In partnership with the University of Pennsylvania's Graduate School of Education, The Franklin Institute Science Museum will develop, test, and pilot an exportable and replicable cyberlearning exhibit using two cutting edge technologies: Augmented Reality (AR) and Virtual Reality (VR). The exhibit's conceptualization is anchored in the learning research vision of the NSF-funded workshop Cyberinfrastructure for Education and Learning for the Future (Computing Research Association, 2005). The incorporation of VR and AR technologies into the Franklin Institute's electricity and Earth science exhibits is an innovation of traditional approaches to hands-on learning and will improve the quality of the learning experience for the primary audience of families with children and elementary school groups. The project has implications for future exhibit development and more broadly, will provide new research on learning on how to incorporate cyberlearning efforts into traditional exhibits. Fifteen participating exhibit developers across the ISE field will assist in the evaluation of the new exhibit; receive training on the design and development of VR and AR exhibits for their institutions; and receive full access to the exhibit's new software for implementation at their informal learning sites. The technology applications will be developed by Carnegie Mellon University's Entertainment Technology Center--leaders in the field in Virtual Reality design and development. Front-end and formative evaluation will be overseen internally by the Franklin Institute. The Institute for Learning Innovation will conduct the summative evaluation. Research will be conducted by the University of Pennsylvania's Graduate School of Education on the effects of AR and VR technologies on exhibit learning.
This research explores how to support collaborative learning practices when science museum visitors employ their own personal mobile devices as Opportunistic User Interfaces (O-UIs) to manipulate a simulation-based museum exhibit. The sophisticated graphical capabilities of modern mobile devices have the potential to distract visitors, a phenomenon known as the heads-down effect. To study the impact of O-UI design on collaboration, a highly-dynamic "complex" O-UI was contrasted against more simplistic, "remote-control" OUI design, in the context of a cancer-treatment simulation. As expected
Studies of interactive systems in museums have raised important design considerations, but so far have failed to address sufficiently the particularities of family interaction and co-operation. This paper introduces qualitative video-based observations of Japanese families using an interactive portable guide system in a museum. Results suggest that interaction with the system is socially structured through family relationships, leading to unexpected usage. The paper highlights the necessity to more fully consider familial relationships in HCI.
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TEAM MEMBERS:
Tom HopeYoshiyuki NakamuraToru TakahashiAtsushi NobayashiShota FukuokaMasahiro HamasakiTakuichi Nishimura
Researchers at the U.C. Davis will carry out observations of museum visitors to plan for a study of how visualizations affect visitors of an Earth Sciences exhibit using 3D technology. The researchers will be able to conduct an experimental study about how much participants in an education center learn from the model of earthquakes and of a model of the Lake Tahoe basin. The researchers will conduct a quasi-experiment of a sample of 100 visitors to the center at Lake Tahoe to study their experience with visualization and learning of science. The funding for this phase of the project will include the development of audience surveys, conducting focus groups to develop types of feedback, train staff to conduct data collection, and to conduct a literature review of technology visualization.
This Communicating Research to Public Audiences project focuses on the Reedy Glacier Antarctic research of Brenda Hall (OPP 0229034) and its relevance to the residents of and visitors to Maine. Collaborators include the University of Maine, the Maine Discovery Museum, the Acadia National Park and Cadillac Mountain Sports (an environmentally active retail company with several stores around the state). The primary deliverable is the development of an interactive software program that presents information and experiences in a two-tiered concept approach -- on the Reedy Glacier and its connection to Maine and on the process of science. The software is being configured into kiosks at the three partnering organizations, into a DVD format for informal and formal settings to be distributed at cost and onto a University of Maine Climate Change web portal currently under separate development. The project web site will provide source code for the portal design so others may use it to create portals and modules of their own. The Maine Discovery Museum intends to create additional exhibitry on the topic with resources outside this proposal, and the Acadia National Park will use the programs in teacher education workshops.
In this article, Nina Simon, an experience design consultant at Museum 2.0, explores the correlation between museum and exhibit design and visitor participation. Simon suggests that increased parameters and more thoughtfully designed exhibits will yield more meaningful visitor participation.
This planning effort, a collaboration of teams at the University of Maryland, Cornell University, Carnegie Mellon University and the Sciencenter of Ithaca, deals with the development and testing of a unique methodology for educating youth in computer programming. Through a mobile robot that is cleverly disguised as a small animal, participants will learn to manipulate the system by physically moving it as well as setting variables via electronic buttons thereby learning programming and design. The eventual use of this system and methodology is in museum exhibits so preliminary survey data will be gathered from various venues that presently use less capable devices. Iterative testing will be done at the Sciencenter in its exhibits.
This planning effort, a collaboration of teams at the University of Maryland, Cornell University, Carnegie Mellon University and the Sciencenter of Ithaca, deals with the development and testing of a unique methodology for educating youth in computer programming. Through a mobile robot that is cleverly disguised as a small animal, participants will learn to manipulate the system by physically moving it as well as setting variables via electronic buttons thereby learning programming and design. The eventual use of this system and methodology is in museum exhibits so preliminary survey data will be gathered from various venues that presently use less capable devices. Iterative testing will be done at the Sciencenter in its exhibits.
The University of Southern California's Institute for Creative Technologies and the Museum of Science, Boston will create life-sized, 3-D Virtual Humans that will interact with visitors as interpretive guides and learning facilitators at science exhibits. Through the use of advanced artificial intelligence and intelligent tutoring techniques, Virtual Humans will provide a highly responsive functionality in their dialogue interpretation that will generate sophisticated interaction with visitors about the STEM content related to the exhibit. The project exemplifies how the confluence of science, technology, engineering, mathematics and education can creatively and collaboratively advance new tools and learning processes. The Virtual Human project will begin to present to the visitor a compelling, real life, interactive example of the future and of the related convergence of various interdisciplinary trends in technology, such as natural language voice recognition, mixed reality environments, para-holographic display, visitor recognition and prior activity recall, artificial intelligence, and other interdisciplinary trends. The 3-D, life-sized Virtual Humans will serve as museum educators in four capacities: 1) as a natural language dialogue-based interactive guide that can suggest exhibits to explore in specific galleries and answer questions about particular STEM content areas, such as computer science; 2) as a coach to help visitors understand and use particular interactive exhibits; 3) be the core focus of the Science behind the Virtual Humans exhibit; and 4) serve as an ongoing research effort to improve human and virtual human interactions at increasingly sophisticated levels of complexity. The deliverables will be designed to build upon visitor experiences and stimulate inquiry. A living lab enables visitors to become part of the research and development process. The project website will introduce visitors to the technologies used to build virtual humans and the research behind their implementation. The site will be augmented with videos and simulations and will generate user created content on virtual human characters. Project evaluation and research will collect language and behavioral data from visitors to inform the improvement of the virtual guide throughout the duration of the grant and to develop a database that directly supports other intelligent systems, and new interface design and development that will have broad impact across multiple fields.
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TEAM MEMBERS:
William SwartoutDavid TraumJacquelyn MorieDiane PiepolH. Chad Lane
TERC Inc. will conduct a one-year proof of concept study that includes the design, development, and research of two prototype science activities for the virtual Blue Mars Science Center located on the Blue Mars 2150 platform developed by Virtual Space Entertainment. Blue Mars is a science fiction-themed virtual world set on Mars far in the future and will be rendered in High Definition, an important incremental step in the development of highly realistic virtual worlds. It is in this virtual world context that the proposed learning activities and research are to be conducted. TERC's research will examine the challenges of learning in virtual environments and which types of tools and interactions can encourage and support collaboration, the results of which will advance both informal and formal learning in virtual worlds. Avatar tracking data, participant observations, interviews, and surveys will be used to study participants. The project has the potential to advance areas of computational visualization systems and cognitive science and will afford an array of learning opportunities using real time data. Millions of visitors to the Blue Mars world will be able to share in an unprecedented range of virtual activities and experiences. It is anticipated that the research will inform the future development of even more advanced immersive interactivity, such as avatar-based models and computationally-oriented interactivity. The study will serve as a basis for both further development of the Blue Mars Science Center and the advancement of research on science learning in virtual worlds. The investigators are interested in continuing to expand as the scientific community evolves in the virtual world. The online world has the potential to become a powerful attractor for the general public to engage in science learning.
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TEAM MEMBERS:
Jodi Asbell-ClarkeTeon EdwardsRichard Childers
The Nanomedicine Explorer kiosk at the Museum of Science, Boston provides opportunities to learn about nanomedicine, nanotechnology, cancer biology, new research in cancer diagnosis and therapy, and the process of medical research from bench to bedside. This report is the formative evaluation of the prototype of this kiosk, presenting the results of visitor observations, exit surveys, and interviews. The findings of these data served to provide the Nanomedicine Explorer production team a basis from which to make improvements to the program, which was released as Version 1.0 in May of 2009
This documents the formative evaluation of Diffusion (aka Mixing Molecules), an immersive video interactive display demonstrating the collision of molecules.