This project uses sea urchin embryos to provide a curriculum module for inquiry-based biology. The curriculum is provided via a new open access website. It addresses several of the National Science Content Standards and provides a range of activities suitable for all levels of high school biology. It will provide instructional support materials such as video demonstrations, animations, time lapse videos and image galleries relevant to each exercise, as well as professional development materials.
Through integration of research and education, this project is providing high resolution data on the spatial distribution of the thermal state of permafrost in Alaska, improving the general knowledge of Earth's climatic patterns, bringing science to remote Alaskan villages, and providing an opportunity for younger generations to take part in understanding Earth's climatic and hydrologic systems.
This project is designed to assist K-3 teachers in teaching life and physical science for conceptual understanding. It integrates videos, stills and voice-over into one multimedia web-based tool. The program provides teachers with experiences in understanding details related to the \"how\" of high quality science teaching. The professional development activities illuminate what happens in planning and in arranging science classrooms to promote student learning.
This project is creating five video-case modules for use in professional development of middle school mathematics teachers. The materials are designed to develop teachers' understanding of mathematics knowledge for teaching similarity. In total, 18-24 video cases will be produced, which, taken together, form the curriculum of a 45- to 60-hour professional development course.
This project is demonstrating the use of cyber-enabled technologies to build and share adaptable interventions for pre- and in-service teacher growth that effectively make use of major video collections and have high promise of success at multiple sites. The cyber infrastructure being significantly extended through this project is supporting development and documentation of additional interventions for teacher professional development using this video collection, as well as other videos that might be added in the future.
The Video Mosaic Collaborative features videos of student mathematics reasoning, tools and services to encourage learning, research and practices fostering the development of student reasoning. The VMC is a collection and service portal intended to support three primary audiences—teacher educators and their pre-service and in-service students, practicing teachers, and researchers. The Video Mosaic Collaborative features a 22-year longitudinal study of students’ mathematical reasoning skills as they are developed from elementary through high school grades. The VMC has been carefully designed to leverage the insights and strategies that can be mined in this extensive and unique video collection featuring observations, interventions and interviews with students solving mathematics problems in the classroom and in informal learning settings. A careful metadata strategy was designed by the library and education research partners in collaboration to capture elements for searching that include forms of reasoning and heuristics, math strand, math problem, NCTM standards, grade level and type of educational environment. Students and researchers are identified and can be individually tracked through the collection. Transcripts, student work and dissertations resulting from the videos are linked in metadata. Tools, such as the VMCAnalytic, a video annotation and analysis tool, are provided to enable registered participants to reuse the videos for instruction, study and research by creating personal clips and combining clips to accomplish research goals such as demonstrating changes in reasoning for an individual student studying probability over several video sessions. Unlike other video annotation tool, the VMC analytic creates XML-based independent resources that can be kept private in the researcher’s workspace but that can also be shared. Shared analytics will be mined for keywords, which will retrieve the video(s) being analyzed, thus adding user tagging to the metadata for the videos. The analytic resources created are not independently searched and displayed but will display as part of the context for the videos in the collection, along with student work, dissertations, and ultimately published articles, etc., all of which form the critical context of research and study surrounding each video.
Different search strategies, guidance in using videos and opportunities to consult or collaborate with others will be provided for each primary audience of the VMC. The latest iteration of the portal, with collections and services available for immediate use, will be presented and demonstrated at the DRK12 Principal Investigators’ meeting poster session. Visitors to the poster will be encouraged to search the portal and to create a small analytic, in a hands-on, interactive one on one demonstration. We believe that the VMC makes a unique and significant contribution to the efforts of teacher educators, practicing teachers and researchers to discover insights and develop innovative strategies to support the development of student reasoning in mathematics education.
Researchers are developing a practice-based curriculum for the professional education of preservice and practicing secondary mathematics teachers that focuses on reasoning and proving; has narrative cases as a central component; and supports the development of knowledge of mathematics needed for teaching. This curriculum is comprised of eight constellations of activities that focus on key aspects of reasoning and proving such as identifying patterns; making conjectures; providing proofs; and providing non-proof arguments.
This project augmenting the traditional professional development model with an online professional development platform—the Active Physics Teacher Community—that provides just-in-time support for teachers as they are enacting targeted units of the Active Physics curriculum. Teachers are helped in preparing lessons by providing them with formal instruction related to the lessons they are teaching in the classroom. In addition, teachers can participate in a moderated forum where they can share experiences.
This project is carrying out a research and development initiative to increase the success rates of our most at-risk high school students—ninth-grade students enrolled in algebra classes but significantly underprepared for high school mathematics. It will also result in new understandings about effective approaches for teaching mathematics to struggling students and about effective ways for implementing these approaches at scale, particularly in urban school districts.
Intensified Algebra I, a comprehensive program used in an extended-time algebra class, helps students who are one to two years behind in mathematics become successful in algebra. It is a research and development initiative of the Charles A. Dana Center at The University of Texas at Austin, the Learning Sciences Research Institute at the University of Illinois at Chicago, and Agile Mind, that transforms the teaching of algebra to students who struggle in mathematics. Central to the program is the idea that struggling students need a powerful combination of a challenging curriculum, cohesive, targeted supports, and additional well-structured classroom time. Intensified Algebra I seeks to addresses the need for a robust Algebra I curriculum with embedded, efficient review and repair of foundational mathematical skills and concepts. It aims to address multiple dimensions of learning mathematics, including social, affective, linguistic, and cognitive. Intensified Algebra I uses an asset-based approach that builds on students’ strengths and helps students to develop academic skills and identities by engaging them in the learning experience. The program is designed to help struggling students succeed in catching up to their peers, equipping them to be successful in Algebra I and their future mathematics and science courses.
This project hypothesizes that learners must have access to the real work of scientists if they are to learn both about the nature of science and to do inquiry themselves. It explores the question "How can informal science education institutions best design resources to support teachers, school administrators, and families in the teaching and learning of students to conduct scientific investigations and better understand the nature of science?"
The American Museum of Natural History and Michigan State University propose a research and development project focused on DR-K12 challenge #2 and the hypothesis that learners must have access to the real work of scientists if they are to learn both about the nature of science and to do inquiry themselves. The overarching questions that drive this project are: How can informal science education institutions best design resources to support teachers, school administrators, and families in the teaching and learning of students to conduct scientific investigations and better understand the nature of science? How are these resources then used, and to what extent and in what ways do they contribute to participants’ learning? How are those resources then used for student learning? Answering these questions will involve the use of existing and new resources, enhancement of existing relationships, and a commitment to systematically collect evidence. Urban Advantage (UA) is a middle school science initiative involving informal science education institutions that provides professional development for teachers and hands-on learning for students to learn how to conduct scientific investigations. This project will (1) refine the UA model by including opportunities to engage in field studies and the use of authentic data sets to investigate the zebra mussel invasion of the Hudson River ecosystem; (2) extend the resources available to help parents, administrators, and teachers understand the nature of scientific work; and (3) integrate a research agenda into UA. Teaching cases will serve as resources to help teachers, students, administrators, and families understand scientific inquiry through research on freshwater ecosystems, and—with that increased understanding—support student learning. Surveys, observations, and assessments will be used to document and understand the effects of professional development on teachers, students, administrators, and parents. The study will analyze longitudinal, multivariate data in order to identify associations between professional development opportunities for teachers, administrators, and parents, their use of resources to support their own learning and that of students, middle school teachers’ instructional practices, and measures of student learning.
This project will develop video-case modules for use in pre-service teacher preparation programs. Modules will target specific grade bands (K-3, 4-5, 6-8) and address standards-based content domains, to help future teachers deepen their content knowledge, pedagogic skills and ability to analyze student thinking. The cases will illustrate reform classroom practices and more traditional instruction, include interviews with teachers and students, and incorporate a set of analytic tasks that promote users' critical observations of the cases.