Examines three broad areas related to the formal learning of engineering. These areas focus on: (1) approaches to learning; (2) developing engineering curricula; and (3) curriculum planning for the future. Also considers whether current engineering curricula can accommodate needed changes. (JN)

Reports on one technical institution which awards a B.S. in science degree when a student can display competencies in selected fields of engineering and a project which interrelates the problems of society with technology. This latter requirement, the interactive qualifying project, and the development of the program from the historian's point of…

Two instructional methodologies are described in this article: (1) a case study approach is advocated for the relevance and motivation it provides, and (2) a lecture and group study approach in which behavioral objectives must be met. (CP)

A methodical approach to teaching that can be used with almost any class style and with any instructional media is described. Planning courses, designing a syllabus, teaching strategies, the use of office hours, test construction, and personal interaction with students are discussed. (KR)

Analyzes a traditional and an innovative course in terms of learning principles, involving Erickson's management methods and Gagne's learning activities. Suggests that learning systems should be designed by applying all principles rather than emphasizing one or two of them. (CC)

Supports a program format in which engineering is integrated with other subjects in order to displace the public's misconceptions of engineers. Offers program guide along with a funding-formula to distribute the cost of such a multidisciplinary approach in a university setting. (CP)

Discusses the development of a design task in which the students can focus on problems in some part of the city. Describes such an improved strategy for teaching the design of complex systems as challenging and beneficial, especially for those interested in urban-related careers. (CC)

Approaches the study of failure analysis by examining the mental and physical steps involved in the development of a product to determine where the failure occurred. (CP)

Presented is a blueprint for restructuring the first two years of the engineering curriculum. Four new concepts for the first two years are discussed: (1) the mathematical and scientific foundations of engineering, (2) fundamentals of engineering, (3) the engineering laboratory, and (4) the professional and personal enrichment program. (MVL)

Discusses the restructuring of the graduate program to accommodate emerging fields in engineering. Notes half of the graduate degrees Cornell grants each year are M.Eng. degrees. Offers 12 specialties: aerospace, agriculture, chemical, civil, electrical, mechanical and nuclear engineering; computer science, engineering physics; geological…

Discusses a two-year masters program; one year of lecture and practical training, and a second year on a supervised design task in an industry or development laboratory. Reviews the emphases of the curriculum. Describes the two paths to engineering careers in the Netherlands. (MVL)

Expresses the opinion that education has overemphasized the written word and needs to move back to the oral tradition. Warns that Americans are trained to use the left brain whereas much of engineering needs right brain processing. Gives perspectives to improve engineering education. (MVL)