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Implementing the connected mathematics project the interaction between student rational number understanding and classroom mathematical practices /Bledsoe, Ann M. January 2002 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 2002. / Typescript. Vita. Includes bibliographical references (leaves 335-348). Also available on the Internet.
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Implementing the connected mathematics project : the interaction between student rational number understanding and classroom mathematical practices /Bledsoe, Ann M. January 2002 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 2002. / Typescript. Vita. Includes bibliographical references (leaves 335-348). Also available on the Internet.
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Elementary students' use of relationships and physical models to understand order and equivalence of rational numbersWenrick, Melanie Renee 28 August 2008 (has links)
Not available / text
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Explicit class field theory for rational function fields /Rakotoniaina, Tahina. January 2008 (has links)
Thesis (MSc)--University of Stellenbosch, 2008. / Bibliography. Also available via the Internet.
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The initial grounding of rational numbers : an investigationBrown, Bruce John Lindsay January 2007 (has links)
This small scale exploratory research project investigated the grounding of rational number concepts in informal, everyday life situations. A qualitative approach was taken to allow for the identification and then in depth investigation, of issues of importance for such a grounding of rational number understanding. The methodology followed could be seen as a combination of grounded theory and developmental research. And the data was generated through in-depth and clinical interviews structured around a number of grounded tasks related to rational numbers. The research comprised three cycles of interviews that were transcribed and then analysed in detail, interspersed with periods of reading and reflection. The pilot cycle involved a single grade three teacher, the second cycle involved 2 grade three teachers and the third cycle involved 2 grade three children. The research identified a number of different perspectives that were all important for the development of a fundamental intuitive understanding that could be considered personally meaningful to the individual concerned and relevant to the development of rational number concepts. Firstly in order to motivate and engage the child on a personal level the grounding situation needed to be seen as personally significant by the child. Secondly, coordinating operations provided a means of developing a fundamental intuitive understanding, through coordination with affording structures of the situation that are relevant to rational numbers. Finally, goal directed actions that are deliberately structured to achieve explicit goals in a situation are important for the development of more explicit concepts and skills fundamental for rational number understanding. Different explicit structures give rise to different interpretations of rational numbers in grounding situations. In addition to these perspectives, it became evident that building and learning representations was important for developing a more particularly mathematical understanding, based on the fundamental understanding derived from the child's grounded experience. The conclusion drawn in this research as a result of this complexity, is that to achieve a comprehensive and meaningful grounding, children's learning of rational numbers will not follow a simple linear trajectory. Rather this process forms a web of learning, threading coordinating operations for intuitive development, interpretations for explicit grounding and representations to develop more formal mathematical conceptions.
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Recharging Rational Number UnderstandingSchiller, Lauren Kelly January 2020 (has links)
In 1978, only 24% of 8th grade students in the United States correctly answered whether 12/13+7/8 was closest to 1, 2, 19, or 21 (Carpenter, Corbitt, Kepner, Lindquist, & Reys, 1980). In 2014, only 27% of 8th grade students selected the correct answer to the same problem, despite the ensuing forty years of effort to improve students’ conceptual understanding (Lortie-Forgues, Tian, & Siegler, 2015). This is troubling, given that 5th grade students’ fraction knowledge predicts mathematics achievement in secondary school (Siegler et al, 2012) and that achievement in math is linked to greater life outcomes (Murnane, Willett, & Levy, 1995). General rational number knowledge (fractions, decimals, percentages) has proven problematic for both children and adults in the U.S. (Siegler & Lortie-Forgues, 2017). Though there is debate about which type of rational number instruction should occur first, it seems it would be beneficial to use an integrated approach to numerical development consisting of all rational numbers (Siegler, Thompson, & Schneider, 2011). Despite numerous studies on specific types of rational numbers, there is limited information about how students translate one rational number notation to another (Tian & Siegler, 2018).
The present study seeks to investigate middle school students’ understanding of the relations among fraction, decimal, and percent notations and the influence of a daily, brief numerical magnitude translation intervention on fraction arithmetic estimation. Specifically, it explores the benefits of Simultaneous presentation of fraction, decimal, and percent equivalencies on number lines versus Sequential presentation of fractions, decimals, and percentages on number lines. It further explores whether rational number review using either Simultaneous or Sequential representation of numerical magnitude is more beneficial for improving fraction arithmetic estimation than Rote practice with fraction arithmetic. Finally, it seeks to make a scholarly contribution to the field in an attempt to understand students’ conceptions of the relations among fractions, decimals, and percentages as predictors of estimation ability.
Chapter 1 outlines the background that motivates this dissertation and the theories of numerical development that provide the framework for this dissertation. In particular, many middle school students exhibit difficulties connecting magnitude and space with rational numbers, resulting in implausible errors (e.g., 12/13+7/8=1, 19, or 21, 87% of 10>10, 6+0.32=0.38). An integrated approach to numerical development suggests students’ difficulty in rational number understanding stems from how students incorporate rational numbers into their numerical development (Siegler, Thompson, & Schneider, 2011). In this view, students must make accommodations in their whole number schemes when encountering fractions, such that they appropriately incorporate fractions into their mental number line. Thus, Chapter 1 highlights number line interventions that have proven helpful for improving understanding of fractions, decimals, and percentages.
In Chapter 2, I hypothesize that current instructional practices leave middle school students with limited understanding of the relations among rational numbers and promote impulsive calculation, the act of taking action with digits without considering the magnitudes before or after calculation. Students who impulsively calculate are more likely to render implausible answers on problems such as estimating 12/13+7/8 as they do not think about the magnitudes (12/13 is about equal to one and 7/8 is about equal to one) before deciding on a calculation strategy, and they do not stop to judge the reasonableness of an answer relative to an estimate after performing the calculation. I hypothesize that impulsive calculation likely stems from separate, sequential instructional approaches that do not provide students with the appropriate desirable difficulties (Bjork & Bjork, 2011) to solidify their understanding of individual notations and their relations.
Additionally, in Chapter 2, I hypothesize that many middle school students are unable to view equivalent rational numbers as being equivalent. This hypothesis is based on the documented tendency of many students to focus on the operational rather than relational view of equivalence (McNeil et al., 2006). In other words, students typically focus on the equal sign as signal to perform an operation and provide an answer (e.g., 3+4=7) rather than the equal sign as a relational indicator (e.g., 3+4=2+5). Moreover, this hypothesis is based on the documented whole number bias exhibited by over a quarter of students in 8th grade, such that students perceived equivalent fractions with larger parts as larger than those with smaller parts (Braithwaite & Siegler, 2018b). If middle school students are unable to perceive equivalent values within the same notation as equivalent in size, it seems probable that they might also struggle perceiving equivalent rational numbers as equivalent across notations. This is especially true in light of evidence that many teachers often do not use equal signs to describe equivalent values expressed as fractions, decimals, and percentages (Muzheve & Capraro, 2012). Chapter 2 underscores the importance of highlighting the connections among notations by discussing the pivotal role of notation connections in prior research (Moss & Case, 1999) and the benefit of interleaved practice in math (Rohrer & Taylor, 2007). Finally, I propose a plan for improving students’ understanding of rational numbers through linking notations with number line instruction, as an integrated theory of numerical development (Siegler et al, 2011) suggests that all rational numbers are incorporated into one’s mental number line.
Chapter 3 details two experiments that yielded empirical evidence consistent with the hypotheses that students do not perceive equivalent rational numbers as equivalent in size and that this lack of integrated number sense influences estimation ability. The findings identify a discrepancy in performance in magnitude comparison across different rational number notations, in which students were more accurate when presented with problems where percentages were larger than fractions and decimals than when they were presented with problems where percentages were smaller than fractions and decimals. Superficially, this finding of a percentages-are-larger bias suggests students have a bias towards perceiving percentages as larger than fractions and decimals; however, it appears this interpretation is not true on all tasks. If students always perceive percentages as larger than fractions and decimals, then their placement of percentages on the number line should be larger than the equivalent fractions or decimals. However, this was not the case. The experiments revealed that students’ number line estimation was most accurate for percentages rather than the equivalent fraction and decimal values, demonstrating that students who are influenced by the percentages-are-larger bias are most likely not integrating understanding of fractions, decimals, and percentages on a single mental number line. Furthermore, empirical evidence provided support for the theory of impulsive calculation defined earlier, such that many students perform worse when presented with distracting information (“lures”) meant to elicit the use of flawed calculation strategies than in situations without such lures. Importantly, integrated number sense, as measured by the composite score of all cross-notation magnitude comparison trials, was shown to be an important predictor of estimation ability in the presence of distracting information on number lines and fraction arithmetic estimation tasks, often above and beyond number line estimation ability and general math ability.
The experiments reported in Chapter 3 also evaluated whether Simultaneous, integrated instruction of all notations improved integration of rational number notations more than Sequential instruction of the three notations or a control condition with Rote practice in fraction arithmetic. The experiments also evaluated whether the instructional condition influenced fraction arithmetic estimation ability. The findings supported the hypothesis that a Simultaneous approach to reviewing rational numbers provides greater benefit for improving integrated number sense, as measured by more improvement in the composite score of magnitude comparison across notations. However, there was no difference among conditions in fraction arithmetic estimation ability at posttest. The experiments point to potential areas for improvement in future work, which are described subsequently.
Chapter 4 attempts to explore further students’ understanding of the relations among notations. For this analysis, a number of data sources were examined, including student performance on assessments, interview data, analysis of student work, and classroom observations. Three themes emerged: (1) students are employing a flawed translation strategy, where students concatenate digits from the numerator and denominator to translate the fraction to a decimal such that a/b=0.ab (e.g., 3/5=0.35). (2) percentages can serve as a useful tool for students to judge magnitude, and (3) students equate math with calculation rather than estimation (e.g., in response to being asked to estimate addition of fractions answers, a student responded, “I can’t do math, right?”). Moreover, case studies investigated the differential effect of condition (Simultaneous, Sequential, or Control) on students’ strategy use. The findings suggest that the Simultaneous approach facilitated a more developed schema for magnitude, which is crucial given that a student’s degree of mathematical understanding is determined by the strength and accuracy of connections among related concepts (Hiebert & Carpenter, 1992).
Chapter 5 concludes the dissertation by discussing the contributions of this work, avenues for future research, and educational implications. Ultimately, this dissertation advances the field of numerical cognition in three important ways: (1) by documenting a newly discovered bias of middle school students perceiving percentages as larger than fractions and decimals in magnitude comparisons across notations and positing that a lack of integrating notations on the same mental number line is a likely mechanism for this bias; (2) by demonstrating that students exhibit impulsive calculation, as measured by the difference in performance between situations where students are presented with distracting information (“lures”) meant to elicit the use of flawed calculation strategies and situations that do not involve lures; and (3) by finding that integrated number sense, as measured by the composite score for magnitude comparison across notations, is a unique predictor of estimation ability, often above and beyond general mathematical ability and number line estimation. In particular, students with higher integrated number sense are more than twice as likely to correctly answer the aforementioned 12/13+7/8 estimation problem than their peers with the same number line estimation ability and general math ability. This finding suggests that integrated number sense is an important inhibitor for impulsive calculation, above estimation ability for individual fractions and a general standardized test of math achievement. Finally, this dissertation advances the field of mathematics education by suggesting instruction that connects equivalent values with varied notations might provide superior benefits over a sequential approach to teaching rational numbers. At a minimum, this dissertation suggests that more careful attention must be paid to relating rational number notations. Future work might examine the origins of impulsive calculation and the observed percentages-are-larger bias. Future research might also examine whether integrated number sense is predictive of estimation ability beyond general number sense within notations. From these investigations, it might be possible to design a more impactful intervention to improve rational number outcomes.
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The role of unit concept in rational number multiplication and division.January 2004 (has links)
Yeung Pui Lam. / Thesis submitted in: December 2003. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2004. / Includes bibliographical references (leaves 99-102). / Abstracts in English and Chinese. / Table of Content --- p.i / List of Tables --- p.iv / List of Figures --- p.v / Abstract --- p.vi / Chapter Chapter 1 --- INTRODUCTION / Research Background --- p.1 / Purpose and Significance of Study --- p.6 / Organization of the Thesis --- p.8 / Chapter Chapter 2 --- CONCEPTS OF UNIT / Introduction --- p.10 / Concepts of Unit as Key Concepts for Transforming Learning from Whole Numbers to Rational Numbers --- p.11 / Development of Unit Concepts across Additive and Multiplication Conceptual Fields --- p.11 / Six Aspects of Unit Concepts --- p.15 / Formation of Units in Rational Number Situation by Partitioning --- p.19 / Formation of Singleton and Composition Unit --- p.22 / A Flexible Concept of Measurement Unit --- p.23 / Decomposition and Composition of Unit --- p.23 / Reconstructing the Unit Whole --- p.24 / Fraction Equivalence --- p.24 / Chapter Chapter 3 --- SITUATIONS OF MULTIPLICATION AND DIVISION / Introduction --- p.26 / Semantics of Rational Numbers --- p.27 / Part-whole Subconstruct / Part-whole Comparison --- p.27 / Quotient --- p.28 / Operators --- p.31 / Measures --- p.32 / Ratio --- p.32 / Structures of Multiplication and Division --- p.34 / Vergnaud's Interpretation on Multiplicative Structures- --- p.35 / Isomorphism of measures --- p.35 / Product of measures --- p.38 / Multiple Proportion --- p.39 / Greer's Classification on Multiplication/Division Situations --- p.40 / Relationship between Unit Concepts and Rational Number Multiplication and Division --- p.46 / The Role of Unit in the Scope of Rational Numberśؤ --- p.46 / Children's Implicit Model of Fraction Multiplication / Division --- p.47 / The Role of Unit in Multiplication/Division Situation --- p.49 / Research Question --- p.54 / Influence of Concepts of Unit in Students' Solving Rational Number Multiplication and Division --- p.55 / The Development of Unit Concepts in the Course of Learning --- p.57 / Chapter Chapter 4 --- METHODOLOGY / Design --- p.58 / Participants --- p.58 / Instruments --- p.59 / Unit concept test --- p.60 / Fraction multiplication and division test --- p.61 / Procedures --- p.62 / Research Hypothesis --- p.63 / Chapter Chapter 5 --- RESULTS / Dimensions of the Unit Concepts --- p.67 / Relationship between Various Concepts of Unit and Fraction multiplication and division Performance --- p.68 / Relationship between unit concepts and rational number multiplication and division situational problem --- p.69 / Differentiated relationship between unit concepts and situational vs. symbolic rational number multiplication and division --- p.71 / Relationship between unit concepts and types of situational rational number multiplication and division- --- p.73 / Relationship between Grade Level and Performance on Measures of Unit Concepts and Rational Number Multiplication and Division --- p.83 / Chapter Chapter 6 --- DISCUSSION / Summary of Findings --- p.87 / Importance of Concepts of Unit --- p.88 / Dimension of concepts of unit --- p.88 / Relationship between concepts of unit and situational problems --- p.89 / Differentiated impacts of concepts of unit on situational problems and symbolic problems --- p.90 / Differentiated impacts of concepts of unit between multiplication and division problems --- p.91 / Implications of the Findings for Development of Concepts of Unit and Mathematics Learning --- p.92 / Research Implication --- p.92 / Instructional Implication --- p.93 / Limitations in the Study --- p.94 / Directions for Future Research --- p.96 / Conclusion --- p.97 / References --- p.99 / Appendices / Appendix 1: The questionnaire used in present study --- p.104 / Appendix 2: The characteristics of items in Questionnaire I- --- p.115 / Appendix 3: The characteristics of situational problems of fraction multiplication and divisionin questionnaire II --- p.116 / Appendix 4: The CFA model of concepts of unit --- p.117 / Appendix 5: Sample cases for illustrating strategiesin solving situational problems --- p.118
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Explicit class field theory for rational function fieldsRakotoniaina, Tahina 12 1900 (has links)
Thesis (MSc (Mathematical Sciences))--Stellenbosch University, 2008. / Class field theory describes the abelian extensions of a given field K in terms of various
class groups of K, and can be viewed as one of the great successes of 20th century
number theory. However, the main results in class field theory are pure existence
results, and do not give explicit constructions of these abelian extensions. Such
explicit constructions are possible for a variety of special cases, such as for the field Q
of rational numbers, or for quadratic imaginary fields. When K is a global function
field, however, there is a completely explicit description of the abelian extensions of
K, utilising the theory of sign-normalised Drinfeld modules of rank one. In this thesis
we give detailed survey of explicit class field theory for rational function fields over
finite fields, and of the fundamental results needed to master this topic.
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Ensino dos números racionais comparando medidas de unidade / Teaching of rational numbers comparing unit measureKrug, Carbone Bruno Schmidt 21 May 2015 (has links)
CAPES / A presente pesquisa teve como objetivo investigar a possibilidade de desenvolver o processo de ensino e aprendizagem da divisão de números racionais com tarefas pautadas na interpretação da medida. Adotamos como metodologia a Engenharia Didática e elaboramos uma sequência didática a fim de desenvolver o trabalho com estudantes do Ensino Médio. Participaram das sessões de ensino doze estudantes de uma escola estadual do município de Porto Barreiro - Pr. Os resultados da aplicação da sequência didática sugerem a importância da utilização de atividades pautadas na interpretação da medida, haja vista que potencializou o entendimento, por parte dos estudantes, do conceito de divisão de números racionais fracionários e contribuiu para eles aprofundarem a compreensão de outras questões relacionadas ao conceito de número racional, tais como ordem, equivalência e densidade. / This research aimed to investigate the possibility to develop the process of teaching and learning of the division of rational numbers with guided tasks in interpretation of measure. Adopted as methodology the Didactic Engineering and a didactic sequence in order to develop the work with students of High School. Participated of training sessions twelve students of one state school of Porto Barreiro city - Paran´a. The results of application of the didactic engineering suggest the importance of utilization of guided tasks in interpretation of measure, since strengthened the understanding, on the part of students, the concept of division of fractional rational numbers and contributed for them develop the comprehension of others questions associated to the concept of rational numbers, such as order, equivalence and density.
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