More Like this

1. Multiple Support Mechanisms for Adult and Veteran Students that Increase Academic Success in Engineering and Technology Education

   Jovanovic, Vukica; Dean, Anthony.; Landaeta, Rafael; Tomovic, Cynthia; Sibson, Kim (October 2018, 6th IAJC International Conference)

   Continuing education after years of technician experience can pose multiple challenges to the adult student population, such as incumbent workforce technicians and veterans. Veterans, through their active service, frequently receive training in highly skilled technical areas but may lack a theoretical background in underlying engineering principles. While STEM education is important for the maintenance of national competitiveness, it is especially critical that the nation’s veterans, who possess technical STEM training gained in the military, are enabled to pursue higher education in order to increase the quantity and quality of talent available in the STEM workforce. A program that will be presented in this paper emphasizes the importance of recruiting students to engineering and engineering technology disciplines, mentoring and supporting students through degree completion, and partnering with employers to facilitate student academic success and career placement in the STEM workforce. Enabling multiple mechanisms which support and provide guidance are especially important at universities with large veteran populations such as Old Dominion University, Norfolk, Virginia. Advancing the field’s understanding of interventions that affect these outcomes for adult students and student veterans is important for the improvement of future support programs as well as to guide implementation across different institutions. The program presented in this paper is funded by the National Science Foundation. 

   more » « less
2. Advanced manufacturing research experiences for high school teachers: effects on perception and understanding

   Paul*, D. (January 2018, ASEE annual conference)

   There is significant and growing interest in manufacturing; this is particularly true with respect to advanced manufacturing. Advanced manufacturing typically refers to the use of new technologies to make products that have high value or significant value added through the production process. One of the main impediments advanced manufacturing companies cite is the lack of a skilled workforce. This is the result of both a lack of technical skills, but also due to outdated and incorrect perceptions about manufacturing. Manufacturing is incorrectly perceived as low-skilled, dirty, and low paying. The reality is that a significant portion of manufacturing jobs require advanced technological knowledge and are done in state of the art facilities. One of the more effective ways to increase knowledge about science, technology, engineering, and math (STEM) careers is to increase the knowledge of teachers. As part of a National Science Foundation Advanced Technological Education project, a group of high school teachers was offered the opportunity to work in advanced manufacturing labs with engineering faculty. These projects included additive manufacturing (AM) of ceramics, surface characterization of AM metal parts, and surface alteration. The teachers were tasked with developing lesson plans which incorporated the advanced manufacturing concepts that they had learned. As part of the assessment of the program, teachers were given pre- and post- research experience surveys regarding their perceptions of manufacturing and their views of STEM topics in general; the later data were collected using the validated T-STEM instrument. External evaluation also provided feedback on the usefulness of various program activities. Overall participants found their laboratory research and research facility tours extremely useful. They felt that the program enhanced their excitement about STEM and their laboratory skills. Participants also showed significant increases in their post program technology teaching efficacy, student technology use, and STEM career awareness. In addition to empirical results, project descriptions and program details are also be presented. 

   more » « less
3. Work in Progress: Building the Mechatronics and Robotics Education Community

   Gennert, M.; Lotfi, N.; Mynderse, J.; Jethwani, M.; Kapila, V. (June 2019, ASEE annual conference exposition proceedings)

   Mechatronics and Robotics Engineering (MRE) is one of the engineering disciplines that is experiencing tremendous, dynamic growth. MRE professionals are shaping the world by designing smart systems and processes that will improve human welfare. One’s ability to meaningfully contribute to this field requires her/him to acquire an interdisciplinary knowledge of mechanical, electrical, computer, software, and systems engineering to oversee the entire design and development process of emerging MRE systems. There have been many educational efforts around MRE, including courses, minors, and degree programs, but they have not been well integrated or widely adopted. Now is the time for MRE to coalesce as a distinct and identifiable engineering discipline. To this end, and with support from the National Science Foundation, the authors have planned three workshops, the first of which has concluded, on the future of MRE education at the bachelor’s degree and postgraduate levels. The objectives of these workshops are to generate enthusiasm and inculcate a sense of community among current and future MRE educators; promote diversity and inclusivity within the community; seek feedback from the community to serve as a foundation for future activities; and identify thought leaders for future community activities. The workshops will benefit a wide range of participants including educators currently teaching in MRE; PhD students seeking academic careers in MRE; and industry professionals desiring to shape the future MRE workforce. These workshops will significantly contribute to the quality of MRE education and increase adoption to prepare individuals with a blend of theoretical knowledge and practical hands-on learning. Workshop activities include short presentations on sample MRE programs; breakout sessions on topics such as mechatronic and robotics knowledgebase, project-based learning, advanced and open-source platforms, reducing barriers to adoption, accreditation, preparation to teach MRE, and community-building; and open discussion and feedback. In this paper, the outcomes of the first workshop, results of the qualitative and quantitative surveys collected from the participants, and their analyses are presented. Particular attention is paid to attendee demographics, changes in participant attitudes, and development of the MRE community. 

   more » « less
4. Evaluation of students’ digital literacy through an immersive university-high school collaboration

   https://doi.org/10.3389/feduc.2024.1429893  

   Bruckhaus, Alexander A; Bennett, Alexis; Brawer-Cohen, Maya; Sinclair, Michael; Ramirez-De_La_Cruz, Glendy; Ragusa, Gisele; Duncan, Dominique (October 2024, Frontiers in Education)

   IntroductionRecent efforts including the U.S. Department of Education’sRaise the Bar: STEM Excellence for All Students, designed to strengthen Science, Technology, Engineering and Mathematics (STEM) education, typify the development of effective outreach programs implemented in high school settings to increase STEM achievement and literacy and to promote future careers in STEM. Specifically, artificial intelligence (AI) and machine learning (ML) are topics of great importance and interest but are often reserved for higher-level education. Introductions of complex subjects in high school promotes student efficacy, enthusiasm, and skill-development for STEM careers. Establishing strong partnerships between universities and high schools is mutually beneficial for the professional development of students, teachers, and professors. In this paper, we detail immersive outreach efforts and their effectiveness in a high school setting. MethodsFrom Spring 2021 to Spring 2024, we conducted eight data-science and analysis-coding style workshops along with two data science units, with 302 students participating in the data science workshops and 82 students in the data science units. All students who participated in the data science lessons completed a comprehensive final project. Surveys measuring knowledge and appeal to data science and coding were conducted both retrospectively and prospectively, before and after each workshop and the data science units. A 1 year follow up survey was conducted for students in the 2023 data science lessons (n= 23). ResultsOverall, average student interest significantly increased from 2.72 ± 1.08/5.0 (n= 205) to 3.15 ± 1.18/5.0 (n= 181,p= 0.001) during the data science workshops, while 70% of students expressed desire to continue with coding. Interest modestly increased in the data science lessons from 3.15 ± 0.65/4.0 to 3.17 ± 0.77/4.0 (n= 82,p= 0.8571), while knowledge significantly increased from 64.16% to 88.5% (% correct out of six questions) in the 2023 data science lessons and from 52.62% to 60.79% (% correct out of 29 questions) in the 2024 data science lessons. DiscussionIncreasing STEM exposure through outreach programs and a modified curriculum can positively alter students’ career trajectory and prepare them for the evolving technologically advanced world and the careers within it. 

   more » « less
5. Social Responsibility and Veteran Student Retention in Engineering

   https://doi.org/10.18260/1-2--33273  

   Hood, Jeffrey; Kulesza, Stacey; Liang, Jia; Fitzsimmons, Eric; Zacharakis, Jeff (June 2019, 2019 ASEE Annual Conference & Exposition)

   null (Ed.)

   Despite considerable gains made towards increasing students interest in STEM education, one specific population, Veterans in engineering, suffers from disproportionally high attrition. Social responsibility (SR) is one motivating factor for becoming an engineer and was identified as a successful intervention strategy to improve retention of first-year engineering students. SR is also a core value instilled by all branches of the U.S. military while actively serving. Therefore, the objective of this research study was to examine Veterans’ perceptions of SR as it related to engineering. For this study, a survey instrument was designed, piloted, revised, and launched for instrument validation and exploratory examination if a relationship between SR and Veteran students’ core beliefs existed. Results of this study showed that both Veteran and first-year non-Veteran students strongly value the tenants of SR. The results of this study indicate the potential for curriculum and policy changes to increase Veteran retention in engineering programs. 

   more » « less