resources.In addition to fulfilling the course requirements for the STEM education Ph.D. curriculum, thisseries of meetings helps build community among the students and faculty members. It providesan opportunity to share insights and experiences while having faculty members present to helpguide processes and discussions. A goal is to create a strong foundation of collaboration that willtranscend the course and continue beyond its requirements. As students progress in theirrespective research, this course can provide a venue to continually give back to the program.This paper will provide a reflection on the experience of three STEM education Ph.D. studentswho participated in the redesigned seminar course. STEM education students who participated inthe
involves active teaching pedagogy, which many educators may be unfamiliarwith and hesitant to adopt. The increasing popularity of engineering design courses inundergraduate programs reflects a broader response to industry demands and calls foreducational reform from education and professional organizations [3]-[5].The pedagogical goals of incorporating making and design activities into the curriculum aremultifaceted. These activities aim to enhance problem-solving skills, foster creativity, andencourage teamwork among students. Engineering design courses, particularly senior capstoneprojects, provide students with opportunities to apply their knowledge of the engineering designprocess to create discipline-related artifacts. Freshman design courses
Boomer is a graduate student completing his master’s degree in aerospace engineering at the University of Michigan. His focus in engineering education research has been towards bridging the gap between the undergraduate engineering curriculum and engineering industry practice.Cindy Wheaton, University of MichiganDr. Aaron W. Johnson, University of Michigan Aaron W. Johnson (he/him) is an Assistant Professor in the Aerospace Engineering Department and a Core Faculty member of the Engineering Education Research Program at the University of Michigan. His lab’s design-based research focuses on how to re-contextualize engineering science engineering courses to better reflect and prepare students for the reality of ill-defined
urgent call to action. To encourage thrive to learn and delve intoaction, a gamified reflective and immersive process would be more sought by learners instead ofreviewing the definition of goals and their description without any tangible practice. To do so, TheYork University SDG Uphold (YU-SDG-UP) app was designed to immerse students into a worldof those scenarios, where their responses are recorded and graded on an impact scale. This providesan interactive approach which is certain to influence the user’s understanding of the SDG, andtheir attitude towards a sustainable, inclusive, diverse, and equitable future. This is accomplishedthrough developing a mobile application hosting a virtual world with a global health score, wherethe user
, university programs inconstruction engineering must adapt to meet the current and future job market demands. Theresults will not only identify specific AI competencies deemed vital in the constructionindustry, per the perspectives of the interviewed professionals and experts, but also provideactionable insights into how these skills can be developed and integrated into the industry,enhancing project efficiency and quality. The analysis of semi-structured interviews withindustry experts reveals a labor market that highly values critical reflection, ethical principles,interpersonal and management skills, technical mastery in programming, data analysis,mastery of emerging technologies and construction-related software, English, andcybersecurity
] and some well-intentioned trainingsexacerbating the problem of bias [16]. In turn, many campuses moved to embracing student-centered pedagogies. Tools and resources, such as the “Advancing Inclusion and Anti-Racism inthe College Classroom: A rubric and resource guide for instructors” [17] and “Toward anantiracist engineering classroom for 2020 and beyond: A starter kit,” [18] were developed to helpfaculty reflect on their identity and positionality, consider their students’ lived experiences, andmove toward anti-racist pedagogy, assessments, and inclusive teaching practices.Within our department, there was a strong desire to make lasting changes to the culture andcurriculum. These efforts were driven by our graduate students with support from
pathway toexplore and pressure test new ideas and ventures, understand systems, network and practicallybuild and foster resilient organizations and communities. Fellows receive stipends, training,mentoring and opportunities to field test their ideas and ventures over their entire college career.Fellowship outcomes are assessed through coded analysis of student reflections and applying theEntreComp entrepreneurial competency framework. This paper suggests that the fellowshipeffectively helps students develop and field test creative vision, cultivate greater self-awarenessand intrinsic motivation, take thoughtful risks, overcome challenges, and nurture teams andcollaborative environments while birthing impactful new ventures and bolstering their
, we developed the Plug -n- Play approach, a flexiblepedagogical approach which ensures instructors have a fixed core structure, flexibility inleveraging their own teaching style, and a mechanism for constant reflection which allows foradaptations to the course structure over time. The PNP approach focuses course design around thestudent experience, while acknowledging and supporting individual teaching styles and teachingmethods.To assess PNP, a classroom observation protocol was developed to evaluate student engagement,as well as examination of sixteen sections worth of grades and student evaluations. The resultsshow that students are highly engaged with the course material, peers in the class, and theinstructors. Finally, the PNP approach
preparing learners todevelop scripts and action plans for acting consistently with their values in ethically challengingscenarios. The approach moves away from discussing what the right action would be accordingto different ethical normative frameworks, and instead starts from the premise that most peopleare able to recognize the right course of action that is consistent with their values, and want topursue it; however, they have difficulties acting accordingly. Central to this learning model is theapplication of a thought experiment framed as: “Assuming I know what I want to do to act onmy values, how can I get it done?” The capacity to bridge the space between decision and actionis strengthened by reflection about past experiences and each
, several barriers toimplementing these types of frameworks exist. First, many engineers continue to hold atraditional, hierarchical view of leadership and thereby may resist the notion that engineering is aleadership profession [7], [8]. Additionally, while many opportunities to gain experience exist,support is needed to provide students with more meaningful development through intentionalengagement and reflection [9]. Providing a comprehensive framework for competencydevelopment faces many challenges, including lack of shared curriculum across engineeringmajors, lack of faculty expertise or commitment to leadership development [10], difficultyimplementing efforts at scale, and misconceptions that leadership is a field best suited for studentsin
conclusions or recommendations expressedin this material are those of the authors and do not necessarily reflect the views of the National Science Foundation orother funding sources.clinician with expert knowledge. But, what is the benefit received by the need-knower for sharingtheir expertise? While some students may produce a usable artifact and deliver it to theneed-knower, others may not. In some assistive device design classes, there may be noinstructional requirement for producing a working artifact delivered to the need-knower at the endof term at all – we call this an education-first approach. While some need-knowers may be awareof this potential outcome, others may be disappointed by the lack of follow-through.Unfortunately, in talking with
Recitation sessions – Methodology November 5 Methodology Due 100 December 1, 2023 Mid-Term Project Reflection 25 December 1, 2023 TOTAL 500 TABLE 3 SPRING – CAPSTONE II Point Description Due Date s Recitation Session - Data Analysis / Solutions / December, January ROI
in college and beyond. The EcologicalValidation Model of Student Success and its educational practices reflecting the social evolutionframed this study. Information was collected through surveys and interviews from three studentcohorts. The findings revealed how this culturally asset-based program reinforced the identity ofstudents as Hispanics by centering culture and community aspects that students were familiarwith, promoted teamwork with peers as a strategy to make learning better situated in theirinterest to support each other, and contributed to creating a research space where students feltintegrated, included, and valued considering who they were or represent. Programs that center onstudent asset-based features and pedagogical
Paper ID #42409Exploring Variance in Undergraduate Research Participation: A Quantitativeand Qualitative Investigation among Students with Differing Levels of InvolvementDr. Andrew Olewnik, University at Buffalo, The State University of New York Andrew Olewnik is an Assistant Professor in the Department of Engineering Education at the University at Buffalo. His research includes undergraduate engineering education with focus on engineering design, problem-based learning, co-curricular involvement and its impact on professional formation, and the role of reflection practices in supporting engineering undergraduates as they
, communication, critical thinking, and problem-solving within thecontext of robotic competitions.Furthermore, diverse themes in annual robotic competitions facilitate project-based learning(PBL) opportunities tailored to children of varying ages. PBL can serve as an effective vehicle tofacilitate student-driven knowledge acquisition, skill practice, and reflective inquiry. Thecombination of PBL and hands-on robotic competition empowers a promising direction that cango beyond traditional educational models, making STEM fields accessible and appealing to K-12students. It has been reported that students who gain technical skills in high school are betterprepared for both the job market and higher education opportunities [15-17]. Additionally, whenstudents
that these events are deeply embedded in the intersectionalidentities of the authors and these accounts may not necessarily translate to other individualsundergoing similar situations. Also, because these challenges are layered, complex, and situatedin the authors’ intersectional identities, the findings may include multiple systemic barriers thatare intertwined in the interpretation of the findings. The authors opted to maintain the complexityof the narration as it was deemed more authentic to their lived working and personal realities.Further, the multilayered complexity in the narrative demonstrates the levels of cognitive loadand role strain associated with each presented challenge, subsequent reflection/decision, andperceived outcome. The
, students design their egg protection device, convert the model to machinecode, print their structure and finally load test it. Reports are required at the end of each phase,and a summary presentation is made to the entire course at the end of the project. This projectaims to improve several student outcomes such as experimental design and analysis, research ofnew technology, and communication. Initial student reflections were collected at the end of theproject and are presented here. By intertwining contemporary technology with traditional coursestructures, we aim to reinforce the design thinking of students while providing hands-onexperience with an emergent technology.Keywords:Integrative design course, Additive manufacturing, 3D printing with
, 1971). By acquiring multiple sources of information about the sameevent occurring in a social setting, researchers can integrate and triangulate these data, enhancingthe analysis’ depth and accuracy. Therefore, in this research project, the researcher engaged inextensive first-hand observation in classroom settings throughout the semester, collectedstudents’ written responses reflecting their class, and conducted open-ended interviews designedto validate our findings with students’ perspectives. Second, investigations of instructors’ pedagogical practices in naturalistic settings, versusin a laboratory or through lab-based experiments, can yield different findings (Le Compte &Goetz, 1982). Indeed, identifying instructor’s
on the use of waste plastics in asphalt pavements and the technical outcomes of thatresearch. Second, we present a reflection from the three undergraduate students involved in thisexperimental research, including their main motivations to engage in the URE, their learningoutcomes, and the impact of URE in their career trajectories. Accordingly, two major goals anddeliverables are included in this paper:Goal 1: Pratical Research Application: Exploring Waste Plastic in Sustainable Infrastructure • Present student-led literature review and provide a comprehensive background on the use of waste plastic in infrastructure development. • Discuss the specific research methods employed, including experimental design and material
supportsustainability-focused projects. The evolution of the IE curriculum at QU reflects a commitmentto producing engineers equipped to address the complex challenges of a sustainable future.IntroductionThis work-in-progress manuscript discusses ongoing efforts to integrate a strong focus onsustainability and societal impact into the Industrial Engineering (IE) program within the Schoolof Computing and Engineering (SCE) at Quinnipiac University (QU).QU, a private institution located in the northeastern United States, boasts a comprehensiveacademic structure encompassing nine distinct units, including SCE. Notably, sustainabilityfeatures prominently in QU's strategic plan [1][2]. A dedicated sustainability committee drivesvarious campus-wide initiatives, and
phases: planning, monitoring, control, and reaction andreflection [3], [8]. The planning phase involves planning for the problem such as guidingquestions, making a concept map, or planning ahead as seen in [1, Tab. 1], [3]. The monitoringphase could have diagrams, prompts for self-explanation or reasoning, or cognitive feedbackdone by the student [3], [12]. In the control phase, there could be worked out examples,processing and reflective prompts, or guiding questions [3], [10]. Lastly, in the reflection phase,students reflect on the learning they’ve done [3], [13]. As previously mentioned, effectivescaffolds can be both domain-general and domain-specific in each phase. In the context ofcomputer-based learning environments, or CBLEs, prompts
, the stretching of the hands through awindow on a cold morning is used to gauge the weather condition. African educators who wantto enact CSP should consider observations of their students of paramount importance. Thisemphasis is rooted in cultural (i.e., African) perspectives and aligns with the paradigmaticapproach of CSP, promoting observation as a way of knowing. 11. Reflects on Teaching Practices The ability of teachers to self-reflect on teaching practices is an essential component of the CSPframework [13]. By reflecting on their instructional practices, teachers examine their actionswithin the classroom and the underlying philosophies and beliefs that power their decisions andactions. This critical reflection can then improve
correctly while only two managedto determine the weight of the plate correctly. Several students referred to using tabulated data orsimpler shapes in other courses to find the centroid and this lack of practice with equations beinga barrier to success in solving the problem used in this study which does not use a simple shape;“So you have areas which you can find by, by just like simple shapes. And then those have likeknown centroids. And then you can just do sum of centroid times area divided by sum of area forthis because your thing is modeled by an equation, you can't do that. So my dilemma now isremembering the formula.”(5) Solution Evaluation; the only student to obviously display reflective and evaluative practicewas the individual who
brainstorm and research extensively, allowing for a freeflow of creative ideas without immediate constraints. The Explain phase then guides students tosynthesize and articulate their findings, akin to defining a clear problem statement in design thinking. Theprocess continues with the Elaborate phase, where students develop tangible solutions or prototypes,reflecting the prototyping stage in design thinking. This hands-on approach encourages the practicalapplication of their ideas, emphasizing testing and refinement. Finally, the Evaluate phase mirrors thetesting phase in design thinking, where students assess the effectiveness of their solutions and gatherfeedback. This not only allows for reflection but also encourages iterative improvement, a
objectionable or estimable, or simply, “who benefits and whopays” [2], these published reflections could be useful for institutions considering similarinternational humanitarian trips to better prepare their students and encourage reflective practices.This article is divided into three sections: (1) background information on the experience, authors,and terminology in international humanitarian trips, (2) benefits for students and community, and(3) reasons to question participation.Background InformationTo provide context for the resulting discussion, this section contains a description of theinternational humanitarian trip, a land acknowledgement and positionality statement, and adiscussion on common but not synonymous terms for humanitarian
with decisions and specifications rooted in that context [21]. Storiesand reflection have been used to develop engineering literacy through contextual awareness forsociotechnical problem solving [22], [23], [24] and creative engineering skill building morelargely [25], [26]. Given this, having stories that are useful for students, faculty, and evenpractitioners to reflect on barriers and promoters of divergent thinking in engineering may helpfoster encouraging environments, provide contextualized support and resources, and be aneducational tool for more creative outcomes.MethodsThe goal of this work was to describe in depth and contextualize barriers and facilitators ofdivergent thinking for one engineering student. We selected one student to
the center since its launch and our progress after twoyears of operation with the help of tutors. We also present the formation of a tutor network,which is designed to be diverse in terms of academic background and culture. An evaluation ofthe impact of our approach on makerspace diversity, inclusion, and equity is presented throughthe analysis of statistics and reflections from the tutors involved in the initiative. The studyshows that our proposed tutor network can effectively serve as a role model for fosteringdiversity, equity, and inclusion in academic makerspaces for undergraduate students.BackgroundThe University of Hong Kong's Faculty of Engineering has established the Tam Wing FanInnovation Wing [1], also known as the HKU Inno Wing
engineering reviewed the survey andprovided feedback on survey questions regarding their relevance, wording, and inclusion. Inaddition, we piloted the survey, and over 50 students from the researched university respondedand provided feedback on the pilot version. The final survey was administered in February andMarch 2023. It was distributed to all students at the Faculty of Engineering through theUndergraduate and Graduate Dean's offices, students' affinity groups, the CommunicationOffice, the Faculty social media and newsletter, and informal students' social media channels.For this study, we only worked with independent variables reflecting students’ demographicfactors, examining how these factors could have influenced their decision-making
engineering course, were asked tocomplete two poems throughout the semester-long course. The students were asked to constructpoems around a concept, model, or topic covered in the course: the first poem was focused ondeterministic inventory modeling and the second poem was focused on stochastic inventorymodeling. After each technical poem writing assignment, students were asked to respond toseveral open-ended questions detailing their experience and attitude towards these creativewriting assignments. Data was collected during the semesters Fall 2022 and Spring 2023 and ofthe 84 total students over the two semesters, 64 consented to participate in the study. Theparticipant responses to reflection prompts were analyzed qualitatively using open and
cannot be a prerequisite for ABC 101 because then there would be no way to takeeither of them. This makes the graph abstraction both directional and acyclic. Within this representation,the number of credits for each course is reflected by the node size. The course level graph abstraction can allow for the scheduling of one’s term and visualizing howcourses interact with one another. However, these dependencies rely on the accuracy of the prerequisiteswhich could have been established years prior and the courses and, more broadly, the curriculum couldhave changed since. For example, students may be encouraged by their adviser to take ABC 103 and ABC104 in the same term. From the graph abstraction, this need is not clear perhaps because ABC 103