The lion's share of my current research program is devoted to the study of learning in the blooming, buzzing confusion of inner-city classrooms. My high-level goal is to transform grade-school classrooms from work sites where students perform assigned tasks under the management of teachers into communities of learning ( Bereiter & Scardamalia, 1989; Brown & Campione, 1990) and interpretation ( Fish, 1980), where students are given significant opportunity to take charge of their own learning. In my current work, I conduct what Collins (in press) refers to as design experiments, modeled on the
This article discusses a 1988-1990 study that analyzed the effectiveness of a collaborative effort between a museum and a school system to build an integrated curriculum package. The partners included the York County School System (VA) and the Yorktown Victory Center (operated by the Jamestown-Yorktown Foundation). The theme of the curriculum was 18th Century Medicine and the unit was designed to enhance the science, math, and social studies instruction of fourth graders.
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TEAM MEMBERS:
Ronald GieseJudy Davis-DorseyJoseph Gutierrez
resourceprojectProfessional Development, Conferences, and Networks
The Buffalo Society of Natural Sciences plans to conduct a 5 year project to train 150 mentor teachers (30 teachers/year) and their principals, who will then train the remaining 1100 elementary teachers in the Buffalo Public School System. The training would include two 5-week summer sessions (in a Magnet school that is physically incorporated into the Buffalo Museum of Science) and 4 in-service workshops during the academic years following each of the summer workshops. This innovative leadership project is a collaborative effort between the Buffalo Society of Natural Sciences (including both education and curatorial/science staff persons) the Buffalo Public Schools, and individuals from local colleges and universities. The setting of the project is enhanced by a Science and Math Magnet School which is housed within the museum, and by the school/museum's location in a largely inner city environment with easy accessibility to minority persons. The project is designed to provide mentor teachers with a strong science background in pedagogy and content over a two-year period of summer and academic-year workshops, and to prepare and support these mentors as they inservice their colleagues. Project staff from the museum, public schools, and the academic community will provide strong support through academic-year workshops, site visits and telecommunications networking. Principals will be appropriately involved, and will work with mentors to develop a science inservice program tailored to meet the needs of their individual schools; as a consequence, virtually all of the 1100 K-6 classroom teachers of science in the Buffalo Public Schools will have been prepared to teach investigative, hands-on science to their students. Non-NSF cost sharing is approximately 27.9% of the amount requested from NSF.
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TEAM MEMBERS:
Peter Dow
resourceprojectProfessional Development, Conferences, and Networks
This project is aimed at perfecting and testing a new instructional method to improve the effectiveness of introductory physics teaching. the methods has two chief characteristics: 1) a systematic challenge to common sense misconceptions about the physical world, and 2) an emphasis on models and modeling as basic to physical understanding. Two versions of the method will be tested. The first version is designed especially for high school physics. It emphasizes student development of explicit models to interpret laboratory activities. After an initial test, this version will be taught to high school physics teachers in a summer Teacher Enhancement Workshop, and its effect on their subsequent teaching will be evaluated. Teachers with weak as well as strong backgrounds will be included. A special effort will be made to include females and minorities. The second version will be tested in a special college physics course designed to prepare students with weak backgrounds for a standard calculus based physics course. It emphasizes modeling techniques in problem solving. This project is jointly supported by the Division of Materials development, Research and Informal Science Education and the Division of Teacher Preparation and Enhancement.
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TEAM MEMBERS:
David HestenesMalcolm Wells
resourceprojectProfessional Development, Conferences, and Networks
Scientists and engineers are an underutilized resource in motivating students and assisting classroom teachers in teaching science. Pilot programs have demonstrated the value of preparing scientists for what to expect when they enter the classroom, how to incorporate the school curriculum into their program, and how best to reach the goal of making their visits a "never to be forgotten" life changing experience for students. The concept of a Survival Kit is an outgrowth of a Scientist-in-Residence program at the North Carolina Museum of Life and Science which has successfully matched scientists and public school classrooms locally since 1982. The North Carolina Museum of Life and Science proposes to conduct meetings for staff and outside educational specialists to identify the materials and strategies needed to prepare scientists to enter school classrooms. The final report of these meetings will include mechanicals of a Scientist Survival Kit, which can be disseminated across the country, and an evaluation report of how the kits can be and are used. Dr. Mark St. John, Inverness Associates, a professional evaluator noted for his work with nationally significant science education projects, will provide local and national evaluation through surveys and meetings to give a picture of the issues involved in establishing and maintaining programs of scientists in the schools and the role played by the Scientist's Survival Kit in furthering this aim.
Project Enhanced Science Learning (PESL) offers learning partners opportunities to engage in authentic scientific inquiry through apprenticeship. Such inquiry is often enabled by dynamic interactions among learning partners in physical proximity. Yet scientific and business practice using Internet and broadband services recognizes that not all partners necessary to an interaction can be co-located. Our vision uses new technologies to extend the collaborative "reach" of PESL to include diverse expertise among remote learners, teachers, and scientists. This work, in atmospheric sciences, extends collaborative media beyond asynchronous text-only email to shared workspaces and two-way audio/video connections that allow for collaborative visualization of science phenomena, data, models - What You See Is What I See (WYSIWIS). Tools for local- and wide-area networked learning environments will enable highly interactive, media-rich communications among learning partners. Research on these learning architectures will provide pedagogy and social protocols for authenticating the science learning experience in classrooms and other spaces. Greater motivation to learn and enhanced science learning in terms of more valid, performance assessments should result from students' participations. The next decade brings widespread, networked multi-media interpersonal computing. This project will provide a blueprint to inform the effective use of interpersonal collaborative media for science education.
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