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.
This paper describes a platform for sharing programmable media on the web called ScratchR. As the backbone of an on-line community of creative learners, ScratchR will give members access to an audience and inspirational ideas from each other. ScratchR seeks to support different states of participation: from passive consumption to active creation. This platform is being evaluated with a group of middle-school students and a larger community of beta testers.
The focus of this paper is to turn our attention to the arts as an understudied area within the computer-supported collaborative learning community and examine how studying the learning of arts and programming can open new avenues of research. We document, describe, and analyze urban youths’ media arts practices within the context of the design studio, particularly by focusing on how collaboration, computation, and creativity play out within this context. We utilize a mixed methods design that draws upon three approaches: (1) participant observations; (2) media arts object analyses; and (3)
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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TEAM MEMBERS:
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.
The PhET Interactive Simulations group at the University of Colorado is expanding their expertise of physics simulations to the development of eight-to-ten simulations designed to enhance students' content learning in general chemistry courses. The simulations are being created to provide highly engaging learning environments which connect real life phenomena to the underlying science, provide dynamic interactivity and feedback, and scaffold inquiry by what is displayed and controlled. In a second strand of the project, a group of experienced faculty participants are developing and testing lecture materials, classroom activities, and homework, all coordinated with well-established, research-based teaching methods like clicker questions, peer instruction, and/or tutorial-style activities, to leverage learning gains in conjunction with the simulations. The third strand of the project focuses on research on classroom implementation, including measures of student learning and engagement, and research on simulation design. This strand is establishing how specific characteristics of chemistry sim design influence engagement and learning, how various models of instructional integration of the sims affect classroom environments as well as learning and engagement, and how sim design and classroom context factors impact faculty use of sims. To ensure success the project is basing sim design on educational research, utilizing high-level software professionals (to ensure technically sophisticated software, graphics, and interfaces) working hand-in-hand with chemistry education researchers, and is using the established PhET team to cycle through coding, testing, and refinement towards a goal of an effective and user friendly sim. The collection of simulations, classroom materials, and faculty support resources form a suite of free, web-based resources that anyone can use to improve teaching and learning in chemistry. The simulations are promoting deep conceptual understanding and increasing positive attitudes about science and technology which in turn is leading to improved education for students in introductory chemistry courses both in the United States and around the world.
The Physics and Chemistry Education Technology (PhET) Project is developing an extensive suite of online, highly-interactive simulations, with supporting materials and activities for improving both the teaching and learning of physics and chemistry. There are currently over 70 simulations and over 250 associated activities available for use from the PhET website (http://phet.colorado.edu). These web-based resources are impacting large number of students. Per year, there are currently over 4 million PhET simulations run online and thousands of full website downloads for offline use of the simulations. The goal is that this widespread use of PhET's research-based tools and resources will improve the education of students in physics and chemistry at colleges and high schools throughout the U.S. and around the world. This PhET project combines a unique set of features. First, the simulation designs and goals are based on educational research. Second, using a team of professional programmers, disciplinary experts, and education research specialists enables the development of simulations involving technically-sophisticated software, graphics, and interfaces that are highly effective. Third, the simulations embody the predictive visual models of expert scientists, allowing many interesting advanced concepts to become widely accessible and revealing their relevance to the real world. And finally, the project is actively involved in research to better understand how the design and use of simulations impacts their effectiveness - e.g. investigating questions such as "How can these new technologies promote student understanding of complex scientific phenomena?" and "What factors inhibit or enhance their use and effectiveness?".
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TEAM MEMBERS:
Katherine PerkinsMichael DubsonNoah FinkelsteinRobert ParsonCarl Weiman
Based on work in media studies, new literacy studies, applied linguistics, the arts and empirical research on the experiences of urban youths’ informal media arts practices we articulate a new vision for media education in the digital age that encompasses new genres, convergence, media mixes, and participation. We first outline the history of how students’ creative production has been used to meet the goals of media educators and highlight new trends in media education that are instructive for creative production. Our goal is to introduce and situate the new ways in which youth are
In this paper we articulate an alternative approach to look at video games and learning to become a creator and contributor in the digital culture. Previous discussions have focused mostly on playing games and learning. Here, we discuss game making approaches and their benefits for illuminating game preferences and learning both software design and other academic content. We report on an ongoing ethnographic study that documents youth producing video games in a community design studio. We illustrate how video game making can provide a context for addressing issues of participation
This paper argues that the "kindergarten approach to learning" – characterized by a spiraling cycle of Imagine, Create, Play, Share, Reflect, and back to Imagine – is ideally suited to the needs of the 21st century, helping learners develop the creative-thinking skills that are critical to success and satisfaction in today’s society. The paper discusses strategies for designing new technologies that encourage and support kindergarten-style learning, building on the success of traditional kindergarten materials and activities, but extending to learners of all ages, helping them continue to
In today's rapidly changing world, people must continually come up with creative solutions to unexpected problems. Success is based not only on what one knows or how much one knows, but on one's ability to think and act creatively. In short, people are now living in the Creative Society. Unfortunately, few of today's classrooms focus on helping students develop as creative thinkers. In addition, the proliferation of new technologies is quickening the pace of change, accentuating the need for creative thinking in all aspects of people's lives. In this article, the author discusses two
Media Arts within primary and secondary education is a relatively new avenue of research. Within the context of the arts classroom, rarely is learning to program emphasized despite its importance for creative expression in a digital medium. We present outcomes from an extensive field study at a digital studio where youth accessed programming environments emphasizing graphic, music and video. Learning the language of creative coding is essential to expression in a digital medium — one with increasing importance for youth and society at large. Here, we argue that it’s not just in the viewing or