In 2006, the Institute for Advanced Learning and Research (IALR) received a three-year grant from the National Science Foundation's Information/Innovative Technology Experiences for Students and Teachers (ITEST) division to create the Dan River Information Technology Academy (DRITA) for under-served high school students in rural Virginia. The only program of its kind in Southern Virginia, the program was designed to provide participating students with competencies in information technology (IT) and workforce skills. In addition, the program seeks to encourage students to graduate from high
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TEAM MEMBERS:
Irene GoodmanLorraine DeanMiriam KochmanHelena PylvainenColleen ManningKaren PetermanInstitute of Advanced Learning and Research
resourceprojectProfessional Development, Conferences, and Networks
Rhode Island Information Technology Experiences for Students and Teachers (RI-ITEST) is a comprehensive ITEST project for high school students and teachers. The goal of RI-ITEST is to prepare students from diverse backgrounds for careers in information technologies by engaging them in exciting, inquiry-based learning activities that use sophisticated computational models in support of a revolutionary science curriculum. It advances science education by enhancing the Physics First initiative in Rhode Island through the use of NSF funded student materials based on molecular modeling and promotes IT education by teaching modeling skills and providing students with career and vocational information on the use of computational models. The project provides over 120 hours of credit-bearing activities for 100 teachers and full support for classroom implementation. RI-ITEST is developing an optimal placement of the interactive materials from CC's Science of Atoms and Molecules project in the Physics First courses in Rhode Island; developing IT materials that are coordinated with the student materials that emphasize modeling skills and the career and vocational dimensions of computational modeling; preparing100 diverse Rhode Island science teachers in two cohorts to offer a course in the Physics-Chemistry-Biology sequence; developing materials and supports for using molecular dynamics and related IT materials for teachers in Rhode Island and elsewhere who are not ITEST participants; generating evidence for the effectiveness of the IT-enhanced project materials for increasing student learning and changing student attitudes about science, mathematics, and technology careers; reaching parents, guidance counselors, school administrators, and business partners with information about the project, student productions, and evidence for effectiveness; disseminating materials and findings to other teachers, programs, and districts nationwide.
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TEAM MEMBERS:
Daniel DamelinGerald KowaiczykJames Magyar
Maine is a rural state with unequal access to computers and information technology. To remedy this, the Maine laptop program supplies iBooks to every seventh and eighth grade student in the state. The goal of EcoScienceWorks is to build on this program and develop, test and disseminate a middle school curriculum featuring computer modeling, simple programming and analysis of GIS data coupled with hands-on field experiences in ecology. The project will develop software, EcoBeaker: Maine Explorer, to stimulate student exploration of information technology by introducing teachers and students to simple computer modeling, applications of simulations in teaching and in science, and GIS data manipulation. This is a three-year, comprehensive project for 25 seventh and eighth grade teachers and their students. Teachers will receive 120 contact hours per year through workshops, summer sessions and classroom visits from environmental scientists. The teachers' classes will field test the EcoScienceWorks curriculum each year. The field tested project will be distributed throughout the Maine laptop program impacting 150 science teachers and 17,000 middle school students. EcoScienceWorks will provide middle school students with an understanding of how IT skills and tools can be used to identify, investigate and model possible solutions to scientific problems. EcoScienceWorks aligns with state and national science learning standards and integrates into the existing middle school ecology curriculum. An outcome of this project will be the spread of a field tested IT curriculum and EcoBeaker: Maine Explorer throughout Maine, with adapted curriculum and software available nationally.
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TEAM MEMBERS:
Walter AllanEric KlopferEleanor Steinberg
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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TEAM MEMBERS:
Janet BeissingerSusan GoldmanDaria TsoupikovaBonnine Saunders
The Addressing Gender Barriers in STEM through Theatre of Social Engagement project responds to the need to educate the public about the careers in computer and information science and engineering (CISE) fields by educating high school students, parents, teachers and counselors about the barriers to participation that confront women and other underrepresented groups. In this Communicating Research to Public Audiences (CRPA) project, a dramatic play is used to communicate the findings from the PI's work which resulted in a theory about gender and IT to explain and predict gender (under)representation in IT fields. The play dramatizes constructs of the theory, particularly the ways in which gender, ethnicity, and class affect identity and career and life decisions. Drawing from life history interviews conducted as a part of the research, the storyline of the dramatic play centers on three young women who are graduating from high school and making decisions about their futures and possible careers in IT. Situated squarely in the realm and literature of "theatre of social engagement," this play, and its staged readings and ancillary website, extend access beyond the scientific community to new scientific research on gender barriers in CISE. Learning goals for the project include: 1. Awareness and knowledge about possible computer and information science and engineering careers; barriers and stereotypes that affect CISE career choice among women; and "significant others" such as partners, family members, mentors and teachers who can make a difference at key inflection points in career decision making. 2. Attitude change about the CISE fields being open to everyone regardless of gender, ethnicity, race or class; how one's individual characteristics can be used to resist barriers to inclusion in CISE careers. 3. Intended behavior about learning more about CISE careers and educational opportunities; and responding to negative stereotypes related to CISE. Evaluation of the proposed project will include observations, talk-back sessions (focus groups) after readings of the play, pre-post surveys administered at the showings, and a second post-performance survey to be administered a certain amount of time after the showing. Dissemination will be through readings of the play for audiences in New Jersey and Pennsylvania, with partnering informal learning venues, and through an associated website which will allow visitors to download and stage the play themselves. Advertisement for the play and the website will take place through websites such as Facebook, Twitter, and websites that promote diversity in computing. In addition, the PI intends to contribute to the scholarly literature on theatre as an informal learning approach and on the findings of how audiences respond to the play itself.
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).
This project will examine the implications of the intersection of art, science, and technology as revealed by the events occurring around the celebration of the fiftieth anniversary of the first general electronic computer, ENIAC-50. The finished product will be radio programming and audio material that presents the coming together of scientists, artists, and other participants in Philadelphia. It will build on the previous research and explorations in both of these fields toward finding commonalties and ways in which each has influenced the other. The finished product will be broadcast for the general public and also can be made available to scientists and educators in the field as resource material for courses, seminars, and lectures as they explore the intersections of science and art and implications this has for research and education.
The New York Hall of Science will develop "Connections," a 3,500-sq. ft. interactive exhibition and related learning resources that will introduce visitors to the fundamental technology of networks. "Connections" will offer diverse audiences opportunities to explore networks, both natural and human-designed. The exhibition will highlight the fundamental characteristics of networks such as their structure, function and adaptability. The project will also produce supporting educational resources for families, after-school programs, community groups, students and teachers. Audio-tours will be produced for general visitors and for visitors with visual impairments. The Connections Discovery Lab, a 750-sq. ft. enclosed space adjacent to the exhibition, will offer scheduled workshops and drop-in programs.
The Tech Museum of Innovation is producing a 3,000 square-foot permanent exhibition, complementary online acitivities, and a Design Challenge curriculum to engage visitors in the exploration of Internet techologies. The goals of the project are to enhance the technological literacy of middle school students, provide the general public with tools, experience, and confidence to participate in shaping the future of the internet, and advance the informal science education community through applied research in networked exhibit technology. Two distinct features of the exhibit are: 1) The Smart Museum, a computer network linking gallery and online expereinces, and 2) "dynamic content," a set of strategies for rapid exhibit updates that will mirror the changing Internet for the life of the exhibition. The Design Challenge curriculum will be used at the museum, in outreach to classrooms and community centers, and in training sessions for science educators. The summative research will be shared with the science education community via The Tech's web site as well as professional seminars, publications and conferences.
The Oregon Museum of Science and Industry (OMSI) will design, develop, evaluate and install "Technoquest," a permanent 6,000 square foot interactive technology exhibition for families, underrepresented groups, school groups and OMSI's general audience. "Technoquest" will fill OMSI's Technology Hall with a suite of highly interactive, exciting and engaging hands-on educational exhibits, computer simulations, audio and video components, text, graphics and artifacts. The exhibition hall will be divided into five thematic areas: industrial technology (robotics), medical technology, transportation technology, computer technology and communications technology. Other experiences will include a quick-change area for rapidly exhibiting emerging technologies and a Technology Lab where activities conveying a deeper understanding of the general principles of technology will be presented. Ancillary educational materials will be disseminated to the general public and to educators via print, the exhibition website, teacher workshops and professional development workshops for informal science educators. Content of the exhibition and ancillary materials will focus on general educational principles established by the International Technology Education Association (ITEA) that emphasize the processes common to all forms of technology and that align with state and national science standards. Principal concepts include The Nature of Technology, Technology and Society, Design, Abilities in a Technological World, and The Designed World. These principles will be reinforced throughout the exhibition. Each thematic area will highlight all five key principles of technology as defined by the ITEA.
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TEAM MEMBERS:
Raymond VandiverJan DabrowskiBenjamin Fleskes
This project develops an 8-week middle-school mathematics module that introduces cryptography, the science of sending secret messages, while teaching and reinforcing the learning of related mathematical concepts. The topics range from the classical encryption systems and the historic context in which they were used through powerful modern encryption systems that provide secrecy in electronic messages today. The module also covers passwords and codes that correct errors in the transmission of information. Public awareness of the importance of cryptography is growing, as is the need to understand the issues involved. The study of cryptography provides an interesting context for students to apply traditional mathematical skills and concepts. Mathematical topics covered include percents, probability, functions, prime numbers, decimals, inverses and modular arithmetic. The main product is a middle-school student book, with accompanying teacher materials. A web site is being developed that supports the activities in this book. Abbreviated modules for Grades 3, 4 and 5 are also being developed, as well as an instructor's guide for adapting the materials for use in informal educational settings such as museums and after-school programs. The development of the module involves piloting and field-testing by experienced classroom teachers from diverse school communities and instructors of informal educational programs. Evaluation includes review by mathematicians and educators, as well as an investigation into the level of students' understanding of the topics studied.
The goal of the project is to produce a one hour television documentary and a series of video teaching modules which explore a wide range of scientific disciplines in an exciting manner by presenting the story of how these disciplines are used in the preparation and racing of an Indianapolis race car. This program will be distributed to a wide audience through its broadcast by PBS and cable sports networks; through dissemination to classrooms and museums nationwide; and through distribution via agencies that focus on bringing educational programs to youth and minorities across the country. We expect to attract a new audience to science, the millions of Americans who are infatuated by automobiles. This is an audience that cuts across age, ethnic and racial distinctions in America today. This exciting story of applied science should also appeal to American youth in a way that more traditional science stories do not. The major scientific disciplines involved in the project are: basic engineering, mathematics and physics, aerodynamics, materials science, mechanics, telemetry and computer aided design. This project is submitted to the Informal Science Education Program. The specific content of this project will be aimed at an audience with little background in science. High-school students and adults should be able to understand all the principles presented. Younger audiences will gain insight into how a knowledge of science is fundamental to a sport that many of them find fascinating.