Selected NSF projects of interest to K-12 engineering and technology education

The National Science Foundation (NSF) portfolio addressing K-12 engineering and technology education includes initiatives supported by a number of programs. This list includes projects identified by searching lists of awards in the respective NSF programs as well as projects suggested for inclusion by researchers, practitioners, and program officers. The list includes projects concerned with standards in technology education, teacher professional development, centers for learning and teaching, preparation of instructional materials, digital libraries, and technological activities in informal settings, as well as small numbers of projects in several other areas. This compilation provides current information on projects of interest to educators, instructional designers, consultants, and researchers who are concerned with the development, delivery, and evaluation of instruction to develop technological literacy, particularly in K-12 engineering and technology education. Projects are grouped under headings for each program providing primary funding. Within each program, the award numbers determine the order of listing, with the most recent awards at the beginning of the list. Each award entry includes the project title, NSF award number, funding program, amount of the award to date, starting and ending dates, the principal investigator (PI), the grantee institution, PI contact information, the url of the project Web site, a description of the project’s activities and accomplishments, relevant previous awards to the PI, products developed by the project, and information on the availability of those products

A Framework for Teaching Computational Thinking in Primary Schools: A Namibian Case Study

Several professional development programs have been designed to train in-service teachers on a computational thinking (CT) curriculum, but few researchers have examined how these affect primary school teachers\u27 self-efficacy and knowledge of CT in emerging economies. This study\u27s objective was to create a framework for the professional development of primary school in-service teachers for the teaching of CT (referred to as professional development for primary computational thinking - PD4PCT) to be integrated into teachers\u27 professional development programs. An initial framework was refined after implementing it at a Namibian school with a group of 14 teachers from five different disciplines (social studies, English, natural science, mathematics, and Afrikaans). Literature reviews, pre- and post-intervention questionnaires, semi-structured interviews, and self-reporting diaries were used to collect data. The framework was evaluated by experts via an online questionnaire. The findings show that teachers who participated in the professional development program improved their perceived CT knowledge, beliefs, and confidence to teach CT

Elementary Educators\u27 Attitudes about the Utility of Educational Robotics and Their Ability and Intent to Use It with Students

Educational robotics (ER) combines accessible and age-appropriate building materials, programmable interfaces, and computer coding to teach science and mathematics using the engineering design process. ER has been shown to increase K-12 students\u27 understanding of STEM concepts, and can develop students\u27 self-confidence and interest in STEM. As educators struggle to adapt their current science teaching practices to meet the new interdisciplinary nature of the Next Generation Science Standards, ER has the potential to simultaneously integrate STEM disciplines, engage and inspire students in mathematics and science, and build connections to STEM careers. One challenge is a lack of documented models for preparing educators, particularly at the elementary level, to effectively use robotics in their classrooms. The lack of scholarship on appropriate robotics platforms for elementary learners, reliable techniques of delivering professional development in ER, or standardized instruments that can reliably measure elementary educators\u27 self-efficacy with robotics suggests there is a need for such research. The primary purpose of this study was to investigate the impact of a four-hour, hands-on, ER professional development workshop on K-5th grade educators\u27 attitudes about their ability to teach ER, the value (utility) of the technology, and their desire to use it (intent). An 18-question survey was administered before (pre-) and after (post-) the workshop, as well as a third time after educators had an opportunity to use robotics with students (post-post). In order to extend and explain the quantitative data, 60% of the educators who completed all three surveys were also interviewed. This study sought to determine if any of the trained educators also participated in after-school robotics competitions, and if so what impact that had on their attitudes of using ER. Results comparing the pre to post workshop means determined that there were statistically significant differences with large effect sizes in educators\u27 attitudes across all three subscales. The interviews supported the conclusion that the workshop and classroom kits are important for successful implementation of ER in classrooms. Post use surveys did not result in statistically significant differences in educators\u27 attitudes, demonstrating persistence of attitudes consistent with the interview results that revealed educators value the hands-on nature of ER which they believe increases student engagement in STEM and cross-curricular learning. A case-study of one educator suggests that participation in FIRSTRTM LEGORTM League Jr. increased the skills, confidence, and engagement of both the teacher and students which led to the integration of engineering practices, and school-wide interest in ER. This study demonstrates the importance of high-quality professional development in increasing educators\u27 self-efficacy with using ER with elementary students, and suggests that new tablet-based, wireless robotics platforms, such as the LEGORTM WeDo 2.0 enable younger learners to engaged with this technology. Additional research is necessary to better understand the impact of ER on students, and to identify and study schools where ER helped lead a transformation of the teaching toward constructionism. It is vital for the success of our children and our nation that we engage and inspire students in STEM subjects and career pathways at an early age if we are to meet the needs of the 21st century job market, reduce disparities in STEM fields, and maintain our place in the global economy

Design-activity-sequence: A case study and polyphonic analysis of learning in a digital design thinking workshop

In this case study, we report on the outcomes of a one-day workshop on design thinking attended by participants from the Computer-Supported Collaborative Learning conference in Philadelphia in 2017. We highlight the interactions between the workshop design, structured as a design thinking process around the design of a digital environment for design thinking, and the diverse backgrounds and interests of its participants. Data from in-workshop reflections and post-workshop interviews were analyzed using a novel set of analytical approaches, a combination the facilitators made by possible by welcoming participants as coresearchers

A Systematic Review of Studies on Educational Robotics

There has been a steady increase in the number of studies investigating educational robotics and its impact on academic and social skills of young learners. Educational robots are used both in and out of school environments to enhance K–12 students’ interest, engagement, and academic achievement in various fields of STEM education. Some prior studies show evidence for the general benefits of educational robotics as being effective in providing impactful learning experiences. However, there appears to be a need to determine the specific benefits which have been achieved through robotics implementation in K–12 formal and informal learning settings. In this study, we present a systematic review of the literature on K–12 educational robotics. Based on our review process with specific inclusion and exclusion criteria, and a repeatable method of systematic review, we found 147 studies published from the years 2000 to 2018. We classified these studies under five themes: (1) general effectiveness of educational robotics; (2) students’ learning and transfer skills; (3) creativity and motivation; (4) diversity and broadening participation; and (5) teachers’ professional development. The study outlines the research questions, presents the synthesis of literature, and discusses findings across themes. It also provides guidelines for educators, practitioners, and researchers in areas of educational robotics and STEM education, and presents dimensions of future research

Developing Teaching Practice in Computational Thinking in Palestine

Sporadic efforts have been made to introduce computational thinking methods into K-12 education in Palestine, but these have been held back by the challenging educational environment. However, a recent in-service training initiative, funded and organized by the Ministry or Education of Palestine, constitutes a significant effort to embed computational thinking in K-12 practice. The middle school teachers who participated in the training course were invited to participate in the present study, and 38 did so. A qualitative approach involving both interviews with teachers and classroom observations was used in data collection. All the teachers agreed to be observed in their classrooms, while 20 of the 38 also agreed to participate in the interviews. The findings showed that teachers of a range of topics, including social sciences and languages, employed computational thinking skills in teaching their students, but they were confronted by a number of challenges, including technical infrastructure and support, and a lack of time to prepare CT classes and space in the curriculum to deliver them. The results indicate that the most appropriate action to support teachers' delivery of CT would be to provide peer exchanges and expert coaching in the integration of CT in the curriculum

Determining the Effectiveness of a Professional Development Experience Focused on Integrating Computer Science into Early Childhood Curriculum

No doubt exists that literacy and mathematics are the primary foci of early childhood education. Children have limited exposure to computer science-related topics, including robotics, coding, and engineering design. This study is based on prior research evidence indicating that early childhood teachers’ confidence and competence can be enhanced with professional development in computer science-related areas, which in turn can enhance the exposure of children and increase their interest and skills in computer science. In this record of study using both quantitative and qualitative methods, I address early childhood teachers’ lack of knowledge and experience in coding, engineering design, and robotics, and by conducting three, six-hour workshops focused on these concepts. Participants engaged in hands-on activities and discussions and were provided resources to support learning and classroom integration. Participants completed two pre- and two identical post- assessments measuring a) competence levels in engineering design, robotics, computational thinking, and coding and b) their confidence levels in using coding, engineering design, and robotics in their classrooms. Positive gains were made in both confidence and competence levels of the teachers. The artifact created is a framework that can be used to design and deliver focused professional development. The key factors within the framework include reflective practice, providing appropriate and timely resources, and building a personal network. Designing sustained professional development that includes the key factors may lead to an increase in confidence and competence in integrating computer science concepts across the early childhood curriculum

Academic Collaborative Efforts to Promote STEM Equity in High Needs Schools

America is at risk of facing a shortage of workers in STEM fields in the near future because lack of interest by its youth. It is well known that providing early exposure for P-12 students to engaging science, technology, engineering, and math (STEM) experiences can lead to lifelong learning and positively impact future career decisions. This manuscript describes one university’s collective efforts to bring equity to STEM education for an urban high needs school district in the northeastern part of the United States through various STEM initiatives over a five-year period. Through multiple projects and initiatives targeting both P-12 students and their teachers, descriptive results revealed a positive impact while pinpointing areas that still require attention. P-12 students indicated an increase in STEM knowledge and an increased interest in STEM careers following exposure to various STEM lessons and interactive experiences. P-12 teachers specified that Professional Development (PD) they received from university faculty as well as engaging in STEM experiences with their students enhanced their confidence in their ability to incorporate STEM lessons within their classrooms. An urban partner administrator viewed these various STEM initiatives as vital in their quest to bring equity for STEM education to their diverse student population

Robots in elementary school : some educational, legal and technical aspects

This article focuses on robots in elementary school. The authors present an analysis of a number of educational, legal and technical aspects. The article also includes an overview of literature on robotics in elementary school. In the second part a description is provided of more adequate equipment: LEGO Robotics and the LEGO MINDSTORMS RCX Intelligent Brick and Robotics Invention System, WeDo 2.0, Dash & Dot Pack: 2 companionable robots for teaching robotics to children. Next, the authors discuss selected legal regulations relating to school curricula, for example, proposals put forward by the Council for the Informatization of Education at the Ministry of National Education. One of the sections contains good examples of use of robotics in Polish schools. The position of the course of robotics (including elements of design, construction and programming of robots) in modern teaching in Polish schools is also presented, using as an example the experience of teachers working in Bielsko-Biala (Silesia region). Besides, research results of a study, conducted in Poland and in Ukraine, are discussed. Finally, the authors present their conclusions

Where and how 3D printing is used in teaching and education

The emergence of additive manufacturing and 3D printing technologies is introducing industrial skills deficits and opportunities for new teaching practices in a range of subjects and educational settings. In response, research investigating these practices is emerging across a wide range of education disciplines, but often without reference to studies in other disciplines. Responding to this problem, this article synthesizes these dispersed bodies of research to provide a state‐of‐the‐art literature review of where and how 3D printing is being used in the education system. Through investigating the application of 3D printing in schools, universities, libraries and special education settings, six use categories are identified and described: (1) to teach students about 3D printing; (2) to teach educators about 3D printing; (3) as a support technology during teaching; (4) to produce artefacts that aid learning; (5) to create assistive technologies; and (6) to support outreach activities. Although evidence can be found of 3D printing‐based teaching practices in each of these six categories, implementation remains immature, and recommendations are made for future research and education policy.This work was supported by the Engineering and Physical Sciences Research Council [number EP/K039598/1]