Fostering empirical examination after proof construction in secondary school geometry

In contrast to existing research that has typically addressed the process from example generation to proof construction, this study aims at enhancing empirical examination after proof construction leading to revision of statements and proofs in secondary school geometry. The term "empirical exa...

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Veröffentlicht in:	Educational studies in mathematics 2017-10, Vol.96 (2), p.129-144
1. Verfasser:	Komatsu, Kotaro
Format:	Artikel
Sprache:	eng
Schlagworte:	Construction Education Empirical analysis Geometry Grade 8 Grade 9 Intervention Mathematical analysis Mathematical Logic Mathematics Mathematics Education Mathematics Instruction Mathematics Teachers Methods Proof (Mathematics) Secondary School Mathematics Secondary School Students Secondary School Teachers Students Study and teaching Teachers Validity
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container_title	Educational studies in mathematics
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description	In contrast to existing research that has typically addressed the process from example generation to proof construction, this study aims at enhancing empirical examination after proof construction leading to revision of statements and proofs in secondary school geometry. The term "empirical examination" refers to the use of examples or diagrams to investigate whether a statement is true or a proof is valid. Although empirical examination after proof construction is significant in school mathematics in terms of cultivating students' critical thinking and achieving authentic mathematical practice, how this activity can be fostered remains unclear. This paper shows the strength of a particular kind of mathematical task, proof problems with diagrams, and teachers' roles in implementing the tasks, by analysing two classroom-based interventions with students in the eighth and ninth grades. In the interventions, the tasks and the teachers' actions successfully prompted the students to discover a case rejecting a proof and a case refuting a statement, modify the proof, properly restrict the domain of the statement by disclosing its hidden condition, and invent a more general statement that was true even for the refutation of the original statement.
doi_str_mv	10.1007/s10649-016-9731-6
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subjects	Construction Education Empirical analysis Geometry Grade 8 Grade 9 Intervention Mathematical analysis Mathematical Logic Mathematics Mathematics Education Mathematics Instruction Mathematics Teachers Methods Proof (Mathematics) Secondary School Mathematics Secondary School Students Secondary School Teachers Students Study and teaching Teachers Validity
title	Fostering empirical examination after proof construction in secondary school geometry
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