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Modeling Students' Mathematical Modeling Competencies : ICTMA 13 (2013)

Lesh, Richard ; Galbraith, Peter L. ; Haines, Christopher R. ; [et al.]

Dordrecht : Springer Netherlands

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ISBN: 9789400762718

Language: English

Pages: Online-Ressource (XIV, 651 p. 134 illus, digital)

Series Statement: International Perspectives on the Teaching and Learning of Mathematical Modelling

Series Statement: SpringerLink

Series Statement: Bücher

Parallel Title: Buchausg. u.d.T.

RVK:

DP 4600

RVK:

SM 630

RVK:

TB 4053

RVK:

UB 4049

RVK:

VB 4052

Keywords: Mathematics ; Education ; Education ; Mathematics

Abstract: Modeling Students Mathematical Modeling Competencies offers welcome clarity and focus to the international research and professional community in mathematics, science, and engineering education, as well as those involved in the sciences of teaching and learning these subjects.

Abstract: Modeling Students' Mathematical Modeling Competencies offers welcome clarity and focus to the international research and professional community in mathematics, science, and engineering education, as well as those involved in the sciences of teaching and learning these subjects

Description / Table of Contents: Modeling Students' Mathematical Modeling Competencies; Contents; Contributors; Chapter 1: Introduction: ICTMA and the Teaching of Modeling and Applications; Part I: The Nature of Models & Modeling; Chapter 2: Introduction to Part I Modeling: What Is It? Why Do It?; References; Section 1: What Are Models?; Chapter 3: Modeling Theory for Math and Science Education; 3.1 Introduction; 3.2 Origins of Modeling Theory; 3.3 Models and Concepts; 3.4 Imagination and Intuition; 3.5 Mathematical Versus Physical Intuition; 3.6 Modeling Instruction; 3.7 Conclusions

Description / Table of Contents: 3.8 Epilogue: A New Generation of Mathematical ToolsReferences; Chapter 4: Modeling a Crucial Aspect of Students' Mathematical Modeling; 4.1 Introduction; 4.2 Three Examples; 4.3 The Intricacies of Mathematization; 4.4 Modeling Students' Mathematizations; References; Chapter 5: Modeling Perspectives in Math Education Research; 5.1 Introduction; 5.2 Spesier and Walter on Models; 5.3 Harel on Models; 5.4 Larson on Models; 5.5 Oehrtman on Models; 5.6 Rasmussen and Zandieh on Models; References; Section 2: Where Are Models & Modelers Found?

Description / Table of Contents: Chapter 6: Modeling to Address Techno-Mathematical Literacies in Work6.1 Introduction; 6.2 Methodology; 6.3 Findings; 6.4 Results; 6.4.1 Two Examples: Manufacturing and Statistical Process Control; 6.5 Conclusions; References; Chapter 7: Mathematical Modeling in Engineering Design Projects; 7.1 Introduction; 7.2 Methodology; 7.2.1 Industrial Engineering Undergraduates; 7.2.2 Mechanical Engineering Graduate Students; 7.3 Discussion; 7.4 Conclusion; References; Chapter 8: The Mathematical Expertise of Mechanical Engineers - The Case of Mechanism Design; 8.1 Introduction

Description / Table of Contents: 8.2 Method of Investigation8.3 The Task: Design of Part of a Cutting Device; 8.4 Results and Discussion; 8.5 Conclusions; References; Section 3: What Do Modeling Processes Look Like?; Chapter 9: Modeling and Quantitative Reasoning: The Summer Jobs Problem; 9.1 Theoretical Framework; 9.2 Methods; 9.3 Results; 9.3.1 What Is the Students' Model?; 9.3.2 What Is the Role of Quantities in Students' Models?; 9.3.3 What Is the Role of Quantitative Reasoning in Students' Models?; 9.3.4 What Is the Relationship Between Quantitative Reasoning and Model Development?; 9.4 Discussion; References

Description / Table of Contents: Chapter 10: Tracing Students' Modeling Processes in School10.1 Introduction; 10.2 Theoretical Framework; 10.3 The Present Study; 10.3.1 The Purpose of the Study; 10.3.2 Participants, Modelling Activity, and Procedures; 10.3.3 Data Sources and Analysis; 10.4 Results; 10.4.1 Modelling Processes; 10.4.2 Mathematical Developments; 10.5 Discussion; References; Section 4: What Creates "The Need For Modeling"; Chapter 11: Turning Ideas into Modeling Problems; 11.1 Introduction; 11.2 Approaches to Mathematical Modeling; 11.2.1 Modeling as Vehicle; 11.2.2 Modeling as Content

Description / Table of Contents: 11.3 Educational Rationale

Note: Includes bibliographical references and index

DOI: 10.1007/978-94-007-6271-8

URL: Volltext

URL: Cover

URL: Inhaltstext

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Modeling Students' Mathematical Modeling Competencies : ICTMA 13 (2010)

Lesh, Richard ; Galbraith, Peter L. ; Haines, Christopher R. ; [et al.]

Boston, MA : Springer Science+Business Media, LLC

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ISBN: 9781441905611

Language: English

Pages: Online-Ressource , v.: digital

Edition: 1

Edition: Online-Ausg. Springer eBook Collection. Humanities, Social Science and Law Electronic reproduction; Available via World Wide Web

RVK:

SD 2007

RVK:

SM 603

RVK:

SM 619

RVK:

DP 4600

RVK:

SM 630

RVK:

TB 4053

RVK:

UB 4049

RVK:

VB 4052

Keywords: Education ; Mathematics ; Science Study and teaching ; Mathematikunterricht ; Mathematisches Modell ; Fähigkeit

Abstract: As we enter the 21st century, there is an urgent need for new approaches to mathematics education emphasizing its relevance in young learners' futures. Modeling Students' Mathematical Modeling Competencies explores the vital trend toward using real-world problems as a basis for teaching mathematics skills, competencies, and applications. Blending theoretical constructs and practical considerations, the book presents papers from the latest conference of the ICTMA, beginning with the basics (Why are models necessary? Where can we find them?) and moving through intricate concepts of how students perceive math, how instructors teach and how both can become better learners. Dispatches as varied as classroom case studies, analyses of math in engineering work, and an in-depth review of modeling-based curricula in the Netherlands illustrate modeling activities on the job, methods of overcoming math resistance, and the movement toward replicable models and lifelong engagement. A sampling of topics covered: How students recognize the usefulness of mathematics Creating the modeling-oriented classroom Assessing and evaluating students' modeling capabilities The relationship between modeling and problem-solving Instructor methods for developing their own models of modeling New technologies for modeling in the classroom Modeling Students' Mathematical Modeling Competencies offers welcome clarity and focus to the international research and professional community in mathematics, science, and engineering education, as well as those involved in the sciences of teaching and learning these subjects.

Note: Includes bibliographical references , Electronic reproduction; Available via World Wide Web

DOI: 10.1007/978-1-4419-0561-1

URL: Volltext (lizenzpflichtig)

URL: Inhaltstext

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Research in Science Education — Past, Present, and Future (2001)

Behrendt, Helga [HerausgeberIn] ; Dahncke, Helmut [HerausgeberIn] ; Duit, Reinders [HerausgeberIn] ; [et al.]

Dordrecht : Imprint: Springer | Dordrecht : Springer Netherlands

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ISBN: 9780306476396

Language: English

Pages: 1 Online-Ressource(VIII, 344 p.)

Edition: 1st ed. 2001.

Parallel Title: Erscheint auch als

RVK:

DB 3000

RVK:

TB 4050

Keywords: Learning. ; Instruction. ; Science education. ; Teaching. ; Educational technology. ; Chemistry. ; Humanities. ; Science—Study and teaching. ; Teachers—Training of. ; Learning, Psychology of. ; Social sciences. ; Education ; Chemistry ; Science Study and teaching ; Teachers Training of ; Naturwissenschaftlicher Unterricht ; Naturwissenschaftliche Bildung

Abstract: Views and Visions of Science Education Research -- Science Education Researchers and Research in Transition: Issues and Policies -- Research in Science Education in Europe: Retrospect and Prospect -- Science Content as Problematic - Issues for Research -- Science Education Versus Science in the Academy: Questions - Discussion - Perspectives -- Scientific Literacy — Conceptions and Assessment -- The Assessment of Scientific Literacy in the OECD/PISA Project -- Scientific Literacy: From Theory to Practice -- Making Formative Use of a National Summative Assessment Regime -- A Comparison of STS-teaching and Traditional Physics Lessons - On the Correlation of Physics Knowledge and Taking Action -- Students’ Conceptions -- On the Quantum Thinking of Physics Undergraduates -- Experiences with a Modern Course in Quantum Physics -- Learning Process Studies in the Field of Fractals -- Students’ Understandings of their Internal Structure as Revealed by Drawings -- Personal Context and Continuity of Human Thought; Recurrent Themes in a Longitudinal Study of Pupils’ Understanding of Scientific Phenomena -- Entities of the World and Causality in Children’s Thinking -- Using Media Reports of Science Research in Pupils’ Evaluation of Evidence -- Pupils’ Perceptions of Science Education at Primary and Secondary School -- Teachers’ Conceptions -- Teacher Professionalism and Change: Developing a Professional Self Through Reflective Assessment -- Formative Assessment Using Concept Cartoons: Initial Teacher Training in the UK -- Teaching Chemical Equilibrium in Australian and German Senior High Schools -- The Ideas of Spanish Primary Teachers on how to Develop an Understanding of Processes in Science and their Support in Textbooks -- Pre-service Elementary Teachers Constructing the Nature and Language of Science -- Combining Knowledge of Physics and Chemistry in Teaching: The Behaviour of a Narrow Jet of Water in the Presence of Charged Insulators -- Intuitive Rules: A Theory and its Implications to Mathematics and Science Teacher Education -- Conceptual Change — Teaching and Learning Processes -- Conceptual Change Research and the Teaching of Science -- Rhetoric and Science Education -- Development of Complexity through Dealing with Physical Qualities: One Type of Conceptual Change? -- On the Micro-structure of Analogical Reasoning: The Case of Understanding Chaotic Systems -- Role-playing, Conceptual Change, and the Learning Process: A Case Study of 7th Grade Pupils -- Concept Mapping as a Tool for Research in Science Education -- The Need for and the Role of Metacognition in Teaching and Learning the Particle Model -- Evolving Mental Models of Electric Circuits -- Two Models for a Physical Situation: the Case of Optics. Students’ Difficulties, Teachers’ Viewpoints and Guidelines for a ?Didactic Structure? -- The Influence of a Historically Oriented Course on the Content Knowledge of Students in Optics -- Using Everyday and Scientific Conceptions for Developing Guidelines of Teaching Microbiology -- Teaching and Learning the Concept of the Model in Secondary Schools -- Conceptual Change and Student Diversity: The Case of Volcanism at Primary School -- The Development of Prospective Teachers’ Concerns about Teaching Chemistry Topics at a Macro-micro-symbolic Interface -- How to Enhance Students’ Motivation and Ability to Communicate in Science Class-discourse -- How do Boys and Girls use Language in Physics Classes? -- Instructional Media and Lab Work -- Improving the Use of Instructional Illustrations in Learning Chemistry -- Computing in Stereochemistry - 2D or 3D Representations? -- Learning Physics with Multimedia- and Experimental-supported Workshop Instruction -- Generating Hypotheses in Scientific Enquiry -- Using Laboratory Work for Purposeful Learning about the Practice of Science -- University Students During Practical Work: Can We Make the Learning Process Intelligible? -- Learning About Investigations - The Teacher’s Role -- Point and Set Paradigms in Students’ Handling of Experimental Measurements -- Beyond the Laboratory-learning Physics Using Real-life Contexts.

Abstract: This volume includes articles based on papers presented at the Second International Conference of the European Science Education Research Association (E.S.E.R.A.) held in Kiel, August 31 to September 4, 1999. About 300 colleagues, virtually from around the world - with a particular European focus - participated. Some 200 papers were presented. Three pages synopses of these papers were published in Proceedings of the conference (edited by Michael Komorek, Helga Behrendt, Helmut Dahncke, Reinders Duit, Wolfgang Gräber and Angela Kross). They are available from the IPN homepage: http://www.ipn.uni-kiel.de. The participants were asked to submit contributions to the present volume. It contains the invited plenary lectures and a selection of the submitted contributions based on reviews by an international board and the editors. The volume mirrors main lines of research in science education in Europe and around the world. The invited lectures provide overviews of the growth of science education research from the past to the present, including views of future developments. Major emphasis of empirical research still seems to be students' conceptions and conceptual change. About half of the contributions fall into that category. In addition, most of the remaining contributions deal with various cognitive issues of teaching and learning science. It was surprising for us that the number of studies on affective issues and gender differences was much smaller than expected.

Note: Includes bibliographical references and index

DOI: 10.1007/0-306-47639-8

URL: lizenzpflichtig

URL: Volltext

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