Piaget’s Genetic Epistemology for Mathematics Education Research: Research in Mathematics Education
Editat de Paul Christian Dawkins, Amy J. Hackenberg, Anderson Nortonen Limba Engleză Hardback – 3 ian 2024
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Specificații
ISBN-13: 9783031473852
ISBN-10: 303147385X
Pagini: 617
Ilustrații: XVII, 617 p. 112 illus., 72 illus. in color.
Dimensiuni: 155 x 235 mm
Greutate: 1.06 kg
Ediția:1st ed. 2024
Editura: Springer International Publishing
Colecția Springer
Seria Research in Mathematics Education
Locul publicării:Cham, Switzerland
ISBN-10: 303147385X
Pagini: 617
Ilustrații: XVII, 617 p. 112 illus., 72 illus. in color.
Dimensiuni: 155 x 235 mm
Greutate: 1.06 kg
Ediția:1st ed. 2024
Editura: Springer International Publishing
Colecția Springer
Seria Research in Mathematics Education
Locul publicării:Cham, Switzerland
Cuprins
Section 1. Introduction to Piaget’s genetic epistemology and the tradition of use featured in this book.- Chapter 1) Introduction to Piaget’s Genetic Epistemology.- Chapter 2) An Historical Reflection on Adapting Piaget’s Work for Ongoing Mathematics Education Research.- Section 2. Key constructs from genetic epistemology being used in ongoing mathematics education research.- Chapter 3) Schemes and Scheme Theory: Core Explanatory Constructs for Studying Mathematical Learning.- Chapter 4) Operationalizing Figurative and Operative Framings of Thought.- Chapter 5) Figurative and Operative Imagery: Essential Aspects of Reflection in the Development of Schemes and Meanings.- Chapter 6) Empirical and Reflective Abstraction.- Chapter 7) Group and Group-like Structures.- Chapter 8) Reflected Abstraction.- Chapter 9) The Construct of Decentering in Research on Mathematics Learning and Teaching.- Chapter 10) Logic in Genetic Epistemology.- Chapter 11) Units Coordination.- Chapter 12) Modeling Quantitative and Covariational Reasoning.- Section 3. Commentaries on genetic epistemology and its use in ongoing research.- Chapter 13) Genetic Epistemology as a Complex and Unified Theory of Knowing.- Chapter 14) Second-Order Models as Acts of Equity.- Chapter 15) Reflections on the Power of Genetic Epistemology by the Modern Cognitive Psychologist.- Chapter 16) Skepticism and Constructivism.- Section 4. Using constructs from genetic epistemology to develop agendas of research.- Chapter 17) Researching Special Education: Using and Expanding Upon Genetic Epistemology Constructs – Jessica Hunt.- Chapter 18) Research in Subitizing to Examine Early Number Construction.- Chapter 19) Researching Coordinate Systems Using Genetic Epistemology Constructs.- Chapter 20) Researching Quantifications of Angularity Using Genetic Epistemology Constructs.- Chapter 21) UsingConstructivism to Develop an Agenda of Research in Stochastics Education Research.
Notă biografică
Dr. Paul Christian Dawkins is a Professor of mathematics education at Texas State University, USA. His research focuses on students’ learning of proof-oriented mathematics at the university level, specifically on student understanding of logic, defining, and axioms. Since he began as a professor in 2010, he has published 30 peer-reviewed journal articles and received multiple awards for his work, including the Selden Prize from the Mathematics Association of America. He serves on the editorial board of the Journal of Mathematical Behavior and the International Journal of Research in Undergraduate Mathematics Education.
Dr. Amy J. Hackenberg is a Professor of mathematics education at Indiana University, Bloomington, USA. Her research focuses on how middle school students construct rational number knowledge and algebraic reasoning and the role of units coordination in those processes. She also does research on how to orchestrate mathematics instruction for middle school students at different stages of units coordination, studying her own teaching as well as co-teaching with classroom teachers. She was the recipient of an early career award from the National Science Foundation, and she has earned the Trustees Teaching Award for excellence in teaching four times since she joined the faculty at IU in 2007. She serves on the Advisory Board of the journal For the Learning of Mathematics.Dr. Anderson Norton is a Professor of mathematics education in the Department of Mathematics at Virginia Tech. USA. His research focuses on building psychological models of students’ mathematical development—particularly in the domain of fractions knowledge—and epistemology of mathematics. He has served as chair for the editorial panel of the Journal for Research in Mathematics Education, chair of the steering committee for the North American Chapter of the International Group for the Psychology of Mathematics Education, and lead editor for the Springer book, Constructing Number. In 2013, in recognition of his outreach efforts, he received the Early Career Award from the Association of Mathematics Teacher Educators.
Dr. Amy J. Hackenberg is a Professor of mathematics education at Indiana University, Bloomington, USA. Her research focuses on how middle school students construct rational number knowledge and algebraic reasoning and the role of units coordination in those processes. She also does research on how to orchestrate mathematics instruction for middle school students at different stages of units coordination, studying her own teaching as well as co-teaching with classroom teachers. She was the recipient of an early career award from the National Science Foundation, and she has earned the Trustees Teaching Award for excellence in teaching four times since she joined the faculty at IU in 2007. She serves on the Advisory Board of the journal For the Learning of Mathematics.Dr. Anderson Norton is a Professor of mathematics education in the Department of Mathematics at Virginia Tech. USA. His research focuses on building psychological models of students’ mathematical development—particularly in the domain of fractions knowledge—and epistemology of mathematics. He has served as chair for the editorial panel of the Journal for Research in Mathematics Education, chair of the steering committee for the North American Chapter of the International Group for the Psychology of Mathematics Education, and lead editor for the Springer book, Constructing Number. In 2013, in recognition of his outreach efforts, he received the Early Career Award from the Association of Mathematics Teacher Educators.
Textul de pe ultima copertă
The book provides an entry point for graduate students and other scholars interested in using the constructs of Piaget’s genetic epistemology in mathematics education research. Constructs comprising genetic epistemology form the basis for some of the most well-developed theoretical frameworks available for characterizing learning, particularly in mathematics. The depth and complexity of Piaget’s work can make it challenging to find adequate entry points for learners, not least because it requires a reorientation regarding the nature of mathematical knowledge itself. This volume gathers leading scholars to help address that challenge. The main section of the book presents key Piagetian constructs for mathematics education research such as schemes and operations, figurative and operative thought, images and meanings, and decentering. The chapters that discuss these constructs include examples from research and address how these constructs can be used in research. There are two chapters on various types of reflective abstraction, because this construct is Piaget’s primary tool for characterizing the advancement of knowledge. The later sections of the book contain commentaries reflecting on the contributions of the body of theory developed in the first section. They connect genetic epistemology to current research domains such as equity and the latest in educational psychology. Finally, the book closes with short chapters portraying how scholars are using these tools in specific arenas of mathematics education research, including in special education, early childhood education, and statistics education.
Caracteristici
Introduces the use of Piaget’s Genetic Epistemology for mathematics education research Explains methodological requirements for using Piaget's key constructs of genetic epistemology Summarizes models of student thinking through the lens of Piaget's genetic epistemology Provides the perfect starting point for those hoping to engage with Piaget’s work for the teaching and learning of mathematics