Digital design and fabrication for ICT education: Difference between revisions

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Digital design and fabrication for ICT education most often means assembling a robot from a variety of technologies and the programming it. Some technology, e.g. [http://hyperduino.com/hdrobotics.html HyperDuino],  [http://makerbit.com Makerbit] or [https://www.lego.com/en-us/mindstorms LEGO Mindstorms]are more suitable to combine making and programming while respecting the curriculum, according to Green at al. who created a little taxonomgy that allows classifying use of tools according to educational outcomes. {{quotation|The ''curriculum  domain'' focuses on outcomes that support learners using the tools to understand and demonstrate understanding of content (particularly related to content standardsThe ''making domain'' is strongly focused on outcomes that are craft-centric (i.e., making a product). The ''principles of engineering and coding domain'' focuses on outcomes associated with coding as the curriculum; learning to use the tools is the primary outcome of this domain. The overlapping of the circles combines the outcomes of the different domains.}} (Green et al. 2018)
Digital design and fabrication for ICT education most often means assembling a robot from a variety of technologies and the programming it. Some technology, e.g. [http://hyperduino.com/hdrobotics.html HyperDuino],  [http://makerbit.com Makerbit] or [https://www.lego.com/en-us/mindstorms LEGO Mindstorms]are more suitable to combine making and programming while respecting the curriculum, according to Green at al. who created a little taxonomgy that allows classifying use of tools according to educational outcomes. {{quotation|The ''curriculum  domain'' focuses on outcomes that support learners using the tools to understand and demonstrate understanding of content (particularly related to content standardsThe ''making domain'' is strongly focused on outcomes that are craft-centric (i.e., making a product). The ''principles of engineering and coding domain'' focuses on outcomes associated with coding as the curriculum; learning to use the tools is the primary outcome of this domain. The overlapping of the circles combines the outcomes of the different domains.}} (Green et al. 2018)


Since both Digital design & fabrication and ICT education are most often associated with engineering and since educational robotics has long standing tradition starting in Papert's [[constructionism]], it is natural that making is frequently associated with robotics.
Since both Digital design & fabrication and ICT education are most often associated with engineering and since educational robotics has long standing tradition starting in Papert's [[constructionism]], it is natural that making is frequently associated with robotics. {{quotation|Making spans a myriad of activities, including cooking, sewing, welding, robotics, painting, printing, and building (Peppler and Bender 2013). Making activities often involve programming and physical computing (e.g., robotics) that creates interactive experiences of sensing and controlling the physical world with computers (O’Sullivan and Igoe 2014). ([https://doi.org/10.1007/s11528-017-0172-6 Hsu et al. 2017)]


== Bibliography ==
== Bibliography ==


* Green, T., Wagner, R., & Green, J. (2018). A Look at Robots and Programmable Devices for the K-12 Classroom. TechTrends. https://doi.org/10.1007/s11528-018-0297-2
* Green, T., Wagner, R., & Green, J. (2018). A Look at Robots and Programmable Devices for the K-12 Classroom. TechTrends. https://doi.org/10.1007/s11528-018-0297-2
* Hsu, YC., Baldwin, S. & Ching, YH. Learning through Making and Maker Education, TechTrends (2017) 61: 589. https://doi.org/10.1007/s11528-017-0172-6

Revision as of 11:04, 28 May 2018

Introduction

Digital design and fabrication in education is an emerging discipline, e.g. in the UK under the label "Design and technology". In this page we only focus on the potential of digital design and fabrication to teach and learn ICT skills.

Contents will include citations and summaries that then could be used for further exploration, research and teaching activities. - Daniel K. Schneider (talk) 16:27, 25 May 2018 (CEST)

Green at al. 2018, A Look at Robots and Programmable Devices for the K-12 Classroom

Digital design and fabrication for ICT education most often means assembling a robot from a variety of technologies and the programming it. Some technology, e.g. HyperDuino, Makerbit or LEGO Mindstormsare more suitable to combine making and programming while respecting the curriculum, according to Green at al. who created a little taxonomgy that allows classifying use of tools according to educational outcomes. “The curriculum domain focuses on outcomes that support learners using the tools to understand and demonstrate understanding of content (particularly related to content standardsThe making domain is strongly focused on outcomes that are craft-centric (i.e., making a product). The principles of engineering and coding domain focuses on outcomes associated with coding as the curriculum; learning to use the tools is the primary outcome of this domain. The overlapping of the circles combines the outcomes of the different domains.” (Green et al. 2018)

Since both Digital design & fabrication and ICT education are most often associated with engineering and since educational robotics has long standing tradition starting in Papert's constructionism, it is natural that making is frequently associated with robotics. {{quotation|Making spans a myriad of activities, including cooking, sewing, welding, robotics, painting, printing, and building (Peppler and Bender 2013). Making activities often involve programming and physical computing (e.g., robotics) that creates interactive experiences of sensing and controlling the physical world with computers (O’Sullivan and Igoe 2014). (Hsu et al. 2017)

Bibliography