scholarly journals INTERNATIONAL FIELD SCHOOL FOR FIRST-YEAR ENGINEERING STUDENTS

Author(s):  
Brian Dick ◽  
Thai Son Nguyen ◽  
Mackenzie Sillem

Engineering graduates increasingly find that they are part of teams that draw a multi-disciplinary membership across a broad range of cultural, socio-economic, and linguistic backgrounds. Although engineering students often have the opportunity to participate in international projects (e.g. co-operative education programs, study abroad), formal international field schools are not typical within engineering curricula, particularly at the first- and second-year level. To provide an early introduction to intercultural perspectives, first-year engineering students at Vancouver Island University (VIU) participated in a field school at Tra Vinh University (TVU) in Tra Vinh Province, Vietnam over a period of three weeks. This field school consisted of a number of cultural and engineering activities, and involved pairing of students at both TVU and VIU for the duration of the experience. To measure student response during the field school, participating VIU students completed the on-line Intercultural Effectiveness Scale questionnaire pre- and post-experience. Students at both institutions also completed reflection exercises throughout the three-week period. This feedback suggested each student pairing continuously developed skills necessary to overcome linguistic, cultural, and technical barriers to learning and growing over their time together. Students described an enhanced understanding of self, and an increased likelihood to further participate in intercultural experiences. 

Author(s):  
Anabela C. Alves ◽  
Francisco Moreira ◽  
Celina P. Leão ◽  
Sandra Fernandes

Abstract Project-Based Learning (PBL) is an active student-centered learning methodology. Several schools (of varying degrees of education) have implemented, in different ways, PBL, having as common strands that the student learns in teams, and being challenged in the context of a case-scenario. In Portugal, a PBL methodology has been implemented, in the first year of an Industrial Engineering and Management (IEM) program, for more than 15 years. This represents a total number above 700 students of IEM enrolled in PBL during the reported timeframe. A continuous improvement process of the PBL activities was relentlessly pursued during such period. Grounded on end-of-term on-line PBL process satisfaction questionnaires, as well as on results of each PBL edition final workshops, this paper studies and reports on a number of such achievements and shortcomings. Thus, this paper presents the analysis of the results of ten academic years of PBL evaluation process, grounded on the compiled results obtained from 2009/10 to 2019/20. Also, a synthesis of the effective findings (either positive or negative), systematically pointed out by the students, will be presented. Altogether, the PBL implementation in the IEM program has been very positive for students and teachers and worth for others to follow.


Author(s):  
B. Memarian ◽  
S. Zuluaga ◽  
M. Stickel

This paper shares a summary of the self-reported concerns of 134 first-year engineering students around engagement in online active learning environments during COVID-19. The students had volunteered to participate in remote weekly problem-solving workshops for four weeks that utilized Active Learning techniques. In this paper, we specifically analyze samples from the students who participated in only one workshop and responded to the following question: What concerns do you have that might limit your ability to engage in online active learning environments? Twenty of the participants reported no concerns. The tone of each student's response and personal feelings reported were also analyzed. Then, a thematic analysis of each student response was made, with the transcription and coding agreement being performed by two coders. As expected, most of the students expressed their concerns in a negative or neutral tone, and only a few expressed an affinity for current educational settings. Word mining of feeling terms shows that more students had verbalized being disengaged, followed by distracted and uncomfortable and none communicated a positive feeling. Our thematic analysis showed that learning socially (72/114, or 63%) is the most pressing concern for the students, followed by more personal regulating factors such as attitude and motivation (44%), quality of physical and virtual study environment (40%), as well as the guidance received from the course administrators (24%). Findings suggest the need for developing a global understanding of what active learning in an online environment entails in the context of engineering education, and to develop and adjust tools and practices to help students learn in this new context.


2018 ◽  
Vol 42 (2) ◽  
pp. 360-367 ◽  
Author(s):  
Daniel Naveed Tavakol ◽  
Cara J. Broshkevitch ◽  
William H. Guilford ◽  
Shayn M. Peirce

In the Undergraduate School of Engineering and Applied Sciences (SEAS) at the University of Virginia (UVa), there are few opportunities for undergraduate students to teach, let alone develop, an introductory course for their major. As two undergraduate engineering students (D. N. Tavakol and C. J. Broshkevitch), we were among the first students to take advantage of a new initiative at UVa SEAS to offer student-led courses. As part of this new program, we designed a 1000-level, 1-credit, pass-fail course entitled Introduction to Research in Regenerative Medicine. During a student’s first year at the University, opportunities to build research skills and gain exposure to topics within the field of the biomedical sciences are relatively rare, so, to fill this gap, we focused our course on teaching primarily freshman undergraduate students how to synthesize and contextualize scientific literature, covering both basic science and clinical applications. At the end of the course, students self-reported increased confidence in reading and discussing scientific papers and review articles. The critical impact of this course lies not only in an early introduction to the popularized field of regenerative medicine, but also encouragement for younger students to participate in research early on and to appreciate the value of interdisciplinary interactions. The teaching model can be extended for implementation of student-taught introductory courses across diverse undergraduate major tracks at an institution.


1996 ◽  
Vol 33 (1) ◽  
pp. 11-17
Author(s):  
R. G. Harris

The Internet — a first year course option for an engineering common programme For new users of the Internet there is a need for a coherent presentation of its facilities. A first year option for all engineering students at Sheffield Hallam University is ‘Navigating the Information Super Highway’ which achieves this. The paper outlines the rationale of this course, describes the topics covered, course structure and student response to it.


Author(s):  
George Platanitis ◽  
Remon Pop-Iliev

Normally, there is very little opportunity for first-year engineering students to practice robust design techniques given the relatively simple nature of their projects, and they are not exposed to any robust design activity and Design of Experiments (DOE) methodologies until their third year. How can junior engineering students gain a sense of the robustness of their designs? Will the resulting product still be acceptably functional if used in non-ideal environments? The purpose of this paper is to introduce a potential assignment to supplement this need at the first-year level. Introduced as a bonus assignment in Fall 2009, students were charged with the task of designing an aircraft wing by choosing parameter setting combinations that would provide the maximum Lift-to-Drag ratio, simulating results theoretically that would be obtained in a wind-tunnel experiment, while including random noise. All necessary facts and equations were given, leaving students with the task of running calculations and employing Taguchi methods to select an optimal set of parameters. While few students chose to undertake the assignment, those that did it found the application interesting and useful. Example results for this robust design assignment, including final parameter selections for the optimal wing design, are presented in this paper, along with factors where students have shown weaknesses.


Author(s):  
Shai Cohen ◽  
Micah Stickel

One of the great advantages of developing online courses is that it enables the institution to reimagine how they can deliver that content to their students. In recent years, the Faculty of Applied Science and Engineering at the University of Toronto has worked to develop a set of first year calculus courses in an online format. These courses were designed specifically for engineering students to: (a) situate the material in an engineering context through multiple real-world examples and “on-site” videos, (b) place an increased emphasis on the form of the solution, and (c) incorporate a significant experience in mathematical modeling through a self-defined project.In July and August of 2014, the Calculus for Engineers I online course was offered to incoming first-year students that were to start in September 2014. The purpose of this paper is to summarize the experiences related to this unique offering from the perspectives of the students as well as the Faculty administration and course instructor.Of the 900 students that were invited to take the course, 170 initially registered for the course in early July, and of those 48 students completed the course at the end of August. Of the 44 students that passed the course, 20 (48%) decided to continue on with the online offering of Calculus for Engineers II in the fall 2014 term.Overall, students were quite positive about their online learning experience and were glad to have the opportunity to complete a credit before their official start. This allowed them to either take an elective in their first year or have a lighter workload in one of the terms.In their course survey comments, they noted that they appreciated the opportunity to learn and review the material at their own pace, the way in which the instructor connected the mathematics to an engineering context, and having an early introduction to the university learning environment.Delivering an online university-level calculus course to incoming first-year students is an exciting and novel way to enhance the engineering student experience in first year. This paper provides an introductory summary of this approach from the students’, instructor’s, and administrators’ perspectives.


2013 ◽  
Vol 14 (2-4) ◽  
pp. 97-113 ◽  
Author(s):  
Danielle Cahill ◽  
Diane Catanzaro
Keyword(s):  

Author(s):  
Jeremiah Vanderlaan ◽  
Josh Richert ◽  
James Morrison ◽  
Thomas Doyle

We are a group of engineering students, in our first year of undergraduate study. We have been selected from one thousand first year students and have competed and won the PACE competition. All engineers share a common general first year, but we have been accepted into Civil and Mechanical engineering. This project was assigned as the final project in the Design and Graphics course. The project we are tasked with, called the Cornerstone Design Project, is to first dissect a product, discover how it works, dimension each part and create a fully assembled model using CAD software (Solid Edge V20 in our case). As part of discovering how it works we must benchmark it so the device can be compared with competing products. The goal of the project is to develop a full understanding of part modeling and assembly in Solid Edge, learn proper measurement techniques, and learn the process of reverse engineering and product dissection. All of these tasks were stepping stones to help us fully understand how the device, and all its components, work.


Author(s):  
Umar Iqbal ◽  
Deena Salem ◽  
David Strong

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.


Sign in / Sign up

Export Citation Format

Share Document