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Author: Chong Ho Yu
Publisher: Springer Nature
ISBN: 9811531560
Category : Education
Languages : en
Pages : 171
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Book Description
This book discusses the merits and potential shortcomings of Hong Kong STEM education from Grade 8 to Grade 12. Based on concurrent triangulated mixed-method methodology, which integrates both quantitative and qualitative procedures, it describes various change models and proposes new models that are considered compatible with Western cultures.
Author: Chong Ho Yu
Publisher: Springer Nature
ISBN: 9811531560
Category : Education
Languages : en
Pages : 171
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Book Description
This book discusses the merits and potential shortcomings of Hong Kong STEM education from Grade 8 to Grade 12. Based on concurrent triangulated mixed-method methodology, which integrates both quantitative and qualitative procedures, it describes various change models and proposes new models that are considered compatible with Western cultures.
Author: Susan Loucks-Horsley
Publisher: Corwin Press
ISBN: 1452208298
Category : Education
Languages : en
Pages : 425
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Book Description
The classic guide for designing robust science and mathematics professional development programs! This expanded edition of one of the most widely cited resources in the field of professional development for mathematics and science educators demonstrates how to design professional development experiences for teachers that lead to improved student learning. Presenting an updated professional development (PD) planning framework, the third edition of the bestseller reflects recent research on PD design, underscores how beliefs and local factors can influence PD design, illustrates a wide range of PD strategies, and emphasizes the importance of: Continuous program monitoring Combining strategies to address diverse needs Building cultures that sustain learning
Author: National Research Council
Publisher: National Academies Press
ISBN: 0309083001
Category : Education
Languages : en
Pages : 59
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Book Description
Improving Mathematics Education has been designed to help inform stakeholders about the decisions they face, to point to recent research findings, and to provide access to the most recent thinking of experts on issues of national concern in mathematics education. The essence of the report is that information is available to help those charged with improving student achievement in mathematics. The documents cited above can guide those who make decisions about content, learning, teaching, and assessment. The report is organized around five key questions: What should we teach, given what we know and value about mathematics and its roles? How should we teach so children learn, given what we know about students, mathematics, and how people learn mathematics? What preparation and support do teachers need? How do we know whether what we are doing is working? What must change? Each of the five main chapters in this report considers a key area of mathematics education and describes the core messages of current publication(s) in that area. To maintain the integrity of each report's recommendations, we used direct quotes and the terminology defined and used in that report. If the wording or terminology seems to need clarification, the committee refers the reader directly to the original document. Because these areas are interdependent, the documents often offer recommendations related to several different areas. While the individual documents are discussed under only one of the components in Improving Mathematics Education, the reader should recognize that each document may have a broader scope. In general, the references in this report should serve as a starting point for the interested reader, who can refer to the original documents for fuller discussions of the recommendations and, in some cases, suggestions for implementation. Improving Mathematics Education is designed to help educators build a critical knowledge base about mathematics education, recognizing that the future of the nation's students is integrally intertwined with the decisions we make (or fail to make) about the mathematics education they receive.
Author: Ole Skovsmose
Publisher: Springer Science & Business Media
ISBN: 0387098291
Category : Education
Languages : en
Pages : 353
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Book Description
More than ever, our time is characterised by rapid changes in the organisation and the production of knowledge. This movement is deeply rooted in the evolution of the scientific endeavour, as well as in the transformation of the political, economic and cultural organisation of society. In other words, the production of scientific knowledge is changing both with regard to the internal development of science and technology, and with regard to the function and role science and technology fulfill in society. This general social context in which universities and knowledge production are placed has been given different names: the informational society, the knowledge society, the learning society, the post-industrial society, the risk society, or even the post-modern society. A common feature of different characterisations of this historic time is the fact that it is a period in construction. Parts of the world, not only of the First World but also chunks of the Developing World, are involved in these transformations. There is a movement from former social, political and cultural forms of organisation which impact knowledge production into new forms. These forms drive us into forms of organisation that are unknown and that, for their very same complexity, do not show a clear ending stage. Somehow the utopias that guided the ideas of development and progress in the past are not present anymore, and therefore the transitions in the knowledge society generate a new uncertain world. We find ourselves and our universities to be in a transitional period in time. In this context, it is difficult to avoid considering seriously the challenges that such a complex and uncertain social configuration poses to scientific knowledge, to universities and especially to education in mathematics and science. It is clear that the transformation of knowledge outside universities has implied a change in the routes that research in mathematics, science and technology has taken in the last decades. It is also clear that in different parts of the world these changes have happened at different points in time. While universities in the "New World" (the American Continent, Africa, Asia and Oceania) have accommodated their operation to the challenges of the construction in the new world, in many European countries universities with a longer existence and tradition have moved more slowly into this time of transformation and have been responding at a less rapid pace to environmental challenges. The process of tuning universities, together with their forms of knowledge production and their provision of education in science and mathematics, with the demands of the informational society has been a complex process, as complex as the general transformation undergoing in society. Therefore an understanding of the current transitions in science and mathematics education has to consider different dimensions involved in such a change. Traditionally, educational studies in mathematics and science education have looked at changes in education from within the scientific disciplines and in the closed context of the classroom. Although educational change in the very end is implemented in everyday teaching and learning situations, other parallel dimensions influencing these situations cannot be forgotten. An understanding of the actual potentialities and limitations of educational transformations are highly dependent on the network of educational, cultural, administrative and ideological views and practices that permeate and constitute science and mathematics education in universities today. This book contributes to understanding some of the multiple aspects and dimensions of the transition of science and mathematics education in the current informational society. Such an understanding is necessary for finding possibilities to improve science and mathematics education in universities all around the world. Such a broad approach to the transitions happening in these fields has not been addressed yet by existing books in the market.
Author: Iris R. Weiss
Publisher: Heinemann Educational Books
ISBN:
Category : Education
Languages : en
Pages : 116
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Book Description
Take advantage of what this volume offers. You will be in a better position to make well-informed decisions because you will be able to see the full sweep of what constitutes quality professional development for mathematics and science teachers. - Barbara Miller Education Development Center, Inc. You've decided it's time for something different. A new way to teach mathematics and science that supports higher achievement in all students. And that means rethinking how you provide teacher professional development. Sounds like a tough task, but you've got a guide to doing it right. Mathematics and Science for a Change collects the wisdom of successful initiatives into one concise guide to making successful change. Mathematics and Science for a Changedescribes the lessons learned by effective National Science Foundation - funded Local Systemic Change programs. Iris Weiss and Joan Pasley support your initiative with key practices drawn from a careful examination of more than ten years of case histories and data. With their observations, you'll: lay the groundwork for change by diagnosing your building or district needs and establishing a vision for high-quality mathematics and science instruction that is consistent with national standards design professional development that achieves your goals by deepening teacher content knowledge, modeling best-practice instruction, and encouraging more productive assessments launch and sustain your professional development model by identifying, preparing, and supporting PD providers then uncovering and nurturing leadership among your staff bolster your improvement effort by enlisting key school or district leaders, partnering with the mathematics and science community outside your system, and engaging the support of parents. Weiss and Pasley fill Mathematics and Science for a Change with on-the-ground advice and the specific strategies of top initiatives around the country. Everything in their book helps you smoothly meet the most important objective of any change program: helping every student learn mathematics and science better.
Author: National Research Council
Publisher: National Academies Press
ISBN: 0309037409
Category : Education
Languages : en
Pages : 231
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Book Description
This book presents a carefully developed monitoring system to track the progress of mathematics and science education, particularly the effects of ongoing efforts to improve students' scientific knowledge and mathematics competency. It describes an improved series of indicators to assess student learning, curriculum quality, teaching effectiveness, student behavior, and financial and leadership support for mathematics and science education. Of special interest is a critical review of current testing methods and their use in probing higher-order skills and evaluating educational quality.
Author: Cathery Yeh
Publisher: National
ISBN: 9780873539081
Category : Educational change
Languages : en
Pages : 0
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Book Description
Presents a comprehensive systems approach to examining mathematics teaching. This volume synthesizes and illustrates current research on the essential elements of mathematics teaching and learning, unpacking each component. In addition, tips on using technology to assess and enhance learning are embedded throughout the book.
Author: Kay McKinney
Publisher: Department of Education
ISBN:
Category : Business & Economics
Languages : en
Pages : 40
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Book Description
A 1992 conference on mathematics and science teaching focused on two specific topics: enhanced professional development for educators and better instructional materials for the classroom. Teachers, members of Congress, governors, teacher educators, professors, researchers, and policymakers shared what they believed was needed to be done to improve mathematics and science education in the United States. This booklet reports the views of the participants and the general consensus of the conference regarding changes needed in the education system. The concepts of systemic reform in education and the setting of national standards as exemplified by the National Council of Teachers of Mathematics are discussed in section 1. The second section discusses the necessity of providing all children with an opportunity to learn mathematics and science. The third section reports the participants' views emphasizing courses that teach mathematics and science for understanding. The fourth section discusses the necessity to prepare teachers of math and science to higher standards of skill and knowledge. Extensive professional development to help practicing teachers enhance their skills is suggested. The fifth section examines the need for the development of better instructional materials for the mathematics and science classroom. Finally, 20 recommendations in the following 4 themes are reported: (1) standards; (2) improving mathematics and science teaching; (3) instructional materials; and (4) systemic change. A list of presenters and demonstrators and a statement of principles on school reform in mathematics and science are provided. (MDH)
Author: National Academies of Sciences, Engineering, and Medicine
Publisher: National Academies Press
ISBN: 0309380189
Category : Education
Languages : en
Pages : 257
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Book Description
Currently, many states are adopting the Next Generation Science Standards (NGSS) or are revising their own state standards in ways that reflect the NGSS. For students and schools, the implementation of any science standards rests with teachers. For those teachers, an evolving understanding about how best to teach science represents a significant transition in the way science is currently taught in most classrooms and it will require most science teachers to change how they teach. That change will require learning opportunities for teachers that reinforce and expand their knowledge of the major ideas and concepts in science, their familiarity with a range of instructional strategies, and the skills to implement those strategies in the classroom. Providing these kinds of learning opportunities in turn will require profound changes to current approaches to supporting teachers' learning across their careers, from their initial training to continuing professional development. A teacher's capability to improve students' scientific understanding is heavily influenced by the school and district in which they work, the community in which the school is located, and the larger professional communities to which they belong. Science Teachers' Learning provides guidance for schools and districts on how best to support teachers' learning and how to implement successful programs for professional development. This report makes actionable recommendations for science teachers' learning that take a broad view of what is known about science education, how and when teachers learn, and education policies that directly and indirectly shape what teachers are able to learn and teach. The challenge of developing the expertise teachers need to implement the NGSS presents an opportunity to rethink professional learning for science teachers. Science Teachers' Learning will be a valuable resource for classrooms, departments, schools, districts, and professional organizations as they move to new ways to teach science.
Author: Marilyn Paula Carlson
Publisher: MAA
ISBN: 9780883851838
Category : Mathematics
Languages : en
Pages : 340
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Book Description
The chapters in this volume convey insights from mathematics education research that have direct implications for anyone interested in improving teaching and learning in undergraduate mathematics. This synthesis of research on learning and teaching mathematics provides relevant information for any math department or individual faculty member who is working to improve introductory proof courses, the longitudinal coherence of precalculus through differential equations, students' mathematical thinking and problem-solving abilities, and students' understanding of fundamental ideas such as variable and rate of change. Other chapters include information about programs that have been successful in supporting students' continued study of mathematics. The authors provide many examples and ideas to help the reader infuse the knowledge from mathematics education research into mathematics teaching practice. University mathematicians and community college faculty spend much of their time engaged in work to improve their teaching. Frequently, they are left to their own experiences and informal conversations with colleagues to develop new approaches to support student learning and their continuation in mathematics. Over the past 30 years, research in undergraduate mathematics education has produced knowledge about the development of mathematical understandings and models for supporting students' mathematical learning. Currently, very little of this knowledge is affecting teaching practice. We hope that this volume will open a meaningful dialogue between researchers and practitioners toward the goal of realizing improvements in undergraduate mathematics curriculum and instruction.
