The Environmental Scientist-in-Residence Program will leverage NOAA s scientific assets and personnel by combining them with the creativity and educational knowledge of the pioneer hands-on science center. To do this, the program will embed NOAA scientists in a public education laboratory at the Exploratorium. Working closely with youth Explainers, exhibit developers, and Web and interactive media producers at the Exploratorium, NOAA scientists will share instruments, data, and their professional expertise with a variety of public audiences inside the museum and on the Web. At the same time the scientists will gain valuable skills in informal science communication and education. Through cutting-edge iPad displays, screen-based visualizations, data-enriched maps and sensor displays, and innovative interactions with visitors on the museum floor, this learning laboratory will enable NOAA scientists and Exploratorium staff to investigate new hands-on techniques for engaging the public in NOAA s environmental research and monitoring efforts.
Investigators from the MIT Media Lab will develop and study a new generation of the Scratch programming platform, designed to help young people learn to think creatively, reason systematically, and work collaboratively -- essential skills for success in the 21st century. With Scratch, young people (ages 8 and up) can program their own interactive stories, games, animations, and simulations, then share their creations with others online. Young people around the world have already shared more than 1 million projects on the Scratch community website (http://scratch.mit.edu). The new generation, called Scratch 2.0, will be fully integrated into the Internet, so that young people can more seamlessly share and collaborate on projects, access online data, and program interactions with social media. The research is divided into two strands: (1) Technological infrastructure for creative collaboration. With Scratch 2.0, people will be able to design and program new types of web-based interactions and services. For example, they will be able to program interactions with social-media websites (such as Facebook), create visualizations with online data, and program their own collaborative applications. (2) Design experiments for creative collaboration. As the team develops Scratch 2.0, they will run online experiments to study how their design decisions influence the ways in which people collaborate on creative projects, as well as their attitudes towards collaboration. This work builds on a previous NSF grant (ITR-0325828) that supported the development of Scratch. Since its public launch in 2007, Scratch has become a vibrant online community, in which young people program and share interactive stories, games, animations, and simulations - and, in the process, learn important computational concepts and strategies for designing, problem solving, and collaborating. Each day, members of the Scratch community upload nearly 1500 new Scratch projects to the website - on average, a new project almost every minute. In developing Scratch 2.0, the team will focus on two questions from the NSF Program Solicitation: (1) Will the research lead to the development of new technologies to support human creativity? (2) Will the research lead to innovative educational approaches in computer science, science, or engineering that reward creativity? Intellectual Merit: The intellectual merit of the project is based on its study of how new technologies can foster creativity and collaboration. The investigators will conduct design experiments to examine how new features of Scratch 2.0 engage young people in new forms of creative expression, collaboration, learning, and metadesign. Young people are already interacting with many cloud-based services (such as YouTube and Facebook). But Scratch 2.0 is fundamentally different in that it aims to engage people in programming their own projects and activities in the cloud. With Scratch 2.0, young people won?t just interact with the cloud, they will create in the cloud. The goal is to democratize the development of cloud-based activities, so that everyone can become an active contributor to the cloud, not just a consumer of cloud-based services. This development and study of Scratch 2.0 will lead to new insights into strategies for engaging young people in activities that cultivate collaboration and creativity. Broader Impacts: The broader impact of the project is based on its ability to broaden participation in programming and computer science. The current version of Scratch has already helped attract a broader diversity of students to computer science compared to other programming platforms. The investigators expect that the collaboration and social-media features of Scratch 2.0 will resonate with the interests of today's youth and further broaden participation. Integration of Scratch into the introductory computer science course at Harvard led to a sharp reduction in the number of students dropping the course, and an increase in the retention of female students. There have been similar results in pre-college courses. The National Center for Women & Information Technology (NCWIT) calls Scratch a ?promising practice? for increasing gender diversity in IT.
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Mitchel ResnickNatalie RuskJohn Maloney
The Jackprot is a didactic slot machine simulation that illustrates how mutation rate coupled with natural selection can interact to generate highly specialized proteins. Conceptualized by Guillermo Paz-y-Miño C., Avelina Espinosa, and Chunyan Y. Bai (New England Center for the Public Understanding of Science, Roger Williams University and the University of Massachusetts, Dartmouth), the Jackprot uses simplified slot-machine probability principles to demonstrate how mutation rate coupled with natural selection suffice to explain the origin and evolution of highly specialized proteins. The
Exposing American K-12 students to science, technology, engineering, and math (STEM) content is a national initiative. Game Design Through Mentoring and Collaboration targets students from underserved communities and uses their interest in video games as a way to introduce science, technology, engineering, and math topics. This article describes a Game Design Through Mentoring and Collaboration summer program for 16 high school students and 3 college student mentors who collaborated with a science subject matter expert. After four weeks, most students produced 2-D video games with themes based
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Neda KhaliliKimberly SheridanAsia WilliamsKevin ClarkMelanie Stegman
This implementation study explores middle school, high school and community college student experiences in Globaloria, an educational pilot program of game design offered in schools within the U.S. state of West Virginia, supported by a non-profit organization based in New York City called the World Wide Workshop Foundation. This study reports on student engagement, meaning making and critique of the program, in their own words. The study's data source was a mid-program student feedback survey implemented in Pilot Year 2 (2008/2009) of the 5 year design-based research initiative, in which the
This book reviews the available research on learning science through interaction with digital simulations and games. It considers the potential of digital games and simulations to contribute to learning science in schools, in informal out-of-school settings, and everyday life. The book also identifies the areas in which more research and research-based development is needed to fully capitalize on this potential.
For the past twenty years there has been a slow trickle of research disseminated through a variety of channels on the natureand use of computer interactives within museum and gallery environments. This research has yet to be consolidated into arobust and coherent evidence base for considering and understanding the continued investment in such interactives byinstitutions.Simultaneously however, the technology has changed almost beyond recognition from early kiosk-based computer exhibitsfeaturing mostly film and audio content, through to the newer generation of multi-touch interfaces being
New mobile devices with large multi-touch displays, such as the iPad, have brought revolutionary changes to ways users interact with computers. Instead of traditional input devices such as keyboards, touchpads and mice, multi-touch gestures are used as the primary means of interacting with mobile devices. Surprisingly, body-motion gestures are evolving to become a new, natural, and effective way for game players to interact with game consoles in a very similar fashion: in Kinect for Xbox 360, a controller-free gaming experience is made possible by using body-motion gestures to play games.
The Cryptoclub: Cryptography and Mathematics Afterschool and Online is a five-year project designed to introduce middle school students across the country to cryptography and mathematics. Project partners include the Young Peoples Project (YPP), the Museum of Science and Industry in Chicago, and Eduweb, an award-winning educational software design and development firm. The intended impacts on youth are to improve knowledge and interest in cryptography, increase skills in mathematics, and improve attitudes towards mathematics. The secondary audience is leaders in afterschool programs who will gain an increased awareness of cryptography as a tool for teaching mathematics and adopt the program for use in their afterschool programs. Project deliverables include online activities, online cryptography adventure games, interactive offline games, a leader\'s manual, and training workshops for afterschool leaders. The project materials will be developed in collaboration with YPP staff and pilot tested in Year 3 at local afterschool programs and YPP sites in Chicago in addition to four national sites. Field testing and dissemination occurs in Year 4 at both local sites in Chicago and national locations such as afterschool programs, science centers, and community programs. Six 3-day training workshops will be provided (2 per year in Years 3-5) to train afterschool leaders. It is anticipated that this project will reach up to 11,000 youth, including underserved youth in urban settings, and 275 professional staff. Strategic impact resulting from this project includes increased awareness of cryptography as a STEM topic with connections to mathematics as well a greater understanding of effective strategies for integrating and supporting web-based and offline activities within informal learning settings. The Cryptoclub project has the potential to have a transformative impact on youth and their understanding of cryptography and may serve as a national model for partnerships between afterschool and mentoring programs.
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Janet BeissingerSusan GoldmanDaria TsoupikovaBonnine Saunders
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.
In this full-scale research and development project, Oregon State University (OSU), Oregon Sea Grant (OSG) and the Hatfield Marine Science Center Visitors Center (HMSCVC) is designing, developing, implementing, researching and evaluating a cyberlaboratory in a museum setting. The cyberlaboratory will provide three earth and marine science learning experiences with research and evaluation interwoven with visitor experiences. The research platform will focus on: 1) a climate change exhibit that will enable research on identity, values and opinion; 2) a wave tank exhibit that will enable research on group dynamics and problem solving in interactive engineering challenges; and 3) remote sensing exhibits that will enable research on visitor interactions through the use of real data and simulations. This project will provide the informal science educaton community with a suite of tools to evaluate learning experiences with emerging technologies using an iterative process. The team will also make available to the informal science community their answers to the following research questions: For the climate change exhibit, "To what extent does customizing content delivery based on real-time visitor input promote learning?" For the wave tank exhibit, "To what extent do opportunities to reflect on and share experiences promote STEM reasoning processes at a build-and-test exhibit?" For the data-sensing exhibit, "Can visitors' abilities to explain or use visualizations be improved by shaping their visual searches of images?" Mixed-methods using interviews, surveys, behavioral instruments, and participant observations will be used to evaluate the overall program. Approximately 60-100 informal science education professionals will discuss and test the viability of the exhibit's evaluation tools. More than 150,000 visitors, along with community members and local middle and high school students, will have the opportunity to participate in the learning experiences at the HMSCVC. This work contributes to the fields of cyberlearning and informal science education. This project provides the informal science education field with important knowledge about learning, customized content delivery and evaluation tools that are used in informal science settings.
This is a proposal for a 3 year, $1,297,456 project to be conducted as collaboration among 5 higher education institutions and one school system across the country, with St. Joseph's University in Philadelphia, PA serving as the lead institution (other collaborators are from Colorado School of Mines, Ithaca College, Santa Clara University, Duke University, and Virginia Beach School System). The primary goal is to attract and retain students in computer science, especially women and underrepresented minorities (including two EPSCoR states). To this end, the project will use Alice, a software program that utilizes 3-D visualization methods, as a medium to create a high-level of interest in computer graphics, animation, and storytelling among high school students, hence to build understanding of object-based programming. Such an IT focus on media and animation is aligned with national computer science standards. The project will build a network of college and high school faculty, who will offer workshops and provide continuing support during the academic year. In each site, pairs of teachers from each participating school (total = 90) will learn with university faculty via a 3-week summer program in which an introduction to using Alice for teaching will be followed by teacher development of materials for students that will then be used to teach high school students. An experimental start at one site will be followed by implementation at four additional sites and culminated with revised implementation at the sixth site (1-4-1 design).