A Paradigm for Assessing Conceptual and Procedural Knowledge in Engineering Students

Taraban, Roman; DeFinis, Alli; Brown, Ashlee G.; Anderson, Edward E.; Sharma, Manorma

doi:10.1002/j.2168-9830.2007.tb00943.x

Cited by 38 publications

(36 citation statements)

References 22 publications

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“…The importance of knowing the ways in which conceptual and procedural knowledge interact and contribute to the development of expertise and skills in pedagogical practice has also been widely acknowledged in engineering disciplines (Chi, 2005;Litzinger, Van Meter, Wright, & Kulikowich, 2006;Taraban, et al, 2007).…”

Section: Summary and Implications For The Present Studymentioning

confidence: 99%

“…However, there are at the same time high expectations in terms of analytic and creative knowledge-based skills on engineers in the work force, which speaks to a need of conceptual mathematical knowledge. The issue of conceptual versus procedural understanding understanding is also relevant in other fields, such as thermodynamics (Taraban, Definis, Brown, Anderson, & Sharma, 2007), where research suggests that engineering students strive to develop conceptual knowledge but at low cognitive levels.…”

Section: Introductionmentioning

confidence: 99%

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Conceptual and Procedural Approaches to Mathematics in the Engineering Curriculum: Student Conceptions and Performance

Engelbrecht

Bergsten

Kågesten

2012

J of Engineering Edu

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BACKGROUNDDemands by engineering faculties of mathematics departments have traditionally been for teaching computational skills while also expecting analytic and creative knowledge-based skills. We report on a project between two institutions, one in South Africa and one in Sweden, that investigated whether the emphasis in undergraduate mathematics courses for engineering students would benefit from being more conceptually oriented than the traditional more procedurally oriented way of teaching. PURPOSE (HYPOTHESIS)We focus on how second-year engineering students respond to the conceptual-procedural distinction, comparing performance and confidence between Swedish and South African groups of students in answering conceptual and procedural mathematics problems. We also compare these students' conceptions on the role of conceptual and procedural mathematics problems within and outside their mathematics studies. DESIGN/METHODAn instrument consisting of procedural and conceptual items as well as items on student opinions on the roles of the different types of knowledge in their studies was conducted with groups of second-year engineering students at two universities, one in each country. RESULTSAlthough differences between the two countries are small, Swedish students see procedural items to be more common in their mathematics studies while the South African students find both conceptual and procedural items common; the latter group see the conceptually oriented items as more common in their studies outside the mathematics courses. CONCLUSIONSStudents view mathematics as procedural. Conceptual mathematics is seen as relevant outside mathematics. The use of mathematics in other subjects within engineering education can be experienced differently by students from different institutions, indicating that the same type of education can handle the application of mathematics in different ways in different institutions.

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Section: Summary and Implications For The Present Studymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Conceptual and Procedural Approaches to Mathematics in the Engineering Curriculum: Student Conceptions and Performance

Engelbrecht

Bergsten

Kågesten

2012

J of Engineering Edu

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“…Recently the research community also actively looks into how engineering students learn. For example, there are studies in assessing engineering students' conceptual and procedural knowledge about thermodynamics [3], as well as the investigation into conceptual understanding in graduate-level engineering and mechanics courses [4].…”

Section: Introductionmentioning

confidence: 99%

Assessing students' integrative learning in biomedical engineering from the perspectives of structure, behavior, and function

Chan

2010

2010 IEEE Frontiers in Education Conference (FIE)

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Learning in biomedical engineering is highly interdisciplinary: students need to integrate concepts between engineering and life sciences, and be able to design and develop technologies with physiological considerations. In this study, biomedical engineering students' artifacts were analyzed in detail according to the structure-behavior-framework (SBF) framework. The SBF framework has been investigated by educational researchers and learning scientists; in particular, the behavioral and functional dimensions were proved to be related to a sophisticated level of understanding of complex systems. Existing research results also indicate that experts (or expert-like learners) show a deeper understanding of the behavioral and functional aspects of systems. In the current study, a 5-level scale comprising structural, behavioral, and functional dimensions of integrated learning was constructed to assess student learning in a biomedical engineering project course. Our results indicate that high achievers and low achievers were different in the behavioral and functional dimensions. The results also indicate significant relationships between behavioral and functional dimensions of learning and students' final course performance. These findings align with existing results in cognitive science and learning sciences on expert-novice differences, which help connecting engineering educational inquiries to the rich body of literature and findings in human learning.

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“…Higher thought is likely to be clouded if that foundation is weak, unclear, or misunderstood 15 . When concepts are well-understood, students are often able to explain related problems, make inferences from the problem, integrate other ideas, predict outcomes and apply conceptual knowledge to other areas 17 .…”

Section: Conceptual Knowledgementioning

confidence: 99%

“…The ability to measure conceptions can help engineering educators address misconceptions instead of assuming that concepts are understood, or worse, leaving those misconceptions in place, to possibly influence future learning in a negative way 17 . Misconceptions can make it extremely difficult for students to accept and learn new information, which is why identification of those misconceptions is so important 18 .…”

Section: Conceptual Knowledgementioning

confidence: 99%

Community College Students’ Self-efficacy and Conceptual Knowledge of Circuit Analysis

Whitesel

Carberry²

2015 ASEE Annual Conference and Exposition Proceedings

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A Paradigm for Assessing Conceptual and Procedural Knowledge in Engineering Students

Cited by 38 publications

References 22 publications

Conceptual and Procedural Approaches to Mathematics in the Engineering Curriculum: Student Conceptions and Performance

Conceptual and Procedural Approaches to Mathematics in the Engineering Curriculum: Student Conceptions and Performance

Assessing students' integrative learning in biomedical engineering from the perspectives of structure, behavior, and function

Community College Students’ Self-efficacy and Conceptual Knowledge of Circuit Analysis

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