Overview of technologies for building robots in the classroom

This paper aims to give an overview of technologies that can be used to implement robotics within an educational context. We discuss complete robotics systems as well as projects that implement only certain elements of a robotics system, such as electronics, hardware, or software. We believe that Maker Movement and DIY trends offers many new opportunities for teaching and feel that they will become much more prominent in the future. Products and projects discussed in this paper are: Mindstorms, Vex, Arduino, Dwengo, Raspberry Pi, MakeBlock, OpenBeam, BitBeam, Scratch, Blockly and ArduBlock

Mobile Robotics

The book is a collection of ten scholarly articles and reports of experiences and perceptions concerning pedagogical practices with mobile robotics.“This work is funded by CIEd – Research Centre on Education, project UID/CED/01661/2019, Institute of Education, University of Minho, through national funds of FCT/MCTES-PT.

Strategies for Digital Creative Pedagogies in Today’s Education

Creativity and digital technologies are considered to be central for success and development in the current society, becoming crucial educational objectives worldwide. Nevertheless, education often fails to keep pace with creative and digital economies; this is mainly because teachers are not prepared for adopting pedagogical strategies that foster creativity or for fully exploiting the educational potential of digital technologies. Based on the seminal theories of creativity, we propose an innovative framework for applying creative teaching practices mediated by digital technologies: in the light of constructivist and constructionist approaches, we suggest a series of digital tools which are particularly suitable to the emergence of creativity, i.e. manipulative technologies, educational robotics and game design and coding. Furthermore, we shape the concept of digital creative pedagogies (DCP) and establish a set of characteristic components of teaching practices which contribute to the development of students’ creativity. Drawing on a substantial body of research, the chapter intends to embed educational creativity in the digital culture

A Comparison of Platform Configurations for Robotics Development within ROS2, Raspberry Pi, andWebots

Background: The field of robotics continues to expand with new, progressive technologies. The vast ecosystem of robotics, with its countless routes, is initially challenging to navigate. It is even more so during a season of virtual instruction. Creating strategic entrance points for the incoming students merits consideration. Purpose: Our aim is to provide a way for students to explore three critical areas in robotics: the physical robot (hardware), the simulated robot (digital twin), and the operating system and code (controller). Method: We explore options for integrating two advanced robot development frameworks (i.e. Robot Operating System 2 (ROS2) and Webots) in combination with the widely used beginners computing platform (i.e. Raspberry Pi) to facilitate introducing students to the field of robotics, while also providing them a path to advanced robot topics. Results: Two configurations for integrating ROS2, Webots, and the Raspberry Pi are presented. The advantages and concerns for each are discussed, along with pointers for mitigating concerns. Conclusion: The integration of these frameworks and platform, along with virtualizing the physical robot as a digital twin, opens a gateway for students to enter the field of robotics. We also envision our ideas supporting paths for improving online distance learning, developing robot networks, and reducing field testing time

Makers at School, Educational Robotics and Innovative Learning Environments

This open access book contains observations, outlines, and analyses of educational robotics methodologies and activities, and developments in the field of educational robotics emerging from the findings presented at FabLearn Italy 2019, the international conference that brought together researchers, teachers, educators and practitioners to discuss the principles of Making and educational robotics in formal, non-formal and informal education. The editors’ analysis of these extended versions of papers presented at FabLearn Italy 2019 highlight the latest findings on learning models based on Making and educational robotics. The authors investigate how innovative educational tools and methodologies can support a novel, more effective and more inclusive learner-centered approach to education. The following key topics are the focus of discussion: Makerspaces and Fab Labs in schools, a maker approach to teaching and learning; laboratory teaching and the maker approach, models, methods and instruments; curricular and non-curricular robotics in formal, non-formal and informal education; social and assistive robotics in education; the effect of innovative spaces and learning environments on the innovation of teaching, good practices and pilot projects

Futures of Work: Perspectives from the Maker Movement

The work presented in this report attempts to explore other realms about the future(s) of work beyond the strongly driven narrative of digital transformation. We have addressed one particular grassroots community, the Maker Movement, which is de facto enabling new models of education, collaborative work, and manufacture. Movements like the Maker Movement can be inspirational of policy making in areas of great complexity and uncertainties as work, employment, jobs are. We suggest that debates about futures of work need to mobilise the imagination, insights and expectations of wide ranges of society. Policy making should be nurturing necessary studies, experiments and conversations until some resilient ideas are found.JRC.I.2-Foresight, Behavioural Insights and Design for Polic

The Tech Café, A Social Action Makerspace: Middle school students as change agents

Makerspaces are fertile grounds for students to develop innovative products infused with STEAM principles and cross disciplinary content knowledge; build technological fluency; and support positive developmental growth. Yet, rarely do Makerspaces prioritize these outcomes. Rather, they tend to revolve around the creation of novel objects using cutting-edge technology; craftwork unhinged from their historical, social, political, or academically-relevant underpinnings; and/or the hacking of so-called “black boxes”. What happens when an educator designs and implements a research-based and content-driven in-school Makerspace? Drawing on field observations, interviews, artifact analysis, and the Developmental Assets Profile (DAP) survey, this mixed methods study explored the experiences of students from two urban middle school classes (n=51) who participated in a social action themed Makerspace called the “Tech Café.” Working from a transformative research perspective, the Tech Café also sought to address the “participation divide”— a term suggesting that higher socioeconomic status students have more opportunity to produce media creatively than students of low socioeconomic status. Qualitative results indicated that students reported increased agency in their ability to effect positive change in their world. They engaged in powerful collaborations with diverse members of the school’s learning community as they worked toward solutions using low- and high-technology tools. Their products included a cigarette smoke detecting shirt, an edible insect bug stand, and a stationary making kit utilizing recycled paper. Student profiles incorporated their chosen social issue; steps and challenges in product creation; and outcomes pertaining to technological fluency and sense of agency to affect change. Findings showed that students may have benefited from scaffolding to deepen their understanding of important social issues through research. Quantitative results of the DAP were statistically analyzed according to measures of Positive Identity, Positive Values, Commitment to Learning, Empowerment, and Social Competencies and indicated that no statistically significant differences existed in the pretest-posttest survey scores of participants (n=30). However, a descriptive analysis of score improvement showed that students who successfully created products in the Tech Café moved to higher DAP score ranges more often than those who did not create products. The study concludes with recommendations pertaining to the implementation of Makerspaces in schools

Makers at School, Educational Robotics and Innovative Learning Environments

This open access book contains observations, outlines, and analyses of educational robotics methodologies and activities, and developments in the field of educational robotics emerging from the findings presented at FabLearn Italy 2019, the international conference that brought together researchers, teachers, educators and practitioners to discuss the principles of Making and educational robotics in formal, non-formal and informal education. The editors’ analysis of these extended versions of papers presented at FabLearn Italy 2019 highlight the latest findings on learning models based on Making and educational robotics. The authors investigate how innovative educational tools and methodologies can support a novel, more effective and more inclusive learner-centered approach to education. The following key topics are the focus of discussion: Makerspaces and Fab Labs in schools, a maker approach to teaching and learning; laboratory teaching and the maker approach, models, methods and instruments; curricular and non-curricular robotics in formal, non-formal and informal education; social and assistive robotics in education; the effect of innovative spaces and learning environments on the innovation of teaching, good practices and pilot projects

The Impact of Collaboration, Problem Solving, and Creativity on Computer Programming Education for Middle School Girls

Despite high scores and abilities, girls lose interest in science and math throughout middle school. According to the Bureau of Labor Statistics, jobs in the computer science research field will grow 19% by 2026; however, only 18% of the bachelor’s degrees in computer science are earned by women in the United States (ComputerScience.org, 2021). New technology and inventions are being created without the benefit of more diverse perspectives and input from females. There is a need to engage girls and maintain their interest throughout middle school and beyond. Additional research needs to be conducted about the impact and best practices used during out-of-school time programs to encourage and motivate girls to stay engaged in STEM, including computer programming (Koch, 2014). This study investigated the relationship between middle school girls’ interest in computer programming and the opportunities to collaborate, solve problems, and use their creativity while participating in computer programming activities led by female role models during the 4-H Girls Tech Challenge, an informal education program. Research questions are the following: 1) In what ways did the 4-H Girls Tech Challenge experience, which included components of problem solving, collaboration, creativity and female role models, affect the attitudes of middle school girls towards computer programming? 2) To what extent did the 4-H Girls Tech Challenge experience affect the attitude of middle school girls towards potentially pursuing careers related to computer science and technology? Evidenced by other studies, experiences in which collaboration, problem solving, and creativity are present have been shown to increase knowledge about computer programming and engagement in STEM (Cooper & Heaverlo, 2013; Wu-Rorrer, 2019; Hayden et al., 2011). A qualitative study employing interviews with previous participants was utilized to determine how the components of collaboration, problem solving, and creativity of the 4-H Girls Tech Challenge affected the attitudes of middle school girls towards computer programming and careers in computer science. Educators will benefit from learning more about best practices that engage, motivate, and retain more girls in STEM. An increase in the number of women in the STEM workforce will maximize innovation, creativity, and competitiveness (Hill et al., 2010)