scholarly journals An Introductory Energy Course to Promote Broad Energy Education for Undergraduate Engineering Students

2021 ◽  
Vol 13 (17) ◽  
pp. 9693
Author(s):  
Jan DeWaters ◽  
Susan Powers ◽  
Felicity Bilow
Keyword(s):  
Learning Outcomes ◽  
Engineering Students ◽  
Qualitative Assessment ◽  
Technical Knowledge ◽  
Engineering Programs ◽  
Course Content ◽  
Energy Education ◽  
Grade Levels ◽  
Energy Technologies ◽  
Complex Interactions

Engineering graduates must be prepared to support our world’s need for a clean and sustainable energy future. Complex problems related to energy and sustainability require engineers to consider the broad spectrum of interrelated consequences including human and environmental health, sociopolitical, and economic factors. Teaching engineering students about energy within a societal context, simultaneous with developing technical knowledge and skills, will better prepare them to solve real-world problems. Yet few energy courses that approach energy topics from a human-centered perspective exist within engineering programs. Engineering students enrolled in energy programs often take such courses as supplemental to their course of study. This paper presents an engineering course that approaches energy education from a socio-technical perspective, emphasizing the complex interactions of energy technologies with sustainability dimensions. Course content and learning activities are structured around learning outcomes that require students to gain technical knowledge as well as an understanding of broader energy-related impacts. The course attracts students from a variety of majors and grade levels. A mixed quantitative/qualitative assessment conducted from 2019–2021 indicates successful achievement of course learning outcomes. Students demonstrated significant gains in technical content knowledge as well as the ability to critically address complex sociotechnical issues related to current and future energy systems.

Assessment of Introductory Transportation Engineering Course and General Transportation Engineering Curriculum

2013 ◽  
Vol 2328 (1) ◽  
pp. 9-15 ◽  
Author(s):  
Rod E. Turochy ◽  
Jon Fricker ◽  
H. Gene Hawkins ◽  
David S. Hurwitz ◽  
Stephanie S. Ivey ◽  
...  
Keyword(s):  
Engineering Students ◽  
Civil Engineering ◽  
Relevant Literature ◽  
Transportation Engineering ◽  
Engineering Programs ◽  
Course Content ◽  
Credit Hours ◽  
Introductory Course ◽  
The Status ◽  
Primary Focus

Transportation engineering is a critical subdiscipline of the civil engineering profession as indicated by its inclusion on the Fundamentals of Engineering Examination and overlap with other specialty areas of civil engineering and as recognized by TRB, ITE, and ASCE. With increasing transportation workforce needs, low numbers of students entering the pipeline, and limited hours within undergraduate civil engineering programs, it is important to ensure that civil engineering students receive adequate preparation and exposure to career opportunities in the transportation engineering field. Thus, investigations into the status of transportation engineering within civil engineering programs and specifically the introductory transportation engineering course are essential for understanding implications to the profession. Relevant literature and findings from a new survey of civil engineering programs accredited by the Accreditation Board for Engineering and Technology is reviewed; that survey yielded 84 responses. The survey indicates that 88% of responding programs teach an introductory course in transportation engineering, and 79% require it in their undergraduate programs. Significant variation exists in the structure of the introductory course (number of credit hours, laboratory requirements, etc.). Common responses about improvements that could be made include adding laboratories, requiring a second course, and broadening course content. In addition, nearly 15% of instructors teaching the introductory course did not have a primary focus in transportation engineering. This finding should be investigated further, given that the course may be an undergraduate civil engineering student's only exposure to the profession.

scholarly journals Exposing Engineering Students To Renewable Energy Through Hands-On Experiments

2013 ◽  
Vol 4 (2) ◽  
pp. 127-140
Author(s):  
Yonggao Yang ◽  
Lin Li
Keyword(s):  
Renewable Energy ◽  
Teaching Methods ◽  
Engineering Students ◽  
Interdisciplinary Collaboration ◽  
Clean Energy ◽  
Business World ◽  
Energy Education ◽  
Energy Applications ◽  
Energy Technologies ◽  
Hands On

Renewable energy is the most rapidly growing discipline in today’s business world and is commonly viewed as the main arena for research and development in various fields. This article summarizes the work and efforts of an educational project conducted at Prairie View A&M University (PVAMU). A major goal of the project was to design renewable energy laboratories and expose engineering students to clean energy technologies. Through this project, the investigators engaged students in renewable energy applications through hands-on experiments, encouraged interdisciplinary collaboration, and better prepared students to enter the energy workforce. Meanwhile, the project also benefited engineering educators by exploring effective teaching methods in energy education. 

scholarly journals “In Our Own Little World”: Invisibility of the Social and Ethical Dimension of Engineering Among Undergraduate Students

2021 ◽  
Vol 27 (6) ◽  
Author(s):  
Jae Hoon Lim ◽  
Brittany D. Hunt ◽  
Nickcoy Findlater ◽  
Peter T. Tkacik ◽  
Jerry L. Dahlberg
Keyword(s):  
Content Knowledge ◽  
Undergraduate Students ◽  
Engineering Students ◽  
Spatial Distance ◽  
Ethical Dimension ◽  
Social Relevance ◽  
Engineering Programs ◽  
Course Content ◽  
Ethical Implications ◽  
The Social

AbstractThis paper explores how undergraduate students understood the social relevance of their engineering course content knowledge and drew (or failed to draw) broader social and ethical implications from that knowledge. Based on a three-year qualitative study in a junior-level engineering class, we found that students had difficulty in acknowledging the social and ethical aspects of engineering as relevant topics in their coursework. Many students considered the immediate technical usability or improved efficiency of technical innovations as the noteworthy social and ethical implications of engineering. Findings suggest that highly-structured engineering programs leave little room for undergraduate students to explore the ethical dimension of engineering content knowledge and interact with other students/programs on campus to expand their “technically-minded” perspective. We discussed the issues of the “culture of disengagement” (Cech, Sci Technol Human Values 39(1):42–72, 2014) fueled by disciplinary elitism, spatial distance, and insulated curriculum prevalent in the current structure of engineering programs. We called for more conscious effort by engineering educators to offer meaningful interdisciplinary engagement opportunities and in-class conversations on ethics that support engineering students' holistic intellectual growth and well-rounded professional ethics.

scholarly journals DEVELOPMENT OF “INTRODUCTION TO ENGINEERING” COURSES FOR FIRST YEAR ENGINEERING STUDENTS: A FOCUS ON STUDENT ATTITUDES

2020 ◽  
Author(s):  
Joel B. Frey ◽  
Ryan Banow
Keyword(s):  
Learning Outcomes ◽  
Time Management ◽  
Student Attitudes ◽  
Engineering Students ◽  
Health And Safety ◽  
Well Being ◽  
First Year ◽  
Self Assessment ◽  
Engineering Programs ◽  
College Of Engineering

Many students entering an engineering program have a strong appreciation of the importance of math- and science-based skills for their future career as an engineer, but often have little grasp of what it means to be entering a professional college.  For this reason, many engineering programs in Canada include some form of an “Introduction to the Engineering Profession” in their first-year program.  The University of Saskatchewan’s College of Engineering has been working toward the launch of a completely redesigned first year program.  This project has afforded the College an opportunity to apply a novel and transferable approach to shaping this “Introduction to the Engineering” experience.  The structure of the proposed new first year program has allowed for short and intensive “Introduction to Engineering” modules, which bookend each of the regular session terms.  This timing makes them an orientation for the program, allowing for timely deep dives into matters of importance to engineering students: study skills, time-management, teamwork, self-assessment, support services, student well-being, ethics, academic integrity, and health and safety.  The timing of the modules also allows for completion of term-long assignments and reflection on both personal and academic growth. This paper describes the process employed to develop the course learning outcomes, schedule of topics and activities, and syllabi.  The process focused on over-arching target attitudes, such as “I am on the path to becoming a professional”, and ensured constructive alignment between these attitudes and the learning outcomes, learning activities, and assessment.  The nature of the process made it easy to clarify what was essential to include in the courses, and to make a compelling case for the importance of the courses in the context of a myriad of foundational technical topics.   

WPI iCREATE: Innovation and Translation in Senior Level Biomedical Engineering Course

2013 ◽  
Author(s):  
Glenn R. Gaudette ◽  
Frank Hoy ◽  
Kristen L. Billiar
Keyword(s):  
Business School ◽  
Engineering Students ◽  
Technical Knowledge ◽  
Graduate Courses ◽  
Technology Entrepreneurship ◽  
Engineering Programs ◽  
Knowledge And Skills ◽  
Problem Solvers ◽  
Teaching Modules ◽  
Innovation And Entrepreneurship

Traditional engineering programs provide an excellent foundation in technical knowledge and skills. However, to be effective problem solvers, today’s engineering students need to develop an innovation mindset. With this goal in mind, a group of faculty from WPI Engineering Departments and from the Business School formed WPI iCREATE: iCREATE: Innovation Center for REsearch And Technology Entrepreneurship. This new center is focused on bringing innovation and entrepreneurship to both undergraduate and graduate courses, partially through the development of teaching modules.

Implementation of the Second-year course in an Engineering Professional Spine

2018 ◽  
Author(s):  
Umar Iqbal ◽  
Deena Salem ◽  
David Strong
Keyword(s):  
Learning Outcomes ◽  
Research University ◽  
Engineering Students ◽  
Employability Skills ◽  
First Year ◽  
Computer Engineering ◽  
Core Courses ◽  
Second Year ◽  
First Time ◽  
Academic Year

The objective of this paper is to document the experience of developing and implementing a second-year course in an engineering professional spine that was developed in a first-tier research university and relies on project-based core courses. The main objective of this spine is to develop the students’ cognitive and employability skills that will allow them to stand out from the crowd of other engineering graduates.The spine was developed and delivered for the first time in the academic year 2010-2011 for first-year general engineering students. In the year 2011-2012, those students joined different programs, and accordingly the second-year course was tailored to align with the different programs’ learning outcomes. This paper discusses the development and implementation of the course in the Electrical and Computer Engineering (ECE) department.

First-Year Engineering Computing Courses in Canadian Engineering Programs

1969 ◽  
Author(s):  
Sean Maw ◽  
Janice Miller Young ◽  
Alexis Morris
Keyword(s):  
Problem Solving ◽  
Engineering Students ◽  
Expected Value ◽  
Knowledge Development ◽  
First Year ◽  
Recent Past ◽  
Engineering Programs ◽  
Digital Computation ◽  
Pedagogical Philosophies ◽  
Introductory Computing

Most Canadian engineering students take a computing course in their first year that introduces them to digital computation. The Canadian Engineering Accreditation Board does not specify the language(s) that can or should be used for instruction. As a result, a variety of languages are used across Canada. This study examines which languages are used in degree-granting institutions, currently and in the recent past. It also examines why institutions have chosen the languages that they currently use. In addition to the language used in instruction, the types and hours of instruction are also analyzed. Methods of instruction and evaluation are compared, as well as the pedagogical philosophies of the different programs with respect to introductory computing. Finally, a comparison of the expected value of this course to graduates is also presented. We found a more diverse landscape for introductory computing courses than anticipated, in most respects. The guiding ethos at most institutions is skill and knowledge development, especially around problem solving in an engineering context. The methods to achieve this are quite varied, and so are the languages employed in such courses. Most programs currently use C/C++, Matlab, VB and/or Python.

Relationship between satisfaction with learning outcomes and mental health among medical and engineering students

2020 ◽  
pp. 70-78
Author(s):  
O. Bukhanovskaya ◽  
N. Demcheva
Keyword(s):  
Mental Health ◽  
Academic Performance ◽  
Mental Disorders ◽  
University Students ◽  
Learning Outcomes ◽  
Engineering Students ◽  
Clinical Forms ◽  
Complete Survey ◽  
Medical University

Method of calculating the index of crisis of gratification has been developed on the basis of the complete survey of 995 students of medical university and 804 students of engineering university, determination of clinical and social parameters and factors related to the process of education in the specialized university. It included: a scale for the assessment of the degree of intellectual intensity, academic performance, stress situations related to the peculiarities of education. Reliable differences in values between groups of healthy students, students with preclinical and clinical forms of mental disorders are revealed as a result of calculation of the index of gratification. The authors conclude that satisfaction with the results of education has a significant impact on the mental health of university students.

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