Iridescent is a not-for-profit company that develops and implements informal science and engineering experiences for students by facilitating the translation of the work that scientists and engineers do in a way that makes that work accessible to families. The proposal expands the Iridescent outreach activities funded by the Office of Naval Research, to provide a blended combination of in-person and online support to the families of underrepresented populations. The project is producing twenty videos of scientists and engineers presenting their research that are closely aligned with one hundred scientific inquiry and engineering design-based experiments and lesson plans. These digital resources, collectively called the Curiosity Machine, provide opportunities for parents and children to engage in scientific inquiry and engineering design in multiple face-to-face and online environments, including mobile technologies. The evaluation findings from this project provide a model of how to engage STEM education practitioners, teachers and online communities, to substantively connect underserved communities, in both informal and more formal learning environments to develop experiences with engineering design and to improve students' perspectives about and motivations to prepare for STEM careers. The Curiosity Machine portal is designed to present scientists and engineers explaining the work that they do in a way that makes it accessible to parents and students. Iridescent is working at three sites across the country in South Los Angeles, the South Bronx in New York City, and San Francisco. Students and their families have multiple access points to the science and engineering videos and materials through after school activities, Family Science Nights and summer camps. The project is piloting the use of electronic badges, similar to those offered in the Boy and Girl Scouts as a mechanism to enhance the engagement and persistence of students in the online activities. The project is developing ways to evaluate student engagement and performance through the analysis of the products that students submit online in response to particular science and engineering challenges. Students can also gain extra credit at school for their participation in the Curiosity Machine activities. The materials that the Curiosity Machine activities and challenges use are those that are commonly available to families, and the project provides access to mobile technology to facilitate participation by families. Student access to out of school science and engineering experiences is limited by the resources in terms of time and availability science centers have available. This project develops the resources and tools to bridge the in-school and out of school activities for students through the use of videos and online participation in ways that expand the opportunity of students from underserved populations to continue to engage in substantive science and engineering experiences beyond what they might get during an intermittent visit to a science center. The research and evaluation that is part of this study provides information about how new forms of extrinsic motivation might be used to support student engagement and persistence in learning about science and engineering.
This evaluation reports on the Mission: Solar System project, a 2-year project funded by NASA. The goal of the Mission: Solar System was to create a collection of resources that integrates digital media with hands-on science and engineering activities to support kids’ exploration in formal and informal education settings. Our goal in creating the resources were: For youth: (1) Provide opportunities to use science, technology, engineering, and math to solve challenges related to exploring our solar system, (2) Build and hone critical thinking, problem-solving, and design process skills, (3)
Rockman et al (REA), a San Francisco-based research and evaluation firm, conducted the external evaluation for Youth Radio's DO IT! program, which was funded by the National Science Foundation. Building upon Youth Radio's previous Science and Technology Program, the DO IT! initiative consisted of three primary components that promoted STEM (science, technology, engineering, and mathematics) learning by training underserved youth in cutting-edge digital technologies: (1) Brains and Beakers: Young people hosted a line-up of investigators and inventors for demo-dialogues at Youth Radio's studios
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Rockman et al | Youth RadioKristin BassJulia Hazer
The University of Massachusetts Lowell and Machine Science Inc. propose to develop and to design an on-line learning system that enables schools and community centers to support IT-intensive engineering design programs for students in grades 7 to 12. The Internet Community of Design Engineers (iCODE) incorporates step-by-step design plans for IT-intensive, computer-controlled projects, on-line tools for programming microcontrollers, resources to facilitate on-line mentoring by university students and IT professionals, forums for sharing project ideas and engaging in collaborative troubleshooting, and tools for creating web-based project portfolios. The iCODE system will serve more than 175 students from Boston and Lowell over a three-year period. Each participating student attends 25 weekly after-school sessions, two career events, two design exhibitions/competitions, and a week-long summer camp on a University of Massachusetts campus in Boston or Lowell. Throughout the year, students have opportunities to engage in IT-intensive, hands-on activities, using microcontroller kits that have been developed and classroom-tested by University of Massachusetts-Lowell and Machine Science, Inc. About one-third of the participants stay involved for two years, with a small group returning for all three years. One main component for this project is the Handy Cricket which is a microcontroller kit that can be used for sensing, control, data collection, and automation. Programmed in Logo, the Handy Cricket provides an introduction to microcontroller-based projects, suitable for students in grades 7 to 9. Machine Science offers more advanced kits, where students build electronic circuits from their basic components and then write microcontroller code in the C programming language. Machine Science offers more advanced kits, which challenge students to build electronic circuits from their basic components and then write microcontroller code in the C programming language. Machine Science's kits are intended for students in grades 9 to 12. Microcontroller technology is an unseen but pervasive part of everyday life, integrated into virtually all automobiles, home appliances, and electronic devices. Since microcontroller projects result in physical creations, they provide an engaging context for students to develop design and programming skills. Moreover, these projects foster abilities that are critical for success in IT careers, requiring creativity, analytical thinking, and teamwork-not just basic IT skills.
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TEAM MEMBERS:
Fred MartinDouglas PrimeMichelle Scribner-MacLeanSamuel Christy
Internet Community of Design Engineers (iCODE) program, which took an innovative approach to structuring self-directed learning – using a collaborative on-line environment to facilitate hands-on activities, was a three year program led by the University of Massachusetts Lowell and Machine Science Inc., Cambridge. The overall objective of this program, which involved after-school and summer sessions and was funded by NSF’s Innovative Technology Experiences for Students and Teachers (ITEST) Program, was to increase the likelihood that participating middle school and high school students will
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Rucha LondheColleen ManningRachel SchechterLaura HousemanIrene Goodman
This Science Learning+ project will develop a Youth Access & Equity Research & Practice Agenda, focusing on addressing equity issues for youth, ages 11-14, primarily from non-dominant backgrounds. The project will involve researchers and practitioners from three ISL settings/contexts, (1) Designed spaces, e.g., museums; (2) Community-based, e.g., afterschool clubs; and (3) Everyday science, e.g., science media. The goal of the agenda will be to advance scholarly understanding of equity issues in relation to these three contexts. Taking an ecological view of STEM learning as a sociocultural process of participation and transformation, the project will employ a Complex Adaptive System lens to document multiple pathways youth take (or not) within/across ISL settings over time, the impact these pathways have on learning and development, and their influence on ISL organizations themselves. These lenses will help us identify aspects of learning environments which shape youth access and development, and the value and impact of the equity ideas, tools and practices.
The purposes of the STUDIO 3D evaluation were to collect information about the impact upon student learning as a result of participating in the STUDIO 3D Project, as well as to elicit information for program improvement. Areas of inquiry include recruiting and retention, impact on project participants, tracking student impacts, and the project as a whole.
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative resources for use in a variety of settings. The project will further develop, roll out, and conduct research on a set of materials that will introduce middle school age youth to innovative and engaging engineering challenges in the Boys and Girls Club (B&GCs) context. Building on substantial prior work and evaluation-based learning, WISE Guys and Gals - Boys & Girls as WISEngineering STEM Learners (WGG) will: (1) combine engineering design activities with the (open source, online) WISEngineering infrastructure; (2) scale-up the infrastructure; (3) engage youth in informal afterschool experiences; and (4) collect a wealth of rich data to further our understanding of how youth learn through these experiences. This work will be conducted by Hofstra University's Center for STEM Research in conjunction with Brookhaven National Laboratory (BNL), The CUNY Graduate Center's Center for Advanced Study in Education (CASE), the Boys & Girls Club of America, and 25 B&GCs in New York and New Jersey. The underlying theoretical framework builds on proof-of-concept work supported by NSF and the Bill and Melinda Gates Foundation. An open source, on-line interface (WISEngineering) provides numerous virtual tools (e.g., social networking, Design Journal, embedded assessments) that promote learning and collaboration through challenging, thoughtful, and creative work. WGG will explore how to incorporate creativity, social networking, connections to real-world STEM needs/careers, and teamwork into challenges that can be completed in a one-hour period, an activity time constraint in many B&GC settings. Staff from the clubs will participate in face-to-face and virtual professional development in an effort to build their capacity as facilitators of STEM learning. Research will focus on: (1) how activities developed for 60-minute implementation and guided by informed engineering design and interconnected learning frameworks support youth learning and engagement; and (2) characteristics of the professional development approach that support B&GC facilitators' capacity development. By the end of the project, over 6,000 middle school aged youth, the majority from groups underrepresented in STEM areas, will gain experience with engineering design as they develop engineering thinking, new STEM competencies, STEM career awareness, and an appreciation for the civic value of STEM knowledge.
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TEAM MEMBERS:
David BurghardtXiang FuKenneth WhiteMelissa Rhodes
This Advancing Informal Science Learning Pathways project, Using Technology to Research After Class (UTRAC), explores whether a combination of technology (e.g., iPad-enabled sensors, web-based inquiry-focused portal) and facilitated visits improves learning outcomes for rural and Native American elementary-age youth in after school programs. Expected outcomes include improved engagement, knowledge, skills, and attitudes toward science, technology, engineering, and math (STEM). Project goals include promoting STEM learning through science inquiry activities keyed to specific Next Generation Science Standards as well as improving how technology can be used to enhance learning outcomes in afterschool programs. The experimental design of this project - testing the effects of physical or virtual facilitation visits on learning outcomes - will lead to improvements in STEM learning outcomes among rural and underrepresented students. This project will employ several innovations in utilizing technology to teach STEM topics including: (i) hands-on, real-time, crowd sourced data collected by participants in their schoolyards; (ii) a pedagogic emphasis on communication of schoolyard data among and between participants; (iii) testing of motivational incentives; and (iv) partnerships between after school providers, preservice teachers, and university researchers as facilitators. The entire process will be modularized so that it can be modified in terms of place, STEM topic or student cohort. The topic focus of the project -- Life Under Snow -- is relevant to participating students, as Montana school playgrounds lie blanketed under snow for the majority of the school year; it includes elements of snow science, carbon cycle science, and a combination at the intersection of three recent literacy initiatives (e.g., Earth Science, Climate, or Energy). UTRAC will pilot and evaluate facilitated snow science/carbon cycle science activities that couple real-time schoolyard data with tools patterned after those available through WISE (Web-based Inquiry Science Environment; wise.berkeley.edu). Participants will collect and compare data with other youth participants, and researchers will use formative assessments to define interventions with potential to maximize student engagement and learning improvements among underserved youth. The project will advance understanding of informal education's potential to improve STEM engagement, knowledge, skills and attitudes by quantifying how - and to what extent - youth engage with emerging technologies iPad-enabled sensors, and crowdsourcing and visualization tools. The deliverables include a quantifying metric for learning outcomes, a training model for the iPad sensors and web application, an orientation kit, a social media portal, and database for the measurements.
This project will help address the urgent need for a new engineering workforce. Middle school students will be entering a workforce that is increasingly global. They will need not only technical skills but also global competencies including: the ability to investigate the world, recognize perspectives, communicate ideas, and take action. This model integrates engineering with global competencies and will provide new knowledge about how this type of learning experience impacts students and educators. This project builds on the success of the previous Design Squad project funded by NSF and developed by WGBH, which has implemented a national model for engineering education for middle school youth. This project expands the model internationally, connecting U.S. based youth with those in Southern Africa (including South Africa, Botswana, and Swaziland). The project partners are FHI 360, a non-profit organization in 60 countries around the world that helps build capacity for improving lives. They will facilitate the implementation of the afterschool programs in Southern Africa . The US dissemination partners include Promise Neighborhoods Institute, Middle Start, Every Hour Counts, and the National Girls Collaborative Project. Project deliverables include a global engineering curriculum; a web platform with videos, games, activities; an afterschool Club Guide; and a Community of Practice for informal engineering educators. A knowledge building component will provide new evidence on how high quality accessible resources and strategies can impact students' development of global competencies and engineering skills to solve real world problems. An iterative approach will be used to develop the resources including the global engineering afterschool curriculum, Club guide, and other components. The methodology uses a continuous cycle of improvement including: assess/design, test/ implement, synthesize/reflect, and utilize/disseminate. The Summative Evaluation will generate evidence about whether and how this kind of collaborative work builds children's understanding of engineering, motivation to participate, and confidence in taking informed action on behalf of pressing global problems. This will contribute to a larger body of work about whether and how engaging with global, collaborative engineering problems leads to greater self-efficacy for children with very different backgrounds, experiences, and opportunities. This project will add new knowledge about how the well-honed Design Squad model in the U.S. can be expanded with a global context and global partners. This proposal was co-funded by EHR/DRL, Engineering/EEC, and International Science and Engineering. During the project period approximately 125,000 children in the US and 5000 children in southern Africa will be reached. In the long term, with the continued global access to the resources, the reach will potentially be in the millions.
This poster was presented at the 2014 AISL PI Meeting held in Washington, DC. It discusses the second season of SciGirls, a multimedia project designed to encourage and empower more girls to pursue careers in STEM.
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Twin Cities Public TelevisionRita Karl