scholarly journals TEACHING FIRST-YEAR STUDENTS TO COMMUNICATE PROBLEM ANALYSIS AND INVESTIGATION WITH AN ENGINEERING-SPECIFIC WRITING MODEL

2020 ◽  
Author(s):  
George Lamont ◽  
Stephan Lambert
Keyword(s):  
Engineering Students ◽  
First Year ◽  
Problem Analysis ◽  
First Year Students ◽  
Engineering Programs ◽  
Students Success

The ability to communicate problem analysis and investigation is crucial to engineering students’ success. The Swales CARS model has generated considerable pedagogical interest because it describes how many engineers communicate in diverse documents. However, research has not yet reached any consensus about how effectively this model improves students’ ability to communicate problem analysis and investigation. In previous work, we reported that teaching the Swales CARS model and deploying an engineering case increased the students’ confidence to critique their own projects, but that study only focused on student impressions of their ability. To address this gap and expand on previous work, we evaluated students in a first-year engineering-communications course to determine whether teaching the Swales CARS model improved their ability to communicate problem analysis and investigation. Our results show our expanded approach generates considerable gains in these skills, which has far-reaching implications for the design of communications instruction in engineering programs. 

CAD Platform Independent Software for Automatic Grading of Technical Drawings

2017 ◽  
Author(s):  
Sanchit Ingale ◽  
Anirudh Srinivasan ◽  
Diana Bairaktarova
Keyword(s):  
Engineering Students ◽  
Spatial Reasoning ◽  
Learning Experience ◽  
Spatial Visualization ◽  
First Year ◽  
Spatial Skills ◽  
First Year Students ◽  
Pedagogical Tool ◽  
Students Success ◽  
Mechanical Objects

Spatial visualization is the ability of an individual to imagine an object mentally and understand its spatial orientation. There have been multiple works proving that spatial visualization skills can be improved with an appropriate training. Such training warrant a critical place in the undergraduate engineering curricula in many engineering schools as spatial skills are considered vital for students’ success in the technical and design fields [1–4]. Enhanced spatial skills help not only professionals in the engineering field but also everyone in the 21st century environment. Drawing sectional views requires mental manipulation and visual thinking. To enhance students spatial reasoning, one of the authors of this study, conducted a class in spatial visualization. The course-learning goal aimed at improving first-year engineering students’ spatial reasoning through instruction on freehand drawings of sectional view. During the semester, two teaching assistants had to grade more than 500 assignments that consisted of sectional views of mechanical objects. This was a tedious and a time consuming task. Motivated by this experience, this paper proposes a software aiming at automating grading of students’ sectional view drawings. The proposed software will also give live feedback to students while they are working on the drawings. This interactive tool aims to 1) improve the learning experience of first year students, with limited CAD knowledge, and 2) introduce a pedagogical tool that can enhance spatial visualization training.

scholarly journals IMPORTANCE OF FIRST-YEAR ENGINEERING DESIGN PROJECTS TO SELF-EFFICACY: DO FIRST-YEAR STUDENTS FEEL LIKE ENGINEERS?

2012 ◽  
Author(s):  
Jon Michael ◽  
J Booth ◽  
Thomas E Doyle
Keyword(s):  
Self Efficacy ◽  
Engineering Students ◽  
First Year ◽  
Primary Concern ◽  
First Year Students ◽  
Engineering Programs ◽  
Design Project ◽  
Mastery Experiences ◽  
Design Projects ◽  
Vicarious Experiences

Self-efficacy, a belief that one can achieve a certain level of attainment, is important to student retention in engineering and technology fields. Developing ways to increase self-efficacy should be a primary concern for engineering programs. Several key tasks will be investigated including (a) the importance of design projects to self-efficacy in first-year engineering, and (b) making first-year engineering students feel like engineers. A team-based “Cornerstone” design project was undertaken by first-year engineering students as part of a Design and Graphics course. Two groups of first- year engineering students were surveyed, (1) students who had completed the course and design project in first term, and (2) students who were enrolled in the second term offering of the same course, before completing the design project. The survey focused on Bandura’s four identified sources of self-efficacy: (a) Mastery experiences, (b) Vicarious experiences, (c) Social persuasions, and (d) Physiological states, as well as a fifth often added characteristic (e) Drive and motivation. Additionally, students were asked to quantify their agreement or disagreement to the statement “I feel like an Engineer.” This paper will present the results between these two groups and will be of interest to faculty involved in freshmen design.

Assessing Engineering Design: A Comparison of the Effect of Exams and Design Practica on First-Year Students’ Design Self-Efficacy

2020 ◽  
Vol 143 (5) ◽  
Author(s):  
Hannah Nolte ◽  
Catherine Berdanier ◽  
Jessica Menold ◽  
Christopher McComb
Keyword(s):  
Self Efficacy ◽  
Engineering Students ◽  
Underrepresented Students ◽  
First Year ◽  
First Year Students ◽  
Engineering Programs ◽  
Efficacy Analysis ◽  
Design Component ◽  
Assessment Survey ◽  
Team Design

Abstract In response to calls for engineering programs to better prepare students for future careers, many institutions offer courses with a design component to first-year engineering students. This work proposes that traditional exam-based assessments of design concepts are inadequate, and alternative forms of assessment are needed to assess student learning in design courses. This paper investigates the self-efficacy differences between a traditional exam and a two-part practicum as a mid-semester assessment for introductory engineering students enrolled in a first-year design course. Increased self-efficacy has been linked to various positive student outcomes and increased retention of underrepresented students. The practicum consisted of an in-class team design task and an out-of-class individual reflection, while the exam was a traditional, individual written exam. All students completed a pre-assessment survey and a post-assessment survey, both of which included measures of design self-efficacy. Analysis showed that the practicum increased the design self-efficacy of students more effectively than the exam. Students who identified as women had greater gains in design self-efficacy during the practicum as compared with men. Identifying as a minority subgroup student was also trending toward being a significant predictor of change in design self-efficacy for the practicum. Findings suggest that a mid-semester practicum is a successful assessment of design competencies that contributes to increased first-year engineering student self-efficacy.

REVERSE ENGINEERING: TENSION RATCHET DISSECTION PROJECT

2011 ◽  
Author(s):  
Jeremiah Vanderlaan ◽  
Josh Richert ◽  
James Morrison ◽  
Thomas Doyle
Keyword(s):  
Reverse Engineering ◽  
Engineering Students ◽  
Measurement Techniques ◽  
First Year ◽  
Stepping Stones ◽  
First Year Students ◽  
Final Project ◽  
Undergraduate Study ◽  
Solid Edge ◽  
Part Modeling

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.

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.

scholarly journals What Can Students’ Bibliographies Tell Us?- Evidence Based Information Skills Teaching for Engineering Students

2006 ◽  
Vol 1 (2) ◽  
pp. 12 ◽  
Author(s):  
Fei Yu ◽  
Jan Sullivan ◽  
Leith Woodall
Keyword(s):  
Web Sites ◽  
Engineering Students ◽  
Chemical Engineering ◽  
First Year ◽  
Journal Articles ◽  
First Year Students ◽  
Internet Resources ◽  
Information Skills ◽  
Upper Level ◽  
Department Faculty

Objective - This project sought to identify students’ strengths and weaknesses in locating, retrieving, and citing information in order to deliver information skills workshops more effectively. Methods - Bibliographies submitted from first-year engineering and second- and fourth-year chemical engineering students’ project reports were analysed for the number of items cited, the variety of items cited, and the correct use of citation style. The topics of the project reports were also reviewed to see the relationships between the topics and the items cited. Results - The results show that upper level students cited more items in total than did lower level students in their bibliographies. Second- and fourth-year engineering students cited more books and journal articles than first-year students cited. Web sites were used extensively by all three groups of students, and for some first-year students these were the most frequently used sources. Students from all three groups had difficulties with citation style. Conclusion - There was a clear difference in citation frequency between upper and lower level engineering students. Different strategies of information skills instruction are needed for different levels of students. Librarians and department faculty members need to include good quality Internet resources in their teaching and to change the emphasis from finding information to finding, interpreting, and citing accurately.

Education for sustainable development in Spanish higher education: an assessment of sustainability competencies in engineering and education degrees

2021 ◽  
Vol ahead-of-print (ahead-of-print) ◽  
Author(s):  
Fermín Sánchez-Carracedo ◽  
Daniel Romero-Portillo ◽  
Bàrbara Sureda Carbonell ◽  
Francisco Manuel Moreno-Pino
Keyword(s):  
Sustainable Development ◽  
Engineering Students ◽  
Education For Sustainable Development ◽  
First Year ◽  
Education Students ◽  
First Year Students ◽  
Content Type ◽  
Spanish Higher Education ◽  
Percentage Measure ◽  
University Degree

Purpose This paper aims to present a methodology for analysing the extent to which students of a university degree perceive that they have received a good education for sustainable development (ESD). The methodology enables us to quantify this perception, which, in turn, allows us to determine: to what extent the objectives related to ESD are achieved in the degree, and to compare the learning in ESD perceived by students of different degrees. The methodology is applied to nine engineering degrees and nine education degrees in the Spanish university system. Design/methodology/approach ESD is analysed from the students’ learning perception. This perception is measured by comparing the responses of first- and fourth-year students to a questionnaire about their sustainability competencies. Two indicators have been designed to analyse the results. The first indicator, learning increase, measures the declared learning difference between fourth- and first-year students. The second indicator, learning percentage, measure the amount of learning as reported by fourth-year students compared to how much they could have learned. Findings The results show that the average learning percentage perceived by students is higher in engineering degrees (33%) than in education degrees (27%), despite the fact that the average learning increase declared by students at the end of their studies in both areas of knowledge is similar (66%). Engineering students report having achieved higher learning than education students in all sustainability competencies, with the exception of ethics. Originality/value This paper analyses ESD from the student’s perspective. Furthermore, to the knowledge of the authors, this is the first study that compares the perception of ESD between engineering and education students. This comparison allows us to determine the different approaches that university Professors take to ESD according to the discipline they teach.

Role of Emotional Intelligence in Academic Achievement

2014 ◽  
pp. 255-263 ◽  
Author(s):  
Tripti Singh ◽  
Manish Kumar Verma ◽  
Rupali Singh
Keyword(s):  
Academic Achievement ◽  
Emotional Intelligence ◽  
Social Intelligence ◽  
Engineering Students ◽  
School Level ◽  
First Year ◽  
First Year Students ◽  
Academic Achievements ◽  
Emotional Intelligence Inventory

The purpose of this study is to see whether there is a relationship between emotional intelligence and academic achievement. The study respondents were B.Tech first year students from the Agra region. Sampling is stratified, making sure that gender, race, socioeconomic status, and abilities are appropriately represented. The respondents are given Emotional Intelligence Inventory (EII–MM), developed by S. K. Mangal and Shubhra Mangal. It consists of 100 items under four scales .The analysis suggests that there is a significant relationship between Emotional Intelligence and Academic Achievement. IQ alone is no more the measure for success; emotional intelligence, social intelligence, and luck also play a big role in a person's success. This study contributes in acknowledging the fact that even engineering students’ academic achievements are attached with Emotional intelligence. Thus, teaching emotional and social skills only at the school level is not sufficient; this can be taught in engineering studies, as well for accomplishing high academic achievements.

EFFECTIVE IMPLEMENTATION OF CONTEMPORARY PRINCIPLES ON LEARNING AND TEACHING A FUNDAMENTAL FIRST-YEAR ENGINEERING COURSE

2015 ◽  
Vol 2 (1) ◽  
Author(s):  
Y. X. Zhang ◽  
C. Yang
Keyword(s):  
Engineering Students ◽  
Team Work ◽  
Independent Learning ◽  
First Year ◽  
Engineering Programs ◽  
Learning And Teaching ◽  
Effective Implementation ◽  
Teaching Principles ◽  
Engineering Mechanics ◽  
Teaching Pedagogies

Statics is the most fundamental component of Engineering Mechanics, and it is usually delivered in the first year in a common core course for engineering programs. The delivery of this key unit to the fresh first-year engineering students is very challenging and thus teaching pedagogies, strategies and methods should be further developed in response to the challenges in this important course which critically facilitates the transition of the students from high school to university and establishes their foundation knowledge on Engineering Mechanics. This paper reports the effective implementation of contemporary learning and teaching principles in a first-year core engineering course-Statics. The learning and teaching activities designed in this course include independent learning and collaborative learning, problem and project-based team work and peer learning, and progressive assessments. Effective teaching pedagogies, strategies and methodologies are developed on the basis of these educational principles to engage and motivate the first-year engineering students at most. The proposed methodologies are demonstrated effective in engaging a medium to large size class and the results of formal course surveys demonstrate the efficiency of these methods.

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