21st Century Ergonomic Education, From Little e to Big E

Despite intense efforts, contemporary educational systems are not enabling individuals to function optimally in modern society. The main reason is that reformers are trying to improve systems that are not designed to take advantage of the centuries of history of the development of today's societies. Nor do they recognize the implications of the millions of years of history of life on earth in which humans are the latest edition of learning organisms. The contemporary educational paradigm of "education for all" is based on a 17th century model of "printing minds" for passing on static knowledge. This characterizes most of K-12 education. In contrast, 21st Century education demands a new paradigm, which we call Ergonomic Education. This is an education system that is designed to fit the students of any age instead of forcing the students to fit the education system. It takes into account in a fundamental way what students want to learn -- the concept "wanting to learn" refers to the innate ability and desire to learn that is characteristic of humans. The Ergonomic Education paradigm shifts to education based on coaching students as human beings who are hungry for productive learning throughout their lives from their very earliest days.Comment: plain latex, 13 pages, 1 tabl

Using Remote Access for Sharing Experiences in a Machine Design Laboratory

A new Machine Design Laboratory at Marquette University has been created to foster student exploration and promote “hands-on” and “minds-on” learning. Laboratory experiments have been developed to give students practical experiences and expose them to physical hardware, actual tools, and design challenges. Students face a range of real-world tasks: identify and select components, measure parameters (dimensions, speed, force), distinguish between normal and used (worn) components and between proper and abnormal behavior, reverse engineer systems, and justify design choices. The experiments serve to motivate the theory, spark interest, and promote discovery learning in the subject of machine design. This paper presents details of the experiments in the Machine Design Laboratory and then explores the feasibility of sharing some of the experiences with students at other institutions through remote access technologies. The paper proposes steps towards achieving this goal and raises issues to be addressed for a pilot-study offering machine design experiences to students globally who have access to the internet

Discovery Learning Experiments in a New Machine Design Laboratory

A new Machine Design Laboratory at Marquette University has been created to foster student exploration with hardware and real-world systems. The Laboratory incorporates areas for teaching and training, and has been designed to promote “hands-on” and “minds-on” learning. It reflects the spirit of transformational learning that is a theme in the College of Engineering. The goal was to create discovery learning oriented experiments for a required junior-level “Design of Machine Elements” course in mechanical engineering that would give students practical experiences and expose them to physical hardware, actual tools, and real-world design challenges. In the experiments students face a range of real-world tasks: identify and select components, measure parameters (dimensions, speed, force), distinguish between normal and used (worn) components and between proper and abnormal behavior, reverse engineer systems, and justify design choices. The experiments serve to motivate the theory and spark interest in the subject of machine design. This paper presents details of the experiments and summarizes student reactions and our experiences in the Machine Design Laboratory. In addition, the paper provides some insights for others who may wish to develop similar types of experiments

Mobile Robot Lab Project to Introduce Engineering Students to Fault Diagnosis in Mechatronic Systems

This document is a self-archiving copy of the accepted version of the paper. Please find the final published version in IEEEXplore: http://dx.doi.org/10.1109/TE.2014.2358551This paper proposes lab work for learning fault detection and diagnosis (FDD) in mechatronic systems. These skills are important for engineering education because FDD is a key capability of competitive processes and products. The intended outcome of the lab work is that students become aware of the importance of faulty conditions and learn to design FDD strategies for a real system. To this end, the paper proposes a lab project where students are requested to develop a discrete event dynamic system (DEDS) diagnosis to cope with two faulty conditions in an autonomous mobile robot task. A sample solution is discussed for LEGO Mindstorms NXT robots with LabVIEW. This innovative practice is relevant to higher education engineering courses related to mechatronics, robotics, or DEDS. Results are also given of the application of this strategy as part of a postgraduate course on fault-tolerant mechatronic systems.This work was supported in part by the Spanish CICYT under Project DPI2011-22443

Media literacy at all levels: making the humanities more inclusive

The decline of the humanities, combined with the arrival of students focused on science, technology, engineering, and mathematics (STEM), represent an opportunity for the development of innovative approaches to teaching languages and literatures. Expanding the instructional focus from traditional humanities students, who are naturally more text-focused, to address the needs of more application-oriented STEM learners ensures that language instructors prepare all students to become analytical and critical consumers and producers of digital media. Training students to question motives both in their own and authentic media messages and to justify their own interpretations results in more sophisticated second language (L2) communication. Even where institutional structures impede comprehensive curriculum reform, individual instructors can integrate media literacy training into their own classes. Tis article demonstrates ways of reaching and retaining larger numbers of students at all levels—if necessary, one course at a time.Published versio

Engineering design process : creating and 3D printing a mechanical toy

This report describes an activity that explores the Engineering Design Process through a research-based module intended to be implemented in a grade 9-12 science, technology, engineering and mathematics (STEM) classroom. Moreover, this study serves as a demonstration of the module’s effectiveness in guiding end users through the Engineering Design Process using computer aided design (CAD) software, to design and fabricate a fully working 3D printed mechanical toy. The hypothesis of the research is that usage of the module makes an impact on students’ proficiency with and understanding of the Engineering Design Process. Of the students enrolled in the Engineering Design and Presentation class (n=38) at the Brownsville Early College High School, a random sample (n=12) was selected for data collection purposes. Results showed that using the module increases students’ understanding of and proficiency with the Engineering Design Process and Autodesk Inventor. Finally, this paper provides insights on future modifications of the module that could lead to a better learning tool for STEM education.Science, Technology, Engineering, and Mathematics Educatio