The push for STEM has raised the visibility of engineering as a discipline that all students should learn. With the release of the "Framework for K-12 Science Education" and the Next Generation Science Standards (NGSS), engineering now has an official place in the science curriculum. In both the "Framework" and the NGSS,…

Before leaders in technology education are able to identify a theoretical framework upon which a curriculum is to stand, they must first grapple with two opposing views of the purpose of technology education--education for all learners or career/technical education. Dakers (2006) identifies two opposing philosophies that can serve as a framework…

Engineering students are taught to approach the identification and solution of problems through design education, systems analysis, and other methods. These methodologies are applicable to other disciplines in relating problem solving to real world situations. (SK)

Argues that the changes in the context of engineering requires new approaches within the curriculum and by promoting active learning and encouraging students to experiment and be more creative. eLearning is one of an important number of strategies for achieving the paradigm shift that is required. (Contains 14 references.) (Author/YDS)

Defines and compares project-organized learning and problem-based learning at a theoretical and practical level. Outlines differences and similarities both for institutions practicing and for institutions planning to implement some of these educational ideas. Contains 14 references. (JRH)

Cites the shortcomings of the traditional educational experiences of chemists. Focuses on their training in engineering and concludes that training is lacking in the areas of mass balances in flow processes, heat balances, reactors, separation processes, and scaleup. (DDR)

Discusses the foundations of engineering design and highlights the problems confronting students who are required to make creative input into a design problem. Describes a way to implement creativity in teaching engineering design. Contains 38 references. (DDR)

Defends the role of humanities instruction in the education of engineering undergraduates in the areas of problem solving, risk taking, and the synthesis of metaphors and symbols. (AEA)

The importance of technological literacy in liberal arts education, and approaches to teaching the concepts behind systems analysis and artifacts in engineering, are outlined and discussed. (MSE)

Discusses the use of a computer-illustrated text (CIT) with integrated software to teach electric circuit theory to college students. Examples of software use are given, including simple animation, graphical displays, and problem-solving programs. Issues affecting electric circuit theory instruction are also addressed, including mathematical…

Proposes that there is a universal method for all realms of knowledge. Reviews Descartes's definition of the universal method, the engineering definition, and the philosophical basis for the universal method. Contends that the engineering method best represents the universal method. (ML)

Offers perspectives and specific ways of developing and nurturing critical and creative problem-solving skills with engineering students. Provides examples of exercises and approaches that aim in stimulating creativity and in providing understanding of course material. (ML)

Examines some of the assumptions associated with attempts to define the "engineering method." Critiques a previously stated definition of this method, and offers an alternative definition that attempts to include the ideas put forth in the previous definition. Discusses the use of engineering heuristics in both definitions. (TW)

Explains that European engineering students are not well prepared to integrate socio-economic and environmental issues efficiently into their future professional activities. Argues that necessary changes include a more interdisciplinary and systems-oriented approach to problems and better training in communication skills. Provides an example of an…

In an effort to more clearly define the engineering method, this document attempts to draw distinctions between engineering and science. Part I, "Some Thoughts on Engineering," discusses strategies that engineers employ to solve problems, and the characteristics of the types of engineering problems. Part II, "The Principal Rule of the Engineering…