Math Is Alive: The Metaphor of Living School Disciplines and Some of the Educational Implications by Stacy K. Stockton A Thesis submitted to the Faculty of Graduate Studies of the University of Manitoba in partial fulfillment of the requirements of the degree of MASTER OF EDUCATION Department of Curriculum, Teaching and Learning Faculty of Education University of Manitoba Winnipeg Copyright © 2017 by Stacy K. Stockton MATH IS ALIVE i Abstract This thesis is concerned with an unconventional understanding of the mathematics taught in schools and, thus, the role that students’ engagement with mathematics plays for mathematics as a discipline. The discipline of mathematics has a rich philosophical history. In this thesis I explore mathematics through the lens of metaphor theory first developed by George Lakoff and Mark Johnson. This area of scholarship is used to develop the idea that all abstract concepts are conceived of metaphorically. From this perspective, the metaphors at the foundation of several major philosophies of mathematics are analyzed. This analysis concludes by asking if there might be another metaphor that allows for a different, more productive, understanding of school mathematics than commonly used mathematical metaphors. The metaphor “Math is Alive” is offered as an alternative through a detailed analysis of living systems in the tradition of Humberto Maturana and Francisco Varela’s theory of autopoietic organization. The final chapter looks specifically at school mathematics as a part of mathematics as a discipline, and how “Math is Alive” might alter how educators view the role of children in mathematics. MATH IS ALIVE ii Acknowledgements This thesis would not have been possible without the guidance of my academic advisor, Thomas Falkenberg, and the support of my committee members, Barbara McMillan and Paul Betts. MATH IS ALIVE iii Table of Contents Page Introduction ………………………………………………………………………… 1 Chapter One: Metaphor …………………………………………………………….. 4 The Integrated Theory of Metaphor ……………………………………………... 5 Some Attributes of Metaphor ……………………………………………………. 6 Categories of Metaphor ………………………………………………………….. 8 Where Metaphors Come From ………………………………………….………. 10 New Metaphors …………………………………………………………………. 13 Conclusion ………………………………………………………………………. 15 Chapter Two: What Mathematics Is (metaphorically speaking) …………………… 17 Mathematics and Metaphor ……………………………………………………... 18 Philosophy of Mathematics …………………………………………………...… 20 Objectivist Philosophies ……………...……………………………………… 20 Platonism ………………………...……………………………………….. 20 Structuralism ……………………...………………………………………. 21 Deductive Philosophies …………...…………………….……………………. 23 Logicism …………………………………………………………………... 23 Formalism …………………………………………………………………. 25 Intuitionism …………………………...…………………………………... 26 Humanist Philosophies ……………………………………………………….. 29 Social Constructivism ……………...…………………...……………….... 29 Embodied Mathematics …………………………………………………… 32 MATH IS ALIVE iv Conclusion ………………………………………………………………………. 34 Chapter Three: Being Alive ……………………………………………………….... 36 Characteristics of Living Systems ………………………………………………. 38 Pattern of Organization ………………………………………………………. 39 Maintenance ………………………………………………………………….. 44 Growth, Adaptation and Evolution …………………………………………... 50 Conclusion ………………………………………………………………………. 60 Chapter Four: Making a Metaphor …………………………………………………. 62 Potential Mappings ……………………………………………………..……….. 63 Pattern of Organization ………………………………………………………. 65 Maintenance ………………………………………………………………….. 72 Growth, Adaptation and Evolution …………………………………………... 78 Conclusion ………………………………………………………………………. 87 Chapter Five: School Mathematics and Metaphor …………………………………. 89 School Mathematics as a Localized Area of Mathematics ……………………… 90 The Pervasiveness of Platonism …………………………………………..….. 92 Constructivism as Hidden Formalism ……………………………..………..... 96 Beyond Platonism ……………………………………………………..……... 98 Metaphors for Mathematics in Schools …………………………………….. 102 Research into Metaphors for Mathematics …………………………………. 103 Math is Alive …………………………………………………………………... 106 Pattern of Organization ……………………………………………………... 110 Maintenance ………………………………………………………………… 116 MATH IS ALIVE v Growth, Adaptation and Evolution …………………………………………. 122 Conclusion ..……………………………………………………………………. 125 References .………………………………………………………………………... 134 MATH IS ALIVE 1 “It is inorganic, yet alive, and all the more alive for being inorganic” (Deleuze & Guattari, 1987, p. 520). I first discovered the science of complexity in a course on arts education. My exploration of its application to the arts in schools inspired my particular interest in autopoietic systems, and led me to a study of biological living systems. Maturana and Varela’s Tree of Knowledge (1987), Capra’s Web of Life (1996), and Deleuze and Guattari’s Thousand Plateaus (1987) altered my understanding of being alive, and invited the possibility of living ideas. As a teacher, I am constantly confronted with uncertainties and differences in paradigm when exploring conceptions of disciplines through discussions with others and through professional development and readings. Paradigmatic changes in disciplines over time and competing current conceptions became more apparent to me. I also began to notice curious resemblances between living systems and disciplines. This included similarities in their patterns of organization, similarities in the way they behaved, and similarities in their processes of evolution. As I continued to read further, seeking more recent explorations of living concepts from a complexity perspective, I was unable to answer my questions about disciplines in particular, and what it would mean for education if they were conceived of as being alive. Just as Deleuze relies on his metaphor of rhizome to allow us to see our thinking about concepts differently, I have begun this thesis to ask if the metaphor of a living discipline might allow us to think differently about disciplines. Further, if we conceive of disciplines in this way, I wonder what this implies for the way that we currently engage with them in classrooms, and what this could become. This inquiry will be philosophical, relying on philosophical inquiry as described by Burbules and Warnick (2006), Floden and Buchmann (1990), and to some extent, John Wilson (1963). It MATH IS ALIVE 2 is not about finding answers, but about asking fundamental questions about what it means to be alive, and what we perceive our role to be in the production of disciplined knowledge. It is about the potential impact of these beliefs on disciplines themselves, which it would be impossible to empirically measure. This is the realm of philosophical inquiry. The methods I have selected represent several of Burbules and Warnick’s (2006) ten methods of philosophical inquiry. These will include the use of concept analysis (method 1, Burbules & Warnick, 2006, p. 491) through an extensive literature review on metaphor, the philosophy of mathematics, complex living systems, and school mathematics methods and metaphors. My thesis deals with the meanings that we assign to the terms we use in the contexts in which we use them, and how our conceptions guide our actions. Philosophical inquiry often relies on analyses of language or concepts. Inquiry will focus on terms that seem to play an important role in an argument or practice, trying to answer the question, what do these words or phrases mean or entail? (Floden & Buchmann, 1990, p. 3) Chapter one focuses on metaphor and its importance of our understanding of abstract concepts. Chapters two and three explore the target and source domains in a living mathematics metaphor, current conceptions of mathematics and the biology of living systems. Using information gathered regarding mathematics and living systems, a metaphor is then constructed in chapter four. This making of a metaphor will be shown to be a conceptual mapping, “an ambitious review of conceptual mapping may include a review of related concepts that share certain features with the primary object” (Burbules & Warnick, 2006, p. 492). The MATH IS ALIVE 3 creation of a metaphor can identify correspondences in structure, maintenance, and reproduction in complex systems and mathematics, following method 10, “synthesizing disparate research from philosophy itself or other fields to find meaning and implications for educational theory and practice” (Burbules & Warnick, 2006, p. 491). Here I ask: what does living have to do with mathematics? Through this, I will be required to show that the vitality of a discipline is one of the “ends or purposes education should achieve,” reflecting method 6 (Burbules & Warnick, 2006, p. 491). Finally, in chapter five I turn to method 7, “speculating about alternative systems or practices of education, whether utopian or programmatic, that contrast with and challenge conventional educational understandings and practices” (Burbules & Warnick, 2006, p. 491), in order to conceive of how this alternate view might impact the way mathematics is taught in schools. I will consider the implications of a living mathematics in educational practice, and how this might resolve difficulties with current perspectives, and create healthier relationships between children and mathematics. MATH IS ALIVE 4 CHAPTER ONE Metaphor “Language is a map, not a tracing” (Deleuze & Guattari, 1987, p. 98). Metaphor is a term most often used to describe a literary device. It is a type of figurative language used to compare objects with like properties. At least this is what I tell my grade six students. In 1980, Lakoff and Johnson challenged this assumption, by noticing the pervasiveness of everyday metaphors and their potential to shape our thinking (Kovecses, 2002, viii). These authors, as well as Gibbs (2008) and others continue to challenge our assumptions about metaphor comprehension, as knowledge about the inner workings of our brains increases. Interestingly, George Lakoff will reappear again later in this thesis when discussing philosophies of mathematics. In cognitive linguistics, metaphors have come to be regarded as any conceptual domain defined in terms of another (Kovecses, 2002, p. 4). It is surprising to realize how often we use metaphor in our everyday discourse, and how difficult it is to describe many things without it. Some metaphors become embedded in a concept, and become a part of that concept to the point where we are barely able to understand them as metaphors at all, and the concepts themselves mean little without them. “Just living an everyday life gives you the experience and suitable brain activations to give rise to a huge system of the same primary metaphorical mappings that are learned around the world without any awareness” (Lakoff as referenced in Gibbs, 2008, p. 26).
Description: