Title: Reconceptualizing Algebraic Transformation as a Process of Substitution Equivalence
In this theoretical paper, we describe how algebraic transformation could be reconceptualized as a process of substitution equivalence, and we discuss how this conceptualization affords mathematical justification of transformation processes. In particular, we describe a model which deconstructs the process of substitution equivalence into core subdomains which could be learned serially and then re-integrated, in order to make them accessible to students with lower prior knowledge in syntactic reasoning. Our aim in presenting this model is to start a conversation about what the core components of knowledge might be in order for students to reason about and justify algebraic transformation using symbolic representations. more »« less
Wladis, C.; Sencindiver, B.; Offenholley, K.; Jaffe, E.; & Taton, J.
(, Proceedings for the 12th Congress of the European Society for Research in Mathematics Education (CERME12))
Cho, Sung Je
(Ed.)
This empirical paper explores students’ conceptions of transformation as substitution equivalence by linking it to their definitions of substitution and equivalence. This work draws on Sfard’s (1995) framework to conceptualize conceptions of substitution equivalence and its components, equivalence and substitution, each on a spectrum from computational to structural. We provide examples of student work to illustrate how students’ understandings of substitution, equivalence, and substitution equivalence as an approach to justifying transformation may relate to one another.
Wladis, C.; Sencindiver, B.; Offenholley, K.; Jaffe, E.; Taton, J.
(, Proceedings for the 24th Annual Conference on Research in Undergraduate Mathematics Education)
Karunakaran, S. S.; Higgins, A.
(Ed.)
This theoretical paper explores student conceptions of transformation as substitution equivalence by linking it to their definitions of substitution and equivalence. This work draws on the work of Sfard (1995) to conceptualize substitution equivalence and its components, equivalence and substitution, as a spectrum from computational to structural. We provide examples of students’ work to illustrate how student notions of substitution, equivalence, and substitution equivalence as an approach to justifying transformation may related to one another.
Sencindiver, B.; Wladis, C.; Offenholley, K.
(, Proceedings of the 44th Conference of the International Group for the Psychology of Mathematics Education)
Substitution is a key idea that is woven throughout the mathematics curriculum. In secondary school, substitution is described as an interchangeability of equal numbers, and then as a method for finding solutions of systems of equations. In university, substitution is used as a means to recognize familiar structures in Integral Calculus. Despite its prevalence in mathematics, there is little research on substitution, especially on students’ understanding of substitution. This work aims to investigate students’ meanings for substitution, and how they use it. We draw on Tall and Vinner’s (1981) ideas of concept definition and concept image to explore students’ meanings of substitution through their personal definitions of substitution, what they identify as substitution, and how they perform substitution. In this presentation, we report on elementary algebra students’ responses to questions about substitution. Data comes includes written responses to multiple-choice and open-ended questions and transcripts from clinical interviews across multiple semesters at a community college. Through a combination of thematic and conceptual analysis, we categorized students’ thinking about substitution and what features appeared to impact how they enact it. We found that students often identify substitution as a process of replacement of one mathematical object for another but differ in the generality of the mathematical objects that they consider (e.g., strictly as the replacement of a number for a variable versus replacement of any expression for another expression). Students further differed in whether or not they thought that substitution entailed equivalence of the objects being replaced. When performing substitution (e.g., substituting x+1 for y in 2y^2), we found that students’ activity was heavily based on their understanding of the structure of the expression where the substitution is taking place (the unified ‘pieces’ of 2y^2). In addition to other findings, we elaborate on the mental processes that students engage in when performing substitution and synthesize our findings with the notion of substitution equivalence (Wladis et al., 2020).
Wladis, C.; Offenholley, K.; Sencindiver, B.
(, Proceedings of the 44th Conference of the International Group for the Psychology of Mathematics Education)
In mathematics education, much research has focused on studying how students think about the equals sign, but equality is just one example of the larger concept of equivalence, which occurs extensively throughout the K-16 mathematics curriculum. Yet research on how students think about broader notions of equivalence is limited. We present a model of students’ thinking that is informed by Sfard’s theories of the Genesis of Mathematical Objects, in which she distinguishes between operational versus structural thinking (e.g., 1995), which we conceptualize as a continuum rather than a binary categorization. Sfard also describes a pseudostructural conception, in which the objects that a student conceptualizes are not the reification of a process. We combine Sfard’s theory with a categorization of the source of students’ definitions, where stipulated definitions are given a priori and can be explicitly consulted when determining whether something fits the definitions, while extracted definitions are constructed from repeated observation of usage (Edwards & Ward, 2004). We combine these theories with inductive coding of data (open-ended questions, multiple-choice questions, and cognitive interviews) collected from thousands of students enrolled in a range of mathematics classes in college in the US, to generate categories of students’ thinking around equivalence. We see this model as a tool for analysing students’ work to better understand how students conceptualize equivalence. With this model we hope to begin a conversation about how students tend to conceptualize equivalence at various levels, as well as the ways in which equivalence is or is not explicitly addressed currently in curricula and instruction, and what consequences this might have for students’ conceptions of equivalence.
Wladis, C.; Sencindiver, B.; Offenholley, K.; Jaffe, E.; & Taton, J.
(, Proceedings for the 12th Congress of the European Society for Research in Mathematics Education (CERME12))
Cho, Sung Je
(Ed.)
In this study, we describe a model of student thinking around equivalence (conceptualized as any type of equivalence relation), presenting vignettes from student conceptions from various college courses ranging from developmental to linear algebra. In this model, we conceptualize student definitions along a continuous plane with two-dimensions: the extent to which definitions are extracted vs. stipulated; and the extent to which conceptions of equivalence are operational or structural. We present examples to illustrate how this model may help us to recognize ill-defined or operational thinking on the part of students even when they appear to be able to provide “standard” definitions of equivalence, as well as to highlight cases in which students are providing mathematically valid, if non-standard, definitions of equivalence. We hope that this framework will serve as a useful tool for analyzing student work and exploring instructional and curricular handling of equivalence.
Wladis, C., Sencindiver, B., and Offenholley, K. Reconceptualizing Algebraic Transformation as a Process of Substitution Equivalence. Retrieved from https://par.nsf.gov/biblio/10481790. Proceedings for the 25th Annual Conference on Research in Undergraduate Mathematics Education .
Wladis, C., Sencindiver, B., & Offenholley, K. Reconceptualizing Algebraic Transformation as a Process of Substitution Equivalence. Proceedings for the 25th Annual Conference on Research in Undergraduate Mathematics Education, (). Retrieved from https://par.nsf.gov/biblio/10481790.
Wladis, C., Sencindiver, B., and Offenholley, K.
"Reconceptualizing Algebraic Transformation as a Process of Substitution Equivalence". Proceedings for the 25th Annual Conference on Research in Undergraduate Mathematics Education (). Country unknown/Code not available: RUME, http://sigmaa.maa.org/rume/Site/Proceedings.html. https://par.nsf.gov/biblio/10481790.
@article{osti_10481790,
place = {Country unknown/Code not available},
title = {Reconceptualizing Algebraic Transformation as a Process of Substitution Equivalence},
url = {https://par.nsf.gov/biblio/10481790},
abstractNote = {In this theoretical paper, we describe how algebraic transformation could be reconceptualized as a process of substitution equivalence, and we discuss how this conceptualization affords mathematical justification of transformation processes. In particular, we describe a model which deconstructs the process of substitution equivalence into core subdomains which could be learned serially and then re-integrated, in order to make them accessible to students with lower prior knowledge in syntactic reasoning. Our aim in presenting this model is to start a conversation about what the core components of knowledge might be in order for students to reason about and justify algebraic transformation using symbolic representations.},
journal = {Proceedings for the 25th Annual Conference on Research in Undergraduate Mathematics Education},
publisher = {RUME, http://sigmaa.maa.org/rume/Site/Proceedings.html},
author = {Wladis, C. and Sencindiver, B. and Offenholley, K.},
editor = {Cook, S. and Infante, N.}
}
Warning: Leaving National Science Foundation Website
You are now leaving the National Science Foundation website to go to a non-government website.
Website:
NSF takes no responsibility for and exercises no control over the views expressed or the accuracy of
the information contained on this site. Also be aware that NSF's privacy policy does not apply to this site.