Projects

The goal of these two linked conferences was to build more effective connections between research and practice. Specifically, the conferences brought together researchers, practitioners. and policy makers around improving students' mathematics proficiency by ensuring that researchers were investigating the most urgent problems of practice and that practitioners were connected to the research in ways that makes the knowledge useful to instruction.

The Coaching Cycle project is creating an online course for K–8 mathematics instructional coaches. The project targets coaches in rural areas and small schools who do not have access to regular district-wide professional development. It provides training in the skills needed for effective instructional coaching in mathematics by using artifacts collected by practicing coaches to engage course participants in the practice of coaching skills.

This project has pioneered simulation-based assessments of model-based science learning and inquiry practices for middle school physical and life science systems. The assessment suites include curriculum-embedded, formative assessments that provide  immediate, individualized feedback and graduated coaching with supporting reflection activities as well as summative end-of-unit benchmark assessments. The project has documented the instructional benefits, feasibility, utility, and technical quality of the assessments with over 7,000 students and 80 teachers in four states.

The primary purpose of this international conference was for participants in the US to exchange views and discuss the latest research findings on (primary) science assessment. The conference focused on research around building assessment systems that help teachers diagnose student learning in the classroom but also link meaningfully to large-scale accountability systems (in districts or national levels). The project resulted in a report, proceedings, journal publications.

The PuM project develops and conducts research on a learning continuum for seamless instruction in middle school physical science and high school physics. The ultimate goal is to use physics as the context to develop mathematics literacy, particularly with students from underrepresented populations and special needs students. The research component analyzes the effects of the curriculum on students' learning while simultaneously investigating teachers' pedagogical content knowledge in a variety of forms.

This project aims to develop a software diagnostic tool for integrating diagnostic interviews, group administered assessments, and student data in real-time so that teachers can enter and view student status information. This project would concentrate on rational number learning in grades 3-8. The design is based on a model of learning trajectories developed from existing research studies.

This project covers participants' costs to attend a national conference series focusing upon supporting incipient science education research projects. A primary objective is to provide a venue in which researchers can describe their lines of inquiry and to then receive guidance and input about refining those ambitions. The other primary objective is to promote an innovative conference design in which a structured presentation format serves as an incubator for scholarly work.

Understanding Science provides an accurate portrayal of the nature of science and tools for teaching associated concepts. This project has at its heart a public re-engagement with science that begins with teacher preparation. To this end, its immediate goals are (1) improve teacher understanding of the nature of the scientific enterprise and (2) provide resources and strategies that encourage and enable K-16 teachers to incorporate and reinforce the nature of science throughout their science teaching.

This research study investigates the impact of the wireless environment on high school science resulting in a professional development model that will inform professional developers, administrators, policy-makers and teachers. The project uses in-depth case studies to examine context factors (e.g. technology implementation plans, school culture, extent and type of teacher professional development and teacher background) and critical interactions that may influence science instructional practice in wireless high school science classrooms.