Community College Engineering Students’ Perceptions of Classroom Climate and Fundamental Engineering Skills

ABSTRACT

The purpose of this study was to examine community college engineering students’ perceptions of their classroom climate and how these perceptions are related to fundamental skills in engineering. The study was guided by the following research question: How are community college engineering students’ perceptions of their fundamental engineering skills related to their perceptions of classroom climate? Data from a 2009 National Science Foundation sponsored project, Prototype to Production: Processes and Conditions for Preparing the Engineer of 2020 (P2P), which contains information from students in 15 pre-engineering community college programs, were examined. Measures of classroom climate and fundamental skills related to engineering were first established through an exploratory factor analysis. In order to explore differences in student perceptions by individual characteristics and by institution, hierarchical linear modeling (HLM) was used. Results indicated that for community college engineering students, a warmer perception of classroom climate was associated with a higher perception of fundamental engineering skills. At community colleges, class sizes are generally smaller, especially compared to introductory courses at universities, and may provide a warmer climate for students considering beginning their engineering degrees. Given the diversity within community colleges, these institutions may provide an important pathway for underrepresented groups in engineering.     

Students’ Views of Design in an Engineering Design-Based Science Curricular Unit

Recent reforms in science education have supported the inclusion of engineering and their practices in K-12 curricula. To this end, many classrooms have incorporated engineering units that include design challenges. Design is an integral part of engineering and can help students think in creative and interdisciplinary ways. In this study, we examined students’ conceptions of design during and after participation in a design-based science curriculum unit. Our study was guided by the following research question: What are students’ views of design after participation in an engineering design-based science curriculum unit and how are these views reflected in their enactment throughout the unit? Using a qualitative approach, we examined students’ conversations throughout the enactment of the curriculum and interviews conducted after the completion of the unit. We found that students had complex and diverse views of design, and these views were reflected in their group discussions throughout the curriculum and design challenge. Students most frequently expressed design as learning and as a process of integration into a coherent whole. These aspects of design were also frequently observed in students’ conversations during the unit. Interestingly, we found evidence of students demonstrating several aspects of design throughout the curriculum that were not explicitly expressed during the student interviews. Taken together, these findings support the complex nature of design as seen at the middle school level.

     

Korean Science and Engineering Students’ Perceptions of English-Medium Instruction and Korean-Medium Instruction

The purpose of this study was to examine how Korean science and engineering students view English-medium instruction (EMI) and Korean-medium instruction (KMI). The participants were 174 undergraduate students enrolled in EMI and KMI classes offered by the same instructor at a Korean science and engineering school. Interviews and questionnaire surveys were conducted, and students’ course evaluations, English scores and course grades were compared. The results of a campus-wide undergraduate student survey on EMI were also analyzed. The findings of the study show that the KMI-class students demonstrated higher levels of satisfaction and better performance in their classes than the EMI-class students did. Only 22% of the students in both classes found EMI classes helpful for improving their English ability. Nevertheless, the majority of the students supported the school’s maintenance of an EMI policy. In the conclusion, the paradoxical attitude of the students and the implications of the study are discussed.     

Exploring Students’ Experimentation Strategies in Engineering Design Using an Educational CAD Tool

Journal of Science Education and Technology - Experimentation is one of the important strategies used in engineering design to understand the relationship between relevant variables so that they...     

Sixth-Grade Students’ Views of the Nature of Engineering and Images of Engineers

This study investigated the views of the nature of engineering held by 6th-grade students to provide a baseline upon which activities or curriculum materials might be developed to introduce middle-school students to the work of engineers and the process of engineering design. A phenomenographic framework was used to guide the analysis of data collected from: (1) a series of 20 semi-structured interviews with 6th-grade students, (2) drawings created by these students of “an engineer or engineers at work” that were discussed during the interviews, and (3) field notes collected by the researchers during the interviews. The 6th-grade students tended to believe that engineers were individuals who make or build products, although some students understood the role of engineers in the design or planning of products, and, to a lesser extent in testing products to ensure that they “work” and/or are safe to use. The combination of drawings of “engineers or engineering at work” and individual interviews provided more insight into the students’ views of the nature of engineering than either source of data would have offered on its own. Analysis of the data suggested that the students’ concepts of engineers and engineering were fragile, or unstable, and likely to change within the time frame of the interview.     

Students’ and teachers’ perceptions: initial achievements of a Project-Based Engineering School

A unified academic model based on the project-based learning (PBL) methodology was implemented, in the 2012–2013 period, in the School of Engineering at Universidad Europea de Madrid. The purpose of this paper is to explore whether teachers and students participating in the capstone projects feel that the objectives for which this methodology was designed for are being achieved. The data were collected through interviews to participants at the end of the PBL experience. The results are encouraging, as students seem to be more motivated, and they say that they are experiencing deeper learning, and have developed key competitive skills required for their professional lives. Findings also suggest that teachers face positively the PBL as a learning approach since they perceive that students obtain a deeper learning, develop transversal skills with the projects and are more engaged with their studies. Implications and recommendations for the future of the model are also discussed.     

Elementary Students’ Learning of Materials Science Practices Through Instruction Based on Engineering Design Tasks

Materials science, which entails the practices of selecting, testing, and characterizing materials, is an important discipline within the study of matter. This paper examines how third grade students’ materials science performance changes over the course of instruction based on an engineering design challenge. We conducted a case study of nine students who participated in engineering design-based science instruction with the goal of constructing a stable, quiet, thermally comfortable model house. The learning outcome of materials science practices was assessed by clinical interviews conducted before and after the instruction, and the learning process was assessed by students’ workbooks completed during the instruction. The interviews included two materials selection tasks for designing a sturdy stepstool and an insulated pet habitat. Results indicate that: (1) students significantly improved on both materials selection tasks, (2) their gains were significantly positively associated with the degree of completion of their workbooks, and (3) students who were highly engaged with the workbook’s reflective record-keeping tasks showed the greatest improvement on the interviews. These findings suggest the important role workbooks can play in facilitating elementary students’ learning of science through authentic activity such as engineering design.     

Reciprocal Relations Between Students’ Evaluation,Reformulation Behaviors,and Engineering Design Performance Over Time

Journal of Science Education and Technology - Understanding the design process may reveal when and where resources should be focused and how engineers can better use tools, methods, and techniques...     

The Influence of Toy Design Activities on Middle School Students’ Understanding of the Engineering Design Processes

The societal demand for inspiring and engaging science, technology, engineering, and mathematics (STEM) students and preparing our workforce for the emerging creative economy has necessitated developing students’ self-efficacy and understanding of engineering design processes from as early as elementary school levels. Hands-on engineering design activities have shown the potential to promote middle school students’ self-efficacy and understanding of engineering design processes. However, traditional classrooms often lack hands-on engineering design experiences, leaving students unprepared to solve real-world design problems. In this study, we introduce the framework of a toy design workshop and investigate the influence of the workshop activities on students’ understanding of and self-efficacy beliefs in engineering design. Using a mixed method approach, we conducted quantitative analyses to show changes in students’ engineering design self-efficacy and qualitative analyses to identify students’ understanding of the engineering design processes. Findings show that among the 24 participants, there is a significant increase in students’ self-efficacy beliefs after attending the workshop. We also identified major themes such as design goals and prototyping in students’ understanding of engineering design processes. This research provides insights into the key elements of middle school students’ engineering design learning and the benefits of engaging middle school students in hands-on toy design workshops.     

Strong Students

I am an English teacher at a high school in Mexico. I give classes to several groups from different grades. I have always had a very nice relationship with all my students. Usually this would be considered a good thing,and in most cases it is. Unfortunately in some other cases this can cause students to see me just as another one of their kind.     

Undergraduate Engineering Students’ Beliefs,Coping Strategies,and Academic Performance: An Evaluation of Theoretical Models

Research has identified factors associated with academic success by evaluating relations among psychological and academic variables, although few studies have examined theoretical models to understand the complex links. This study used structural equation modeling to investigate whether the relation between test anxiety and final course grades was mediated by personal control, self-efficacy, goal orientation, coping strategies, and self-regulation. Participants were 297 undergraduate students taking an algebra course designed for engineering students. Results indicated that the proposed theoretical model was supported by the data, although a modified model produced a better fit. Other competing models were also tested. Collectively, analyses revealed that the psychological variables played important roles in predicting students’ grades, as all the structural coefficients and R ² statistics were statistically and practically significant. Findings suggest value in the development and testing of additional models that contribute to the expansion of intervention programs to enhance academic outcomes among students.     

Avoid,Control, Succumb,or Balance: Engineering Students’ Approaches to a Wicked Sustainability Problem

Wicked sustainability problems (WSPs) are an important and particularly challenging type of problem. Science and engineering education can play an important role in preparing students to deal with such problems, but current educational practice may not adequately prepare students to do so. We address this gap by providing insights related to students’ abilities to address WSPs. Specifically, we aim to (I) describe key constituents of engineering students’ approaches to a WSP, (II) evaluate these approaches in relation to the normative context of education for sustainable development (ESD), and (III) identify relevant aspects of learning related to WSPs. Aim I is addressed through a phenomenographic study, while aims II and III are addressed by relating the results to research literature about human problem solving, sustainable development, and ESD. We describe four qualitatively different ways of approaching a specific WSP, as the outcome of the phenomenographic study: A. Simplify and avoid, B. Divide and control, C. Isolate and succumb, and D. Integrate and balance. We identify approach D as the most appropriate approach in the context of ESD, while A and C are not. On this basis, we identify three learning objectives related to students’ abilities to address WSPs: learn to use a fully integrative approach, distinguish WSPs from tame and well-structured problems, and understand and consider the normative context of SD. Finally, we provide recommendations for how these learning objectives can be used to guide the design of science and engineering educational activities.     

A Cross-Sectional Study of Engineering Students’ Self-Efficacy by Gender, Ethnicity, Year, and Transfer Status

This is a cross-sectional study of 519 undergraduate engineering majors’ self-efficacy beliefs at a large, research extensive, Midwestern university. Engineering self-efficacy is an individual’s belief in his or her ability to successfully negotiate the academic hurdles of the engineering program. Engineering self-efficacy was obtained from four variables: self-efficacy 1, self-efficacy 2, engineering career outcome expectations, and coping self-efficacy. The four variables were analyzed using a repeated analysis of variance among levels of gender, ethnicity, years students had been enrolled in their engineering program, and transfer status. No significant differences in mean engineering self-efficacy scores were found by gender, ethnicity, and transfer status. However, significant interactions between gender and the subscales, ethnicity and the subscales, and transfer status and the subscales were found. Significant differences in mean engineering self-efficacy scores were found among years students had been enrolled in the program.     

Examining Elementary School Students’ Mental Models of Sun-Earth Relationships as a Result of Engaging in Engineering Design

Current reform efforts in science education in the United States call for students to learn science through the integration of science and engineering practices. Studies have examined the effect of engineering design on students’ understanding of engineering, technology, and science concepts. However, the majority of studies emphasize the accuracy of students’ scientific thinking instead of what students’ conceptions are. The aim of this study was to examine elementary school students’ conceptions of sun-Earth relationships as a result of engaging in an engineering design-based science task. Two independent fifth grade classrooms were identified. Each classroom teacher had 2 groups of students: 1 group engaged in traditional science lessons (control) and 1 group engaged in engineering design-based science lessons (treatment). Data were collected via multiple choice knowledge assessments, a draw-and-explain item, and semi-structured interviews designed to elicit students’ working mental models of the relationship between the sun and Earth. Results indicated a range of five different mental models expressed by students in both the control and treatment groups. These findings suggest that students still harbor alternate conceptions and possibly conflicting ideas regarding various sun-Earth relationships. If teachers are expected to implement science and engineering practices, attention must be given to not only what students’ misconceptions are but, more importantly, how best to implement design-based science lessons that facilitate students’ application and understanding of related science concepts.     

Harnessing the Environmental Professional Expertise of Engineering Students—The Course: “Environmental Management Systems in the Industry”

More and more technical universities now advocate integrating sustainability in higher education and including it as a strategic goal for improving education’s quality and relevance to society. This study examines 30 fourth-year chemical engineering students, graduates of a university course designed to combine their terminological domain with sustainability-oriented goals, focusing on topics like corporate sustainability, developing environmental policy, introduction to ISO 14001—Environmental Management Systems (EMS), and environmental legislation. The study explores their perception of industrial-environmental issues and asks—How did the study unit influence the students’ ability to use their preexisting scientific knowledge, while relating to industrial-environmental issues? Our findings indicate that engineering students can develop industrial-environmental awareness, and make use of interdisciplinary knowledge beyond that strictly related to the realm of engineering. Regarding the research’s particular aim—i.e. determining the study unit’s influence on students’ ability to relate industrial-environmental issues to their own field of engineering—the findings indeed show a change in the students’ conceptions of environmental elements related to industry. The course graduates became more attentive to the environmental aspects associated with building and opening a factory, and the concepts they raised in connection with the topic gained in variety.     

How do Teachers Prepare for and Respond to Students’ Evoked Emotions when Addressing Real Social Inequalities Through Engineering Activities?

Making engineering and science culturally and socially relevant requires teachers to have broader content knowledge and an increased repertoire of pedagogical skills. One aspect of being an effective and culturally inclusive teacher that is seldom discussed is the ability to engage with the emotions associated with working for social justice. In other words, teachers need to be prepared to address the mixed emotions and desire to effect social change that students (children or adults) often experience when exposed to the very real social inequalities present in their own communities or in the world. This issue is particularly important now that the Next Generation Science Education Standards, and its emphasis on engineering practices, calls for students to engage in more problem solving of real world issues. This article seeks to raise awareness about critical emotional pedagogy and critical emotional literacy as 2 additional tools that are likely to augment teachers and researchers’ professional tool kit when interested in building a culturally inclusive and socially relevant learning environment.     

The ABCs of Students

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