A Developing Approach to Studying Students’ Learning through Their Mathematical Activity

Simon, Martin; Saldanha, Luis; McClintock, Evan; Akar, Gulseren Karagoz; Watanabe, Tad; Zembat, Ismail

doi:10.1080/07370000903430566

Cited by 75 publications

(52 citation statements)

References 31 publications

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“…Pieces of the necessary knowledge are nevertheless available, and the standards-based reform movement of the last few decades is shifting the norms of teaching away from just delivering the content and towards taking more responsibility for helping all students at least to achieve adequate levels of performance in core subjects The state content standards, as they have been tied to grade levels, can be seen as a first approximation of the order in which students should learn the required content and skills However, the current state standards are more prescriptive than they are descriptive They define the order in which, and the time or grade by which, students should learn specific content and skills as evidenced by satisfactory performance levels But typically state standards have not been deeply rooted in empirical studies of the ways children's thinking and understanding of mathematics actually develop in interaction with instruction 2 Rather they usually have been compromises derived from the disciplinary logic of mathematics itself, experience with the ways mathematics has usually been taught, as reflected in textbooks and teachers' practical wisdom, and lobbying and special pleading on behalf of influential individuals and groups arguing for inclusion of particular topics, or particular ideas about "reform" i. iNTrOduCTiON 3 We favor the view that students are active participants in their learning, bringing to it their own theories or cognitive structures (sometimes called "schemes" or "schemata" in the cognitive science literature) on what they are learning and how it works, and assimilating new experience into those theories if they can, or modifying them to accommodate experiences that do not fit Their theories also may evolve and generalize based on their recognition of and reflection on similarities and connections in their experiences, but just how these learning processes work is an issue that requires further research (Simon et al , 2010) We would not, however, carry this view so far as to say that students cannot be told things by teachers or learn things from books that will modify their learning (or their theories)-that they have to discover everything for themselves A central function of telling and showing in instruction is presumably to help to direct attention to aspects of experience that students' theories can assimilate or accommodate to in constructive ways or "the basics " Absent a strong grounding in research on student learning, and the efficacy of associated instructional responses, state standards tend at best to be lists of mathematics topics and some indication of when they should be taught grade by grade without explicit attention being paid to how those topics relate to each other and whether they offer students opportunities over time to develop a coherent understanding of core mathematical concepts and the nature of mathematical argument The end result has been a structure of standards and loosely associated curricula that has been famously described as being "a mile wide and an inch deep" (Schmidt et al , 1997) Of course some of the problems with current standards could be remedied by being even more mathematical-that is, by considering the structure of the discipline and being much clearer about which concepts are more central or "bigger," and about how they connect to each other in terms of disciplinary priority A focus on what can be derived from what might yield a more coherent ordering of what should be taught And recognizing the logic of that ordering might lead teachers to encourage learning of the central ideas more thoroughly when they are first encountered, so that those ideas don't spread so broadly and ineffectively through large swaths of the curriculum But even with improved logical coherence, it is not necessarily the case that all or even most students will ...…”

Section: Introductionmentioning

confidence: 99%

Learning trajectories in mathematics: A foundation for standards, curriculum, assessment, and instruction

Daro¹,

Mosher²,

Corcoran³

2011

PsycEXTRA Dataset

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Learning Trajectories in Mathematics: A Foundation for Standards, Curriculum, Assessment, and Instruction aims to provide:• A useful introduction to current work and thinking about learning trajectories for mathematics education • An explanation for why we should care about these questions • A strategy for how to think about what is being attempted in the field, casting some light on the varying, and perhaps confusing, ways in which the terms trajectory, progression, learning, teaching, and so on, are being used by the education community.Specifically, the report builds on arguments published elsewhere to offer a working definition of the concept of learning trajectories in mathematics and to reflect on the intellectual status of the concept and its usefulness for policy and practice. It considers the potential of trajectories and progressions for informing the development of more useful assessments and supporting more effective formative assessment practices, for informing the on-going redesign of mathematics content and performance standards, and for supporting teachers' understanding of students' learning in ways that can strengthen their capability for providing adaptive instruction. The authors conclude with a set of recommended next steps for research and development, and for policy. LearnInG TraJeCTOrIeS In MaTHeMaTICSA Foundation for Standards, Curriculum, Assessment, and instructionEstablished in 1985, CPRE unites researchers from seven of the nation's leading research institutions in efforts to improve elementary and secondary education through practical research on policy, finance, school reform, and school governance. CPRE studies alternative approaches to education reform to determine how state and local policies can promote student learning. The Consortium's member institutions are the University of Pennsylvania, Teachers College-Columbia University, Harvard University, Stanford University, the University of Michigan, University of Wisconsin-Madison, and Northwestern University.In March 2006, CPRE launched the Center on Continuous Instructional Improvement (CCII), a center engaged in research and development on tools, processes, and policies intended to promote the continuous improvement of instructional practice. CCII also aspires to be a forum for sharing, discussing, and strengthening the work of leading researchers, developers and practitioners, both in the United States and across the globe.To learn more about CPRE and our research centers, visit the following web sites: Visit our website at http://www.cpre.org or sign up for our e-newsletter, In-Sites, at insites@gse.upenn.edu.Research Reports are issued by CPRE to facilitate the exchange of ideas among policymakers, practitioners, and researchers who share an interest in education policy. The views expressed in the reports are those of individual authors, and not necessarily shared by CPRE or its institutional partners. About the Consortium for PoliCy reseArCh in eduCAtion (CPre)CPre reseArCh rePort series CPRE Research Report # RR-...

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Section: Introductionmentioning

confidence: 99%

Learning trajectories in mathematics: A foundation for standards, curriculum, assessment, and instruction

Daro¹,

Mosher²,

Corcoran³

2011

PsycEXTRA Dataset

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“…If educators assumed that what students learned was the result of the instructional practices of teachers, then it would be unnecessary to assess learning (Wiliam, 2010a); teaching does not cause learning (Simon et al, 2010). In order to assess student learning through inquiry, I will firstly clarify views of learning that align with this pedagogy.…”

Section: Learning In a Mathematics Classroommentioning

confidence: 99%

“…In inquiry, the complex interactions that reflect students participating involve a wide range of characteristics. Simon and his colleagues (Simon et al, 2010) stated that learning occurred in the context of mathematical communication with peers, such as negotiating meanings, or sharing and comparing solutions. In these situations, students are required to justify their thinking when challenged by others, establishing shared mathematical ideas that provide the basis for subsequent work.…”

Section: A Social View Of Learningmentioning

confidence: 99%

“…For constructivists, a problem is a roadblock or problematic, in relation to the solver (Confrey, 1991;Fielding-Wells & Makar, 2008;Koellner, Jacobs & Borko, 2011;Stigler et al, 1996). These roadblocks or perturbations are useful in activating assimilatory schemes that the students have available, becoming an important part of a teaching process (Simon et al, 2010). Often inquiry situations can be engineered by the teacher to evoke misconceptions and to capitalise on any unanticipated problems that arise (Makar, 2008;.…”

Section: The Importance Of Getting Stuckmentioning

confidence: 99%

“…For the mathematics learner in inquiry, classroom peers become the audience as well as problem posers and fellow learners (FieldingWells, 2010). Educational research which strives to understand mathematics conceptual learning does so with the hope of informing teaching practice and pedagogy to support student learning (Simon, 1995;Simon et al, 2010;Steffe, 2003). Although various aspects about learning mathematics in inquiry classrooms has been explored, this has not been considered in relation to classroom elements of assessment and teaching in inquiry settings, even though changes in one element could potentially influence all others.…”

Section: Learning Mathematics In An Inquiry Classroommentioning

confidence: 99%

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Measuring Messy Mathematics: Assessing learning in a mathematical inquiry context

Fry¹

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The pedagogy of inquiry to teach mathematics presents a seemingly messy yet busy classroom, where children are engaged in using purposeful mathematics to collaboratively generate effective and creative solutions to open-ended, ambiguous questions. Problems arise when describing student learning in inquiry settings, when assessment practices are chosen that do not align with or are not designed to capture learning in this context. This study will present an inquiry into mathematics inquiry classrooms, to analyse and interpret the relationships between three classroom elements of assessment, teaching and learning. Distinctive to this study, the researcher was also the classroom teacher which offers the reader close insight into school practices in these classrooms. The researcher aimed to understand if an alignment between these classroom elements could support teaching and learning in inquiry settings. Using design research as a methodology (Cobb et al., 2003), two primary, inquiry classrooms (Years three and six) are presented as three iterative phases of study, each using particular theoretical lenses and analytical tools. In the first phase of study, theoretical analysis of formative assessment practices was based on Dewey's (1891) conception of thinking as a process involving abstraction, comparison and synthesis. Vygotsky's (1978) zone of proximal development was the analytical tool in the second phase of study and was used to analyse how the classroom teacher adjusted her teaching based on feedback she received through formative assessment. The third and final phase looked closer at the mathematical learning revealed through formative assessment using the DNR framework (Harel & Koichu, 2010): a Piagetian-influenced framework. Duckworth's (2006) belief framework was also used to consider an interrelated synthesis of findings from this study, to assist in the development and refinement of assessment practices that align with using the inquiry pedagogy to teaching mathematics.Findings from three phases in this study revealed the inadequacy of summative assessment practices in capturing and describing student learning and thinking, fostered at higher levels through inquiry.In the first phase of study, analysis of assessment completed by students as part of their everyday, classroom curriculum reflected how such assessment only requires students to perform lower-level, reproductive thinking. In contrast, formative assessment opportunities encouraged students through inquiry to conceptualise their mathematical thinking in connected and abstract ways. The second phase of study focused on teaching in one inquiry classroom and characterised the difficulties classroom teachers face as they implement inquiry into their mathematics curriculum. Analysis of inquiry teaching and learning in this phase characterised how the teacher needed to be an engineer: able to interweave student ideas as potentialities, into the scaffolding of particular learning goals.ii Interweaving by the teacher, of students' connections t...

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Social Models of Learning and Assessment

Penuel¹,

Shepard²

2016

The Handbook of Cognition and Assessment

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A Developing Approach to Studying Students’ Learning through Their Mathematical Activity

Cited by 75 publications

References 31 publications

Learning trajectories in mathematics: A foundation for standards, curriculum, assessment, and instruction

Learning trajectories in mathematics: A foundation for standards, curriculum, assessment, and instruction

Measuring Messy Mathematics: Assessing learning in a mathematical inquiry context

Social Models of Learning and Assessment

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