Robotics technologies are a significant tool in many industries. This paper presents a historical analysis of educational robots and how they apply to K-12 education from the past and potential in the future; focusing on the time period before and after the year 2000. The article concludes with future directions for curriculum and robotics in…

Innovative education is a higher training requirement for education in the period of social transformation. It needs the education to cultivate talents with innovative consciousness and ability for the development of society. High school is critical for facilitating students' innovative consciousness, innovative thinking, and innovative ability…

Computational Thinking (CT) is being promoted as "a fundamental skill used by everyone in the world by the middle of the 21st Century" (Wing, 2006). CT has been effectively integrated into history, ELA, mathematics, art, and science courses (Settle, et al., 2012). However, there has been no analogous effort to integrate CT into…

Tinker Tailor Robot Pi (TTRP) is an innovative curriculum development project, which started in September 2014. It involves in-service primary and secondary teachers, university academic engineers, business partners and pupils at Key Stages 1, 2 and 3 (ages 5-14). The focus of the work has been to explore how a pedagogy for primary engineering…

A wide variety of out-of-school time (OST) programs across the U.S. offer science education opportunities that cover many scientific disciplines and use diverse pedagogical practices (National Research Council [NRC], 2009). However, to improve youth's scientific literacy, OST educators need to "have the disposition and repertoire of practices…

An interdisciplinary undergraduate-level robotics course offers students the chance to integrate their engineering knowledge learned throughout their college years by building a robotic system. Robotics is thus a core course in system and control-related engineering education. This paper summarizes the experience of developing robotics courses…

Technological fields, like engineering, are in desperate need of more qualified workers, yet not enough students are pursuing studies in science, technology, engineering, or mathematics (STEM) that would prepare them for technical careers. Unfortunately, many students have no interest in STEM careers, particularly engineering, because they are not…

From 2004-2007, the University of Memphis carried out the NSF-funded Tri-P-LETS (Three P Learning Environment for Teachers and Students) project to improve local high-school computer science curricula. The project reached a total of 58 classrooms in eleven high schools emphasizing problem solving skills, programming concepts as opposed to syntax,…

"Why Teach Robotics?" (Waddell) suggests that the United States lags behind Europe and Japan in use of robotics in industry and teaching. "Creating a Course in Mobile Robotics" (Doty) outlines course elements of the Intelligent Machines Design Lab. (SK)

Inventors design new products because there is a strong need for them. Understanding this and discussing it in the classroom will show students how technology, math and science are used to improve everyone's standard of living and strengthen the economy. There are numerous connections to history, social studies and literacy--making the study of…

A general laboratory course featuring microcomputer interfacing for data acquisition, process control and automation, and robotics was developed at Rensselaer Polytechnic Institute and is now available to all junior engineering students. The development and features of the course are described. (JN)

Discussion of the possibilities of introducing artificial intelligence (AI) into the undergraduate curriculum highlights the introduction of AI in an introduction to information processing course for business students at George Washington University. Topics discussed include robotics, expert systems prototyping in class, and the interdisciplinary…

Discusses why educators should not rush headlong into creating robotics curricula and suggests methods of establishing meaningful courses. Indicates that the solution to the problem of building a robotic curriculum is to incorporate the three major areas of robotics (design, operations, maintenance) into existing curricula where they best fit. (JN)

Describes a four-part curriculum that can serve as a model for incorporating artificial intelligence (AI) into the high school computer curriculum. The model includes examining questions fundamental to AI, creating and designing an expert system, language processing, and creating programs that integrate machine vision with robotics and…

Discusses the development of industrial robotics training materials, considering the need for such materials, preliminary curriculum design, the Piagetian approach followed, and the uses of computer assisted instruction. A list of robotics curriculum courses (with content and audience indicated) is included. (JN)