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1. Implementing Project Management Skills Training Through Thesis Research Within STEM Graduate Education

   Gansemer-Topf, Ann M; Jiang, Shan; Liang, Yiqi; Chen, Dong; Li, Qing; Reuel, Nigel; Okudan_Kremer, Gül E (June 2023, ASEE)

   Science, Technology, Engineering, and Mathematics (STEM) graduate education traditionally has focused on developing technical and research skills needed to be successful in academic and research settings. In the past decade, however, STEM graduate students increasingly have sought positions in the industry [1]; a recent study by Sherman et al. [2] found that non-academic industry jobs were the most preferred career choice for STEM doctoral students. Despite this preference, graduate education has yet to adapt to better prepare students for their industry positions; a significant portion of students need critical professional skills, such as project management (PM), needed to be effective leaders in these non-academic environments [3-9]. Although a required skill in the industry, these professional skills also can significantly enhance future careers within research and the academy. 

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2. How do undergraduate engineering students conceptualize product design? An analysis of two third‐year design courses

   https://doi.org/10.1002/jee.20468  

   Miska, Jacob W.; Mathews, Laura; Driscoll, Jessica; Hoffenson, Steven; Crimmins, Sarah; Espera, Jr., Alejandro; Pitterson, Nicole (May 2022, Journal of Engineering Education)

   Abstract BackgroundEngineering education traditionally emphasizes technical skills, sometimes at the cost of under‐preparing graduates for the real‐world engineering context. In recent decades, attempts to address this issue include increasing project‐based assignments and engineering design courses in curricula; however, a skills gap between education and industry remains. Purpose/HypothesisThis study aims to understand how undergraduate engineering students perceive product design before and after an upper‐level project‐based design course, as measured through concept maps. The purpose is to measure whether and how students account for the technical and nontechnical elements of design, as well as how a third‐year design course influences these design perceptions. Design/MethodConcept maps about product design were collected from 105 third‐year engineering students at the beginning and end of a design course. Each concept map's content and structure were quantitatively analyzed to evaluate the students' conceptual understandings and compare them across disciplines in the before and after conditions. ResultsThe analyses report on how student conceptions differ by discipline at the outset and how they changed after taking the course. Mechanical Engineering students showed a decrease in business‐related content and an increased focus on societal content, while students in the Engineering Management and Industrial and Systems Engineering programs showed an increase in business topics, specifically market‐related content. ConclusionThis study reveals how undergraduate students conceptualize product design, and specifically to what extent they consider engineering, business, and societal factors. The design courses were shown to significantly shape student conceptualizations of product design, and they did so in a way that mirrored the topics in the course syllabi. The findings offer insights into the education‐practice skills gap and may help future educators to better prepare engineering students to meet industry needs. 

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3. Competencies for human–robot collaboration in the construction industry: perspectives from academia and industry

   https://doi.org/10.1007/s41693-025-00156-y  

   Olukanni, Ebenezer; Akanmu, Abiola; Jebelli, Houtan; Ammar, Ashtarout; Okunola, Akinwale (December 2025, Construction Robotics)

   Abstract Robotic automation in construction has created the need for new competencies that will enable the workforce to engage with robots safely and effectively. However, differing perceptions between industry professionals and academia make aligning academic programs with industry needs challenging. This study evaluates these perceptions to guide the design of HRC training programs. A three-round Delphi study was conducted separately with panels of industry professionals and academic experts to assess their views on HRC competencies in construction. The findings revealed that both panels identified human–robot interfaces, HRC safety and standards, robot control systems, and construction robot applications as the top five HRC knowledge areas. Industry professionals also emphasized task planning knowledge, while academic experts focused on HRC ethics. Key HRC skills include effective communication, safety management, technical proficiency, and compliance with regulations and standards, with industry professionals prioritizing proficiency in task planning and academics emphasizing human–robot interface proficiency. Both expert panels prioritized teamwork, continuous learning, problem-solving, communication, and adaptability as top-rated HRC abilities. This study contributes to knowledge by defining key HRC competencies and identifying differences in priorities between industry and academia. These insights can guide the development of academic curricula that better align with industry needs, supporting the creation of training programs that equip the workforce with the competencies required for safe and effective robotic collaboration. The study also promotes collaboration between industry and academia, fostering innovation in HRC and robotics in construction. Future research directions are proposed to explore innovative training methods to equip the future workforce with HRC competencies. 

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4. Holographic Learning Environment for Bridging the Technical Skill Gap of the Future Smart Construction Engineering Students

   Ogunseiju, Omobolanle; Akanmu, Abiola; Bairaktarova, Diana (January 2020, Enabling the Development and Implementation of Digital Twins: Proceedings of the 20th International Conference on Construction Applications of Virtual Reality)

   Dawood, Nashwan; Rahimian, Farzad P.; Seyedzadeh, Saleh; Sheikhkhoshkar, Moslem (Ed.)

   The growth in the adoption of sensing technologies in the construction industry has triggered the need for graduating construction engineering students equipped with the necessary skills for deploying the technologies. One obstacle to equipping students with these skills is the limited opportunities for hands-on learning experiences on construction sites. Inspired by opportunities offered by mixed reality, this paper presents the development of a holographic learning environment that can afford learners an experiential opportunity to acquire competencies for implementing sensing systems on construction projects. The interactive holographic learning environment is built upon the notions of competence-based and constructivist learning. The learning contents of the holographic learning environment are driven by characteristics of technical competencies identified from the results of an online survey, and content analysis of industry case studies. This paper presents a competency characteristics model depicting the key sensing technologies, applications and resources needed to facilitate the design of the holographic learning environment. A demonstrative scenario of the application of a virtual laser scanner for measuring volume of stockpiles is utilized to showcase the potential of the learning environment. A taxonomic model of the operational characteristics of the virtual laser scanner represented within the holographic learning environment is also presented. This paper contributes to the body of knowledge by advancing immersive experiential learning discourses previously confined by technology. It opens a new avenue for both researchers and practitioners to further investigate the opportunities offered by mixed reality for future workforce development. 

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5. NSF ATE: Improving Electrical Engineering Education Structure by Bridging CTE, Community College, and University Programs through Hands-on Skills Integration: Year 1

   Kamali-Sarvestani, Reza; Villa, Hector G; Nguyen, Khang; Mauro, Antony P (June 2025, ASEE Annual Conference)

   This project focuses on developing three technical courses for lower-division electrical engineering education to bridge the gap between Career and Technical Education (CTE) programs in high schools, engineering programs at community colleges, and lower-division electrical engineering courses at four-year universities. The primary goal of the project is to create a seamless academic transition by providing electrical engineering students with the necessary foundational knowledge in analog and digital systems, as well as hands-on experience with laboratory measurement tools. The courses utilize industry-relevant technologies such as LabView, MATLAB, PLC programming, and ready-to-use microcontroller boards to facilitate experiential learning at lower division courses. Early exposure to these tools and systems equips students with practical skills that not only prepare them for further academic pursuits but also align them with workforce demands in industries that increasingly rely on automation, data acquisition, and real-time system controls. The success of this project is attributed to its emphasis on design and project-based learning, which fosters critical thinking and problem-solving skills essential for real-world applications. By integrating design principles early in students' educational experiences, they are better prepared to tackle complex engineering problems as they progress through their academic careers. The use of project-based learning allows students to apply theoretical knowledge to tangible, real-world projects, improving their engagement and deepening their understanding of electrical engineering concepts. Practical tools like MATLAB and microcontroller boards in entry-level courses not only motivates students to pursue engineering but also increases retention rates in STEM fields, a key metric for academic success. This project is also advocating for early exposure to hands-on technical skills as a way to better prepare students for the workforce. By focusing on skill development in both CTE programs and early college courses, students are equipped with a stronger foundation for electrical engineering careers and are more likely to succeed in upper-division coursework and beyond. The seamless integration of high school, community college, and university programs ensures that students acquire both the theoretical and practical skills necessary to be successful in an increasingly technology-driven economy. Moreover, the project's use of industry-standard tools, coupled with its focus on bridging academic gaps, provides a sustainable model for developing a skilled and versatile workforce, addressing the growing need for engineers proficient in both design and system implementation. 

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