Using a Problem-Solving Heuristic to Teach Engineering Graphics

Kimmel, Shari J.; Deek, Fadi P.; Kimmel, Howard

doi:10.7227/ijmee.32.2.5

Cited by 9 publications

(8 citation statements)

References 3 publications

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“…Kosse and Senadeera stressed on the importance of hand-drawing and tolerancing instead of limiting the students to AutoCAD or one of the solid-modelling packages. On the other hand, if the support of modern aids like virtual reality techniques are adopted in engineering drawing, then it paves way for improvement in understanding of the subject (Romero, Maroto, Martínez, & Félez, 2007) (Kimmel, Deek, & Kimmel, 2004) . Kimmel , 2017).…”

Section: Introductionmentioning

confidence: 99%

Fostering Higher Order Thinking Skills in Engineering Drawing

Sharma¹,

Murugadoss²,

Rambabu³

2020

Journal of Engineering Education Transformations

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Engineering drawing is a basic engineering course, which is popularly remembered as the language of engineers and finds the applications in all the domains of engineering as well as architecture. And now due to the intervention of computing facility, it gained further momentum in the field of engineering and technology. This paper traces the development of higher order thinking (HOT) skills in the field of engineering drawing. This paper makes an attempt in proposing distinct platforms for inculcating higher order thinking skills among the engineering students, which further enables them to achieve their highest potential and prepare them to propose solutions for the real world problems. Spatial visualization coupled with an intensive practise in free-hand sketches and manual drafting which is slowly dwindling in today's era of computerization, is proposed for improving HOT skills in the domain of engineering drawing. Students' understanding of the engineering drawing course has registered a substantial improvement and is recorded in the assessment performed.

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Section: Introductionmentioning

confidence: 99%

Fostering Higher Order Thinking Skills in Engineering Drawing

Sharma¹,

Murugadoss²,

Rambabu³

2020

Journal of Engineering Education Transformations

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“…Scholars argue that the tasks assigned in DBEL models should be authentic, open-ended, challenging, and multidisciplinary (Kimmel et al, 2005;Lee et al, 2010;Zhan and Porter, 2010). On the one hand, such tasks should link teaching scenarios, teacher instruction, and student learning in the classroom with real engineering situations.…”

Section: Dbel and Engineering Learning Outcomesmentioning

confidence: 99%

“…Others regard it as a teaching tool for educators to assign challenging tasks and create an interactive environment for students to recall and repeatedly practice what they have learned (Johri and Olds, 2011;Polishetty et al, 2014). DBEL has also been conceptualized as a new approach in which students design specific models using a priori experience and learning, cyclically designing and revising these models and acquiring new knowledge in the process (Kimmel et al, 2005;Lee et al, 2010). DBEL has been framed as a collaborative and optimized model of engineering learning in which students continuously analyze and design existing engineering technology systems and improve their quality, functionality, cost, and price to obtain significant improvements in product performance (Polishetty et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

The study of the effectiveness of design-based engineering learning: the mediating role of cognitive engagement and the moderating role of modes of engagement

Wei,

Zhang,

Lin

2023

Front. Psychol.

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AimDesign-based engineering learning (DBEL) offers a potentially valuable approach to engineering education, but its mechanism of action has yet to be verified by empirical studies. Accordingly, the present study aimed to establish whether DBEL produces better learning outcomes, thereby building a strong, empirically grounded case for further research into engineering education.MethodsTo build a more comprehensive model of design-based engineering learning, the variables of cognitive engagement (the mediator) and modes of engagement (the moderator) were introduced to build a theoretical process model. Questionnaires and multiple linear regression analysis were used to verify the model.Results and discussionAll four features of DBEL (design practice, interactive reflection, knowledge integration, and circular iteration) were found to exert significant and positive effects on learning outcomes. Moreover, cognitive engagement was found to both fully and partially mediate the relationships between these features and the outcomes of engineering learning; under two different modes of engagement, the positive effects of the learning features on cognitive engagement differed significantly.ConclusionThe paper concluded the following: (1) a design-based learning approach can enhance engineering students’ learning outcomes, (2) cognitive engagement mediates between design-based engineering learning and learning outcomes (3) a systematic mode of engagement produces better learning outcomes than a staged modes of engagement.

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“…Commonly, asking questions during different project implementation phases are employed to model and apprentice learners through the more complex parts of the design such as the process of scoping the problem, inquiring and troubleshooting (Chang et al 2008;Etkina et al 2006;Roberts 2001;van Til et al 2009). In addition, problem-solving heuristics such as formulating problem, planning and designing the solution, and testing and delivering the solution, have yield positive results in assisting Behrens et al (2010), Chang et al (2008), Cheville et al (2005), Chinowsky et al (2006), Hirsch et al (2001), Jacobson et al (2006), Kimmel and Deek (2005), Kimmel et al (2003), Linge and Parsons (2006), Macías-Guarasa et al (2006), Martínez Monés et al (2005, Maase (2008), Massey et al (2006), McMartin et al (2000, Mese (2006), Nonclercq et al (2010), Ringwood et al (2005), Roberts (2001) Multidisciplinary Integration of content from different disciplines Teachers/expertise form different disciplines involve in project Kundu and Fowler (2009), Macías-Guarasa et al (2006), Nonclercq et al (2010), Selfridge et al (2007) learners in learning to design. Other examples of scaffolding students' gaining content knowledge include on-line quizzes, discussions (Cheville et al 2005;Maase 2008), worksheets with questions or the use of a solution plan (Etkina et al 2010;Kimmel and Deek 2005;Lyons and Brader 2004).…”

Section: Role Of the Teachermentioning

confidence: 99%

“…In the same line, a number of studies emphasize that weekly questionnaires of on-line quizzes become a flexible assessment method by which the material presented in lectures and lab during the week can be easily tested (Macías-Guarasa et al 2006;Martínez Monés et al 2005;Massey et al 2006;Nooshabadi and Garside 2006;Chang et al 2008;Cheville et al 2005). The added value of the formative quizzes is that, as scaffolding method, it helps students understand concepts and theories involved in the problem to be solved (Kimmel and Deek 2005).…”

Section: Assessmentmentioning

confidence: 99%

A sampled literature review of design-based learning approaches: a search for key characteristics

Puente

Eijck

Jochems

2012

Int J Technol Des Educ

100

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Design-based learning (DBL) is an educational approach grounded in the processes of inquiry and reasoning towards generating innovative artifacts, systems and solutions. The approach is well characterized in the context of learning natural sciences in secondary education. Less is known, however, of its characteristics in the context of higher engineering education. The purpose of this review study is to identify key characteristics of DBL in higher engineering education. From the tenets of engineering design practices and higher engineering education contexts we identified four relevant dimensions for organizing these characteristics: the project characteristics, the role of the teacher, the assessment methods, and the social context. Drawing on these four dimensions, we systematically reviewed the state-of-the-art empirical literature on DBL or DBL-like educational projects in higher engineering education. Based on this review we conclude that DBL projects consist of open-ended, hands-on, authentic and multidisciplinary design tasks resembling the community of engineering professionals. Teachers facilitate both the process of gaining domain-specific knowledge and the thinking activities relevant to propose innovative solutions. Teachers scaffold students in the development from novice to expert engineers. Assessment is characterized by formative and summative of both individual and team products and processes and by the use of a variety of assessment instruments. Finally, the social context of DBL projects includes peer-to-peer collaboration in which students work in teams. The implications of these findings for further research on DBL in higher engineering education are discussed.

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Using a Problem-Solving Heuristic to Teach Engineering Graphics

Cited by 9 publications

References 3 publications

Fostering Higher Order Thinking Skills in Engineering Drawing

Fostering Higher Order Thinking Skills in Engineering Drawing

The study of the effectiveness of design-based engineering learning: the mediating role of cognitive engagement and the moderating role of modes of engagement

A sampled literature review of design-based learning approaches: a search for key characteristics

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