles of Earth Science Literacy and Ocean Literacy. Imagery and data from research cruises are being used to: show how hydrothermal vents link dynamic processes in the lithosphere, hydrosphere, and biosphere; promote stewardship of life in remote environments; and excite viewers about the deep ocean frontier including exploration, research, and resources. The Global Viewport project is geared towards informal science education but also includes a component for teacher professional development from schools in towns with populations underrepresented in STEM fields. An online portal for content on Google Earth enables virtual exploration of deep-sea vents from home, extending the learning experience beyond a single visit to an informal science education institution. The online content, including interactive learning modules and games, is being promoted to marine educators and scientists at national conferences and through the COSEE social network.
The MyDome project will bring 3D virtual worlds for group interaction into planetaria and portable domes. Advances in computing have evolved the planetarium dome experience from a star field and pointer presentation to a high-resolution movie covering the entire hemispherical screen. The project will further transform the dome theater experience into an interactive immersive adventure. MyDome will develop scenarios in which the audience can explore along three lines of inquiry: (1) the past with archeological reconstructions, (2) the present in a living forest, and (3) the future in a space station or colony on Mars. These scenarios will push the limits of technology in rendering believable environments of differing complexity and will also provide research data on human-centered computing as it applies to inquiry and group interactions while exploring virtual environments. The project proposes to engage a large portion of the population, with a special emphasis on the underserved and under-engaged but very tech-savvy teenage learner. Research questions addressed are: 1. What are the most engaging and educational environments to explore in full-dome? 2. What on-screen tools and presentation techniques will facilitate interactions? 3. What are the limitations for this experience using a single computer, single projector mirror projection system as found in the portable Discovery Dome? 4. Which audiences are best served by exploration of virtual hemispherical environments? 5. How large can the audience be and still be effective for the individual learner? What techniques can be used to provide more people with a level of control of the experience and does the group interaction enhance or diminish the engagement of different individuals? 6. What kind of engagement can be developed in producing scientific and climate awareness? Does experiencing past civilizations lead to more interest in other cultures? Does supported learning in the virtual forest lead to greater connection to and understanding of the real forest? Does the virtual model space experience excite students and citizens about space exploration or increase the understanding of the Earth's biosphere? The broader impacts of the project are (1) benefits to society from increasing public awareness and understanding of human relationships with the environment in past civilizations, today?s forests and climate change, and potential future civilizations in space and on Mars; (2) increasing the appeal of informal science museums to the tech-savvy teenage audience, and (3) significant gains in awareness of young people in school courses and careers in science and engineering. The partners represent a geographically diverse audience and underserved populations that include rural (University of New Hampshire), minority students (Houston Museum of Natural Science) and economically-distressed neighborhoods (Carnegie Museum of Natural History). Robust evaluation will inform each program as it is produced and refined, and will provide the needed data on the potential for learning in the interactive dome environment and on the optimal audience size for each different type of inquiry.
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TEAM MEMBERS:
Annette SchlossKerry HandronCarolyn Sumners
In August 2009, the Program Evaluation and Research Group (PERG) at Lesley University contracted with the project's PI at the University of New Hampshire (UNH) to evaluate My Dome: Defining the Computational and Cognitive Potential of Real Time Interactive Simulations in an Immersive Dome Environment, an NSF funded grant. The project focuses on creating interactive experiences in immersive virtual environments, and builds off previous work the PI and co PIs have done in developing films and immersive experiences in domes and traveling domes. The project includes staff from the Carnegie Museum
This project will develop an interactive application for spherical displays developed by NOAA called Science on a Sphere. The spheres are animated globes that can show dynamic, animated images of the atmosphere, oceans, and land of a planet. NOAA primarily uses SOS as an education and outreach tool to describe the environmental processes of Earth. Science On a Sphere was initially developed as a way to explore environmental data using new visualization techniques. There are about 70 installations of the sphere in science centers, planetariums and museums world-wide with 40 in the US. Currently the spheres only display static content. This project will extend the amount of content available and provide interactivity. The resulting application will be available to both installed spheres and those institutions thinking about purchasing and installing the sphere display. Math on a Sphere will enable users to create 3-D interactive graphic content for spheres. The project will enable users to interact with the displays they develop for the spheres either on-site or remotely. Through the use of a computer-based toolkit, users can create their own programs, build geometric patterns, and send a variety of graphical content to the spherical display. The project hypothesizes that user-directed development combined with a visually compelling spherical display will spark interest in STEM topics and specifically, in the test version, mathematical content. This project will prototype, design, implement, test, and evaluate software that allows users to display their computational work on an installed sphere as well as work remotely on the project and to test their mathematical computations by viewing the spherical display remotely either through a computer monitor or a camera view of the sphere itself. While the prototype will be developed focusing on mathematical concepts, there are clear links between the toolkit being developed to physics, meteorology, oceanography and astronomy. The project will increase the computational and spatial reasoning and thinking of the target audience of middle school and high school students. The application will be available remotely for individual users but could easily be used in classroom settings. The application can be used by teachers and museum and science center staff as well to encourage its use among users both on site and remotely. The successful demonstration of interactive 3-D display of science concepts using the Science on a Sphere installations can lead to interactive use of other large public display installations such as walls or large screen projection. This capability would extend the ability of users to derive greater use of these visually driven devices for learning STEM concepts and content.