This is a survey paper submitted to the Design in Engineering Education Division (DEED). As a survey paper, it provides a comprehensive review of the literature on the topic of representations between engineering design and engineering analysis. This research aims to characterize the overlap as well as distinctness between engineering design thinking, on the one hand, and engineering model-based reasoning, on the other hand. The 1990s witnessed the rise of a transformative wave to the engineering curricula, where the "engineering science" model became dominant in engineering curricula. In this model, the focus in the first two years of the curriculum is placed on the "engineering sciences," or, alternatively, "analysis," with the expectation that students would apply the learned scientific principles to solve technical problems. However, a segregation problem between "design" and "analysis" started to emerge. The problem was caused not only by lack of appreciation for the complexities associated with design teaching and learning, but also by lack of students' fluency to apply their learned mathematical modeling skills in complex, open-ended design problems. In this paper, we develop a "representations framework" to study the relationship between engineering design thinking and engineering model-based reasoning. It is the focus of this study to understand the role of multiple representations in problem solving, in order to characterize the overlaps and the distinctiveness in the use of the term "representation" in the contexts of mathematical modeling and design processes. Engineering design is a systematic, intelligent process that aims to solve ambiguous problems. In the majority of current engineering education curricula, a major emphasis is placed on the traditional view where prerequisite ideas are taught in decontextualized situations. While students in their courses interact with models in varying contexts, teaching focuses on algorithmic steps to find a solution. In this paper, we develop a framework to understand how representation is described, taught and learned in analysis-focused classes and in design-focused classes.
Introduction-Nature of the problem"Engineers create the world that never was," famously stated Theodore von Karman, comparing engineers with "scientists [who] discover the world that exists" ("Foundation", n.d.). Arriving at Caltech in 1929 coming from Aachen, Germany, he restructured aerodynamics education placing an emphasis on the scientific and mathematical foundation ("JPL", n.d.). Overall, the American engineering education experienced a first transformative wave in the beginning of the 1900s, and especially later after World War II, when American engineering colleges embraced the analytical mode of engineering science (Seely, 1999). The role of European-educated engineers, such as von Karman, Stephen Timoshenko and Harald Westergaard was impactful in transforming the engineering curricula. Westergaard, for example, realized that his mastery of mathematical theories to study concre...