STEM education in the primary years to support mathematical thinking : using coding to identify mathematical structures and patterns

Cross-curricula opportunities afforded by STEM education (Science, Technology, Engineering and Mathematics education), supports an environment where students can develop twenty-first century competencies. One approach to addressing cross-curricula opportunities in STEM education is the introduction...

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Published in	ZDM Vol. 51; no. 6; pp. 915 - 927
Main Author	Miller, Jodie
Format	Journal Article
Language	English
Published	Berlin/Heidelberg Springer Berlin Heidelberg 01.11.2019 Springer Springer Nature B.V
Subjects	21st century 21st Century Skills Algebra Algorithms Coding Computer programming Computer Science Education Computer Software Core curriculum Critical thinking Curricula Data collection Digital technology Education Education policy Educational Change Educational technology Elementary School Students Generalization Generic skills Interdisciplinary Approach International Education Intervention Knowledge Learning Learning Activities Learning Processes Mathematical analysis Mathematical Concepts Mathematical thinking Mathematics Mathematics Education Mathematics skills Mathematics teaching Original Article Patterns (Mathematics) Pretests Posttests Primary education Primary school mathematics Primary school students Problem solving Programming Science education Skills STEM Education Students Teacher Characteristics Teaching Teaching Methods Technical education Technology education Thinking Skills Video Technology Australia Patterning Coding Mathematical thinking Primary
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ISSN	1863-9690 1863-9704
DOI	10.1007/s11858-019-01096-y

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Abstract	Cross-curricula opportunities afforded by STEM education (Science, Technology, Engineering and Mathematics education), supports an environment where students can develop twenty-first century competencies. One approach to addressing cross-curricula opportunities in STEM education is the introduction of computer science (computer programming-coding) as a basic skill/literacy for all students. Coding (computer programming) is a language that draws on a set of syntax rules (or blocks for primary school students) that informs a computer program to execute a series of functions. While there is evidence that computational thinking (the thinking used for coding/computer programming) and conceptual development in mathematics are connected, there is limited research related to how such a confluence applies to primary school students. The aim of this article is to provide insight into how mathematical knowledge and thinking, specifically the identification of mathematical patterns and structures, can be promoted through engagement with coding activities. The data for this article is drawn from year 2 students (n=135) in two Australian primary schools. A teaching experiment approach was adopted for the study with a small intervention group (n=40) undertaking coding lessons for 6 weeks. Data collection comprised of pre-test and post-tests with a focus on patterning and coding in conjunction with video-recorded lessons. The study provides evidence that the learning that takes place through coding instruction can lead to higher levels of students' mathematical thinking in relation to identifying mathematical patterns and structures that can lead to generalisations. [Author abstract]
AbstractList	Cross-curricula opportunities afforded by STEM education (Science, Technology, Engineering and Mathematics education), supports an environment where students can develop twenty-first century competencies. One approach to addressing cross-curricula opportunities in STEM education is the introduction of computer science (computer programming—coding) as a basic skill/literacy for all students. Coding (computer programming) is a language that draws on a set of syntax rules (or blocks for primary school students) that informs a computer program to execute a series of functions. While there is evidence that computational thinking (the thinking used for coding/computer programming) and conceptual development in mathematics are connected, there is limited research related to how such a confluence applies to primary school students. The aim of this article is to provide insight into how mathematical knowledge and thinking, specifically the identification of mathematical patterns and structures, can be promoted through engagement with coding activities. The data for this article is drawn from year 2 students (n = 135) in two Australian primary schools. A teaching experiment approach was adopted for the study with a small intervention group (n = 40) undertaking coding lessons for 6 weeks. Data collection comprised of pre-test and post-tests with a focus on patterning and coding in conjunction with video-recorded lessons. The study provides evidence that the learning that takes place through coding instruction can lead to higher levels of students’ mathematical thinking in relation to identifying mathematical patterns and structures that can lead to generalisations. Cross-curricula opportunities afforded by STEM education (Science, Technology, Engineering and Mathematics education), supports an environment where students can develop twenty-first century competencies. One approach to addressing cross-curricula opportunities in STEM education is the introduction of computer science (computer programming-coding) as a basic skill/literacy for all students. Coding (computer programming) is a language that draws on a set of syntax rules (or blocks for primary school students) that informs a computer program to execute a series of functions. While there is evidence that computational thinking (the thinking used for coding/computer programming) and conceptual development in mathematics are connected, there is limited research related to how such a confluence applies to primary school students. The aim of this article is to provide insight into how mathematical knowledge and thinking, specifically the identification of mathematical patterns and structures, can be promoted through engagement with coding activities. The data for this article is drawn from year 2 students (n=135) in two Australian primary schools. A teaching experiment approach was adopted for the study with a small intervention group (n=40) undertaking coding lessons for 6 weeks. Data collection comprised of pre-test and post-tests with a focus on patterning and coding in conjunction with video-recorded lessons. The study provides evidence that the learning that takes place through coding instruction can lead to higher levels of students' mathematical thinking in relation to identifying mathematical patterns and structures that can lead to generalisations. [Author abstract] Cross-curricula opportunities afforded by STEM education (Science, Technology, Engineering and Mathematics education), supports an environment where students can develop twenty-first century competencies. One approach to addressing cross-curricula opportunities in STEM education is the introduction of computer science (computer programming--coding) as a basic skill/literacy for all students. Coding (computer programming) is a language that draws on a set of syntax rules (or blocks for primary school students) that informs a computer program to execute a series of functions. While there is evidence that computational thinking (the thinking used for coding/computer programming) and conceptual development in mathematics are connected, there is limited research related to how such a confluence applies to primary school students. The aim of this article is to provide insight into how mathematical knowledge and thinking, specifically the identification of mathematical patterns and structures, can be promoted through engagement with coding activities. The data for this article is drawn from year 2 students (n = 135) in two Australian primary schools. A teaching experiment approach was adopted for the study with a small intervention group (n = 40) undertaking coding lessons for 6 weeks. Data collection comprised of pre-test and post-tests with a focus on patterning and coding in conjunction with video-recorded lessons. The study provides evidence that the learning that takes place through coding instruction can lead to higher levels of students' mathematical thinking in relation to identifying mathematical patterns and structures that can lead to generalisations.
Audience	Elementary Education
Author	Jodie Miller
AuthorAffiliation	University of Queensland
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