Teacher Outcomes

Dynamic Geometry in Classrooms

This project is conducting repeated randomized control trials of an approach to high school geometry that utilizes Dynamic Geometry (DG) software and supporting instructional materials to supplement ordinary instructional practices. It compares effects of that intervention with standard instruction that does not make use of computer drawing tools.

Project Email: 
Lead Organization(s): 
Award Number: 
Funding Period: 
Tue, 09/01/2009 to Sat, 08/31/2013
Project Evaluator: 
Ed Dickey
Full Description: 

The project is conducting repeated randomized control trials of an approach to high school geometry that utilizes dynamic geometry (DG) software and supporting instructional materials to supplement ordinary instructional practices.  It compares effects of that intervention with standard instruction that does not make use of computer drawing/exploraction tools. The basic hypothesis of the study is that use of DG software to engage students in constructing mathematical ideas through experimentation, observation, data recording, conjecturing, conjecture testing, and proof results in better geometry learning for most students. The study tests that hypothesis by assessing student learning in 76 classrooms randomly assigned to treatment and control groups. Student learning is assessed by a geometry standardized test, a conjecturing-proving test, and a measure of student beliefs about the nature of geometry and mathematics in general. Teachers in both treatment and control groups receive relevant professional development, and they are provided with supplementary resource materials for teaching geometry. Fidelity of implementation for the experimental treatment is monitored carefully. Data for answering the several research questions of the study are analyzed by appropriate HLM methods. Results will provide evidence about the effectiveness of DG approach in high school teaching, evidence that can inform school decisions about innovation in that core high school mathematics course. The main research question of the project is: Is the dynamic geometry approach better than the business-as-usual approach in facilitating the geometric learning of our students (and more specifically our economically disadvantaged students) over the course of a full school year?

The main resources/products include geometry teachers’ professional development training materials, suggested dynamic geometry instructional activities to supplement current high school geometry curriculum, instruments such as Conjecturing-Proving Test, Geometry Belief Instrument, Classroom Observation Protocols, DG Implementation Questionnaire and Student Interview Protocols. 

The general plan for the four-year project is as follows:

Year 1: Preparation (All research instruments, professional development training and resource materials, recruitment and training of participants, etc.); 

Year 2: The first implementation of the dynamic geometry treatment, and related data collection and initial data analysis; 

Year 3: The second implementation of the DG treatment, and related data collection and data analysis; 

Year 4: Careful and detailed data analysis and reporting.

We are now in project year 3. Data are collected for the second implementation of the DG treatment. For data collected during project year 2, some initial analysis (the analysis on the geometry pretest and posttest data and the psychometric analysis on the project developed instruments) has been conducted. More thorough analysis of the collected data is still on going. The analysis on the geometry test shows that the experimental group significantly outperformed the control group on geometry performance.

The evaluation will be implemented throughout the project’s four-year duration, with an evolving balance of formative and summative evaluation activities.  In the project’s first three years, the evaluation will emphasize formative functions, designed to inform the project research team of the relative strengths and weaknesses of the research design and execution, and target corrections and improvements of the research components. Summative evaluation activities will also take place in these years with the collection of data on student achievement and teacher change. Evaluation activities for year 4 will focus on the summative evaluation of the project’s accomplishment and especially its impact on participating teachers and students. Evaluation reports will be issued annually with a final summative report presented at the end of year 4.

The research results will be disseminated via the following efforts: 1) Creating and constantly updating the project web site; 2) Publishing the related research articles in research journals such as Journal for Research in Mathematics Education; 3) Presenting at state, regional, national, and international research and professional meetings; 4) Meeting with state and local education agencies, schools, and mathematics teacher educators at other universities for presenting the research findings and using the DG approach in more schools and more mathematics teacher education programs; and 5) Contacting more school districts, with a view to developing relationships and ties that would smooth the way to disseminate the research results.

Integrating Computing Across the Curriculum (ICAC): Incorporating Technology into STEM Education Using XO Laptops

This project builds and tests applications tied to the school curriculum that integrate the sciences with mathematics, computational thinking, reading and writing in elementary schools. The investigative core of the project is to determine how to best integrate computing across the curriculum in such a way as to support STEM learning and lead more urban children to STEM career paths.

Project Email: 
Award Number: 
Funding Period: 
Sat, 08/01/2009 to Sun, 07/31/2011
Project Evaluator: 
Leslie Cooksy - Univ. of Delaware
Full Description: 

Computer access has opened an exciting new dimension for STEM education; however, if computers in the classroom are to realize their full potential as a tool for advancing STEM education, methods must be developed to allow them to serve as a bridge across the STEM disciplines. The goal of this 60-month multi-method, multi-disciplinary ICAC project is to develop and test a program to increase the number of students in the STEM pipeline by providing teachers and students with curricular training and skills to enhance STEM education in elementary schools. ICAC will be implemented in an urban and predominantly African American school system, since these schools traditionally lag behind in filling the STEM pipeline. Specifically, ICAC will increase computer proficiency (e.g., general usage and programming), science, and mathematics skills of teachers and 4th and 5th grade students, and inform parents about the opportunities available in STEM-centered careers for their children.

The Specific Aims of ICAC are to:

SA1. Conduct a formative assessment with teachers to determine the optimal intervention to ensure productive school, principal, teacher, and student participation.

SA2. Implement a structured intervention aimed at (1) teachers, (2) students, and (3) families that will enhance the students’ understanding of STEM fundamentals by incorporating laptops into an inquiry-based educational process.

SA3. Assess the effects of ICAC on:

a. Student STEM  engagement and performance.

b. Teacher and student computing specific confidence and utilization.

c. Student interest in technology and STEM careers.

d. Parents’ attitudes toward STEM careers and use of computers.

To enable us to complete the specific aims noted above, we have conducted a variety of project activities in Years 1-3. These include:

  1. Classroom observations at the two Year 1 pilot schools
  2. Project scaling to 6 schools in Year 2 and 10 schools in Year 3
  3. Semi-structured school administrator interviews in schools
  4. Professional development sessions for teachers
  5. Drafting of curriculum modules to be used in summer teacher institutes and for dissemination
  6. In-class demonstration of curriculum modules
  7. Scratch festivals each May
  8. Summer teacher institutes
  9. Student summer camps
  10. Surveying of teachers in summer institutes
  11. Surveying of teachers and students at the beginning and end of the school year
  12. Showcase event at end of student workshops

The specific ICAC activities for Years 2-5 include:

  • Professional development sessions (twice monthly for teachers), to integrate the ‘best practices’ from the program.
  • Working groups led by a grade-specific lead teacher. The lead teacher for each grade in each school will identify areas where assistance is needed and will gather the grade-specific cohort of teachers at their school once every two weeks for a meeting to discuss the progress made in addition to challenges to or successes in curricula development.  
  • ICAC staff and prior trained teachers will visit each class monthly during the year to assist the teachers and to evaluate specific challenges and opportunities for the use of XOs in that classroom.  
  • In class sessions at least once per month (most likely more often given feedback from Teacher Summer Institutes) to demonstrate lesson plans and assist teachers as they implement lesson plans.
  • ICAC staff will also hold a joint meeting of administrators of all target schools each year to assess program progress and challenges. 
  • Teacher Summer Institutes – scaled-up to teachers from the new schools each summer to provide training in how to incorporate computing into their curriculum.
  • Administrator sessions during the Teacher Summer Institutes; designed to provide insight into how the laptops can facilitate the education and comprehension of their students in all areas of the curriculum, discuss flexible models for physical classroom organization to facilitate student learning, and discussions related to how to optimize the use of computing to enhance STEM curricula in their schools.  Student Summer Computing Camps – designed to teach students computing concepts, make computing fun, and enhance their interest in STEM careers.  
  • ICAC will sponsor a yearly showcase event in Years 2-5 that provides opportunities for parents to learn more about technology skills their children are learning (e.g., career options in STEM areas, overview of ICAC, and summary of student projects). At this event, a yearly citywide competition among students also will be held that is an expanded version of the weeklong showcase event during the student summer camps.
  • Surveying of students twice a year in intervention schools.
  • Surveying of teachers at Summer Institutes and then at the end of the academic year.
  • Coding and entry of survey data; coding of interview and observational data.
  • Data analysis to examine the specific aims (SA) noted above:
    • The impact of ICAC on teacher computing confidence and utilization (SA 3.b).
    • Assess the effects of (1) teacher XO training on student computing confidence and utilization (SA 3.b), (2) training on changes in interest in STEM careers (SA 3.c), and (3) XO training on student engagement (SA 3.a).
    • A quasi-experimental comparison of intervention and non-intervention schools to assess intervention effects on student achievement (SA 3.a).
    • Survey of parents attending the yearly ICAC showcase to assess effects on parental attitudes toward STEM careers and computing (SA 3.d).

The proposed research has the potential for broad impact by leveraging technology in BCS to influence over 8,000 students in the Birmingham area. By targeting 4th and 5th grade students, we expect to impact STEM engagement and preparedness of students before they move into a critical educational and career decision-making process. Further, by bolstering student computer and STEM knowledge, ICAC will impart highly marketable skills that prepare them for the 81% of new jobs that are projected to be in computing and engineering in coming years (as predicted by the US Bureau of Labor Statistics).3 Through its formative and summative assessment, ICAC will offer intellectual merit by providing teachers throughout the US with insights into how computers can be used to integrate the elementary STEM curriculum. ICAC will develop a model for using computers to enhance STEM education across the curriculum while instilling a culture among BCS schools where computing is viewed as a tool for learning.

(Previously listed under Award # 0918216)

Undergraduate Science Course Reform Serving Pre-service Teachers: Evaluation of a Faculty Professional Development Model

This project focuses on critical needs in the preparation and long-term development of pre-service, undergraduate, K-6 teachers of science. The project investigates the impact on these students of undergraduate, standards-based, reform entry level science courses developed by faculty based on their participation in the NASA Opportunities for Visionary Academics processional development program to identify: short-term impacts on undergraduate students and long-term effects on graduated teachers; characteristics of reform courses and characteristics of effective development efforts.

Project Email: 
Lead Organization(s): 
Award Number: 
Funding Period: 
Tue, 08/01/2006 to Sun, 07/31/2011
Full Description: 

The Undergraduate Science Course Reform Serving Pre-service Teachers: Evaluation of a Faculty Professional Development Model project is informally known as the National Study of Education in Undergraduate Science (NSEUS). This 5-year project focuses on critical needs in the preparation and long-term development of pre-service, undergraduate, K-6 teachers of science. The goal is to investigate the impact on these students of undergraduate, standards-based, reform entry-level science courses developed by faculty in the NASA Opportunities for Visionary Academics (NOVA) professional development model. Twenty reform and 20 comparison undergraduate science courses from a national population of 101 diverse institutions participating in NOVA, stratified by institutional type, were be selected and compared in a professional development impact design model. Data is being collected in extended on-site visits using multiple quantitative and qualitative instruments and analyzed using comparative and relational studies at multiple points in the impact design model. Criteria for success of the project will be determined by conclusions drawn from the research questions; including evidence and effect sizes of short-term impacts on undergraduate students and long-term effects on graduated in-service teachers in their own classroom science teaching; identification of characteristics of undergraduate reformed courses that produce significant impacts; identification of characteristics of effective faculty, and effective dissemination.

Project Publications and Presentations:

Lardy, Corrine; Mason, Cheryl; Mojgan, Matloob-Haghanikar; Sunal, Cynthia Szymanski; Sunal, Dennis Wayne; Sundberg, Cheryl & Zollman, Dean (2009). How Are We Reforming Teaching in Undergraduate Science Courses? Journal of College Science Teaching, v. 39 (2), 12-14.  

Building an Understanding of Science

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.

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Mon, 03/12/2007 to Wed, 05/11/2011
Project Evaluator: 

The Role of Educative Curriculum Materials in Supporting Science Teaching Practices with English Language Learners

This project aims to determine whether curricula designed to support teacher and student learning have positive impacts on teacher knowledge, attitudes, and instructional practices; to what degree educative curricula help teachers with more and less experience teaching ELLs and how level of teaching experience relates to teacher knowledge, attitudes, and instructional practices; and the effects of the educative curricula in high implementation settings on ELLs knowledge and attitudes in science, and developing English proficiency.

Project Email: 
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Funding Period: 
Mon, 09/01/2008 to Fri, 08/31/2012
Project Evaluator: 
Jonna Kulikowich

Researching the Expansion of K-5 Mathematics Specialist Program into Rural School Systems

This project addresses the challenge “How can promising innovations be successfully implemented, sustained, and scaled in schools and districts in a cost effective manner?” Project partners are researching the expansion of an established preparation and induction support program for K-5 mathematics specialists into rural school systems.

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Funding Period: 
Tue, 09/01/2009 to Wed, 08/31/2011
Project Evaluator: 
Horizon Research Inc.

Cyber-enabled Design Research to Enhance Teachers' Critical Thinking Using a Major Video Collection on Children's Mathematical Reasoning (Collaborative Research: Derry)

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.

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Mon, 09/15/2008 to Fri, 08/31/2012
Full Description: 

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.

Cases of Reasoning and Proving in Secondary Mathematics (CORP)

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.

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Funding Period: 
Sat, 09/01/2007 to Fri, 08/31/2012

Collaborative Online Projects for ELL Students (COPELLS)

This project is studying effects of linguistically sensitive science instructional materials by translating, enhancing, and evaluating culturally relevant and linguistically appropriate Collaborative Online Projects (originally written in Spanish) for middle school Spanish-speaking English Language Learners.

Project Email: 
Lead Organization(s): 
Partner Organization(s): 
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Funding Period: 
Tue, 09/01/2009 to Sat, 08/31/2013
Project Evaluator: 
Kari Nelsestuen
Full Description: 

Project COPELLS is a research and development project implemented by University of Oregon's Center for Advanced Technology in Education (CATE) and the Instituto Latinamericano de la Communicacion Educativa (ILCE). ILCE is a division of the Department of Education in Mexico that designs relevant collaborative online projects (COPs) for students K through 12.


Project COPELLS has selected, translated, and enhanced culturally relevant and linguistically appropriate COPs designed by ILCE to teach science to middle school, Spanish-speaking, English Language Learners. These COPs were aligned to both National Science Education Standards and Oregon secondary science standards by Oregon State Department of Education Science Curriculum educators. In addition, they were enhanced with supportive resources (etext supports) that promote bilingual use of the materials and increase science literacy in both English and Spanish.


The Center for Advanced Technology in Education has research-based experience enriching online reading materials with content-specific multimedia supports designed to scaffold text comprehension and content learning for struggling students. Specific etext supports identified as potentially useful for this population include: alternative text, audio, and video definitions of terms, translations, and enhanced illustrations that become available only when clicked to open by the reader.


The project's two major goals are to (a) facilitate and improve science content-area learning for Spanish-speaking ELL students and (b) facilitate their acquisition of Academic English while learning science content. Feasibility and usability of the Collaborative Online Projects is being classroom tested. The project is gathering information on the impact of the bilingual online science materials for improving science content-area learning, student attitude toward scientific learning, student and teacher satisfaction, and science academic language proficiency (ALP) of ELL students.


Key people:
Dr. Carolyn Knox, Principal Investigator
Dr. Kenneth Doxsee, Co-Principal Investigator
Dr. Fatima Terrazas-Arellanes, Co-Principal Investigador
Dr. Patricia Cabrera Muñoz, ILCE Partner

Supports for Learning to Manage Classroom Discussions: Exploring the Role of Practical Rationality and Mathematical Knowledge for Teaching

This project focuses on practicing and preservice secondary mathematics teachers and mathematics teacher educators. The project is researching, designing, and developing materials for preservice secondary mathematics teachers that enable them to acquire the mathematical knowledge and situated rationality central to teaching, in particular as it regards the leading of mathematical discussions in classrooms.

Award Number: 
Funding Period: 
Tue, 09/01/2009 to Fri, 08/31/2018
Project Evaluator: 
Miriam Gamoran Sherin
Full Description: 

Researchers at the Universities of Michigan and Maryland are developing materials to survey the rationality behind secondary mathematics teaching practice and to support the development by secondary mathematics preservice teachers of specialized knowledge and skills for teaching. The project focuses on the leading of classroom discussions for the learning of algebra and geometry.

Using animations of instructional scenarios, the project is developing online, multimedia questionnaires and using them to assess practicing teachers' mathematical knowledge for teaching and their evaluations of teacher decision making. Reports and forum entries from the questionnaires are integrated into a learning environment for prospective teachers and their instructors built around these animated scenarios. This environment allows pre-service teachers to navigate, annotate, and communicate about the scenarios; and it allows their instructors to plan using those scenarios and share experiences with their counterparts.

The research on teachers' rationality uses an experimental design with embedded one-way ANOVA, while the development of the learning environment uses a process of iterative design, implementation, and evaluation. The project evaluation by researchers at Northwestern University uses qualitative methods to examine the content provided in the environment as well as the usefulness perceived by teacher educators of a state network and their students.


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