This proposal calls for development, over five years, of a national, interactive, telecommunications-supported Network of 85 or more affiliated neighborhood technology learning centers in inner cities and other impoverished areas, for the purpose of attracting, and then nurturing underserved peoples' active involvement with math, science, and technology. Network affiliates will provide informal opportunities for disadvantaged minority young people and their families and friends to get access to, and learn to use, the most powerful tool for personal empowerment yet known, to engage in explorations designed to increase awareness of their ability to do math and science and of the potential for careers in these areas, and, through telecommunications, to involve themselves with distant peer groups in collaborative investigations. Such opportunities present attractive and cost-effective alternatives to the dead ends that street life, drugs, incarceration, and/or welfare offer. Success in achieving these goals depends, however, on the availability of continuing programmatic and staff development assistance, and on the ability of Network members to engage, not as disparate entities, but as a mutually supportive community, in this momentous task. Proposed Network services include (in addition to telecommunications linkages) the identification, development, and dissemination of technology-mediated math and science activities appropriate to community education, consultative planning and technical assistance, staff development workshops, the development of a resource database, and an annual all-affiliates meeting -- all these to be accompanied by systematized self-assessment procedures. Also included is the development of a Network infrastructure to support continued existence of the Network beyond the grant period.
This research project is a follow-up to previous research on the persistence of high ability minority youth in college programs for mathematics, science, engineering, premedicine and predentistry. The earlier research used data retrieved from the 1985 College Board files for 5,602 students with SAT mathematical scores of 550 or above. All were minority students except for a comparison sample of 404 White students. In 1987, a first follow-up was conducted. 61 percent of the non-Asian American minority students had enrolled in college and were majoring in MSE fields in comparison with 55 percent of the White students and 70 percent for the Asian American students. In the current phase of this research, the original sample will be resurveyed, five years after high school graduation. A subsample will be interviewed in-depth. The major goal of this phase will be to answer three critical questions: which sample members are still studying or employed in MSE fields, what are their unique characteristics, and what are the theoretical and national policy implications of the results. This project is jointly supported by the Studies and Analysis and the Research in Teaching and Learning Programs.
NACME proposes to develop a 20 minute videotape, with a teacher's guide and student brochure, that will use career opportunities in engineering as a vehicle to encourage math and science course-taking among minority high school students. By introducing engineering careers as dynamic, exciting professions that offer excellent prospects for minority graduates, NACME hopes to motivate students to take academic track science and math courses beginning at the 8th/9th grade crossroads and continuing through high school graduation. The video, geared specifically to a primary audience of 11 to 14 year-old minority students (5th through 8th graders) and a secondary audience of non-minority students, parents, teachers and guidance counselors, will focus on the lives of successful young engineers, male and female, from diverse ethnic backgrounds.
Children's Discovery Museum of San Jose seeks National Science Foundation grant support in the amount of $381,000 (55% of a total project cost of $693,188) to develop over a 24-month period a series of interactive exhibits exploring the subject of rhythm, including both obvious and lesser known manifestations within the natural and physical worlds. Drawing upon the scientific disciplines of mathematics, biology, physics and psychology, RHYTHM takes as its construct the idea of time, the articulation of which means for apprehending and understanding rhythm. Working with outside advisors in science education and specific content areas, Co-PI Michael Oppenheimer will develop and build 20 exhibits, which will be semi- permanently installed at Children's Discovery Museum and accessible to our annual visitor population of 350,000; exhibits will also be profiled on "Kids" Clubhouse," a television program developed jointly by the Museum and our local PBS affiliate, KTEH/54, viewed by 55,000 weekly. Matching funds are also being requested to support curricular materials and a traveling version of RHYTHM. Over a 2-year, 8-site tour the Association of Science and Technology Centers projects that the series will reach a national audience of more than 1,000,000 children and adults. As a comprehensive project, RHYTHM provides a compelling model for addressing imperatives articulated in Science for All Americans, the landmark report issued by Project 2061 of the American Association for the Advancement of Science. Located in San Jose, California, the Museum serves an expanding urban area characterized by extraordinary ethnic diversity: Santa Clara County's 1.5 million residents are 42% non-Anglo, while San Jose is 50.8% Hispanic, Asian and Black.
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TEAM MEMBERS:
Sally OsbergKoen LiemTom NielsenMichael Oppenheimer
Through the proposed project, approximately 555,000 youth and adults will improve their knowledge of the basic sciences and mathematics, and learn to integrate and apply these disciplines, by analyzing local environmental problems using remote sensing imagery and maps. Faculty from the Cornell laboratory for Environmental Applications of Remote Sensing (CLEARS) and Cornell Department of Natural Resources will train county teams of teachers, museum and nature center educators, community leaders, and Cooperative Extension agents from throughout New York State to conduct educational programs with youth and adults in their communities. Previously developed CLEARS educator enrichment workshops and training materials will be enhanced and revised based on the interactions among Cornell Faculty, informal and formal science educators, and students during this program. A facultative evaluation focusing on the workshops, training materials, and educator teaching skills, and a summative evaluation focusing on student learning and attitudes, program delivery in the various community education settings, and the effectiveness of the county educator teams will be conducted. The results of the evaluation will be incorporated into a program handbook and used in nationwide dissemination of the program.
Girls Inc. will develop a national model summer program for girls aged 12 to 16 to encourage their interest in science, their enrollment in science courses in high school, and their interest in science careers. The recruitment of girls from low-income and minority families as participants will be a high priority. The program will represent a synthesis of Operation Smart, an afterschool science and mathematics program, and Eureka Teen Achievement Program, which introduces science and mathematics in summer programs through sports. The program will be developed and field- tested in five diverse Girls inc. sites around the country and to other interested groups. Substantial formative and impact evaluation is planned.
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TEAM MEMBERS:
Libby PalmerHeather Johnston Nicholsonellen wahl
Founded in 1979, the Science Skills Center (SSC) is a non-profit community based program which encourages young minority and female students to pursue careers in science, mathematics, and technology. At its current two sites, located in Brooklyn, New York, approximately 400 students, ages six to eighteen, are enrolled in programs where they take accelerated courses in biology, chemistry, physical science, rocketry, oceanography, botany, and advanced mathematics. Classes, which are presented within the cultural and linguistic understanding of minority children, provide students with an opportunity to recognize the relationship of science, mathematics, and technology to their everyday lives. The SSC proposes to replicate its present programs, establishing three additional sites in the New York City area in three years. The SSC also proposes to establish a systematic replication program which would assist other communities, both regional and national, to establish their own SSCs. This project would require a resource person to guide communities in all aspects of program development. To assist in that effort, SSC proposes development of comprehensive educational and administrative manuals as well as the preparation of accompanying training and profile videos. Finally, the SSC proposes to develop a research module in software and manual form which would assess and track student learning, school performance, performance on standardized exams, career aspiration and selection, and student attitudes in a community based science program targeting minority students.
This one-hour documentary film profile of world famous mathematician Paul Erdos is being made for eventual broadcast on the NOVA series. At age 76, the world's most prolific mathematician (1,100 papers and over 200 co-authors) still spends all of his time moving from country to country, meeting with other mathematicians to work on problems. The film will show how a prodigious mathematician, with a career of over 50 years, lives and works, how he interacts with his colleagues, and how the international community of mathematicians functions. It aims to explore the human side of a discipline in which God, Beauty and Numbers are the subjects of daily speculation. But what do mathematicians actually do? Because of his peripatetic nature and eternal curiosity, Erdos provides an ideal window on a field that has often been perceived by the public as remote and intimidating. The film will show Erdos and his colleagues at work and play. Interviews and archival materials will establish his contributions in combinatorics and in Number theory. Some more accessible problems will be illustrated with animation and computer graphics. The interplay of a warm human story with intriguing philosophical speculations and mathematical problems will show important results are arrived at in mathematics. This is expected to stimulate interest in mathematics among television viewers and students. The film is in production and only partial funding is being requested from NSF.
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.
The critically acclaimed film "STAND AND DELIVER" accomplished the formidable task of focusing national attention on the achievements of minority students in higher mathematics. As a motivational tool for educators, the film's value can hardly be overstated. "STAND AND DELIVER" will now have a second life as a play for the stage. The intimate human drama of the story of Jaime Escalante and his inner city A.P. calculus class will be re- written and confined to one set - a classroom - making it a natural for the theatre. Best of all, junior and senior high schools already have the resources to stage a first-rate production. Since almost all the roles depict students and teachers, "STAND AND DELIVER" should be a natural choice for school drama clubs across the country. The transformation of the movie into a play will take place in three stages: First, the screenplay is adapted into a stage play. Second, the initial stage production is mounted. Third, the play is published and made available to schools and theatre companies for local performances.
Talcott Mountain Science Center, in cooperation with the Urban Schools Learning Network (encompassing a variety of state, regional and national partners), seeks $698,141 in National Science Foundation funds under the Informal Science Education Program for a three year national model for increased minority interest and participation in Informal Science Education Program for a three year national model for increased minority interest and participation in informal science education. The title of this partnership is Project PROMMISE )Promoting Role Model Minorities in Science Education). Over the next three years, Project PROMMISE will produce and broadcast at least 30 distance learning programs for thousands of secondary level students in urban and disadvantaged communities throughout the U.S. These Project PROMMISE broadcasts will bring distinguished minority and women scientists, explorers, astronauts and other figures in touch with urban young people through interactive video programming. Broadcasts will be preceded and followed by hands- on informal science education activities. The project also will broadcast national career exposure, exploration, and mentoring programs to better inform urban minority students of academic and career enrollment in secondary and post-secondary math, science and technology studies and cultural isolation by urban students, teachers and urban informal science education institutions. Major national partners for reform and pre- college minority enrichment are participating in the project, including the Edna McConnell Clark Middle School Change Network, the Museum Satellite Network, PIMMS at Wesleyan, the CT Pre- Engineering Program (CPEP). Private sector support has been gained from United Technologies, CIGNA and Union Carbide.
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TEAM MEMBERS:
Donald LaSalleGlenn CassisDaniel Barstow
Digital image processing offers several possible new approaches to the teaching of a variety of mathematical concepts at the middle-school and high-school levels. There is reason to believe that this approach will be successful in reaching some "at-risk" students that other approaches miss. Since digital images can be made to reflect almost any aspect of the real world, some students may have an easier time taking an interest in them than they might with artificial figures or images resulting from other graphics- oriented approaches. Using computer-based tools such as image processing operators, curve-fitting operators, shape analysis operators, and graphical synthesis, students may explore a world of mathematical concepts starting from the psychologically "safe" territory of their own physical and cultural environments. There is reason to hope that this approach will be particularly successful with students from diverse backgrounds, girls and members of minority groups, because the imagery used in experiments can easily be tailored to individual tastes. The work of the project consists of creating detailed designs of the learning modules, implementing them on microcomputers, and evaluating their effectiveness in a variety of ways, using trials with students at Rainier Beach High School, which is an urban public high school having an ethnically diverse student body and a Macintosh computer laboratory.
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TEAM MEMBERS:
Steven TanimotoMichele LeBrasseurJames King