Provides statistics of 1988 engineering and engineering technology enrollments surveyed by the Engineering Manpower Commission. Presented are tables showing the 10-year trend, enrollment by curriculum, and enrollment by schools for all students. (YP)

Analyzes five intellective and nine non-intellective variables to develop mathematical models to predict freshman success and persistence. Lists and describes the variables. Explores the model's attempts in predicting grade point average and chance of success in an engineering school. (MVL)

National Science Foundation support for instructional innovation in design curriculum is discussed. Programs that illustrate diverse approaches to teaching design are described. A list of programs given engineering curriculum development awards in 1988 and 1989 is provided. (CW)

A professor entered a four-year engineering program together with student volunteers to obtain information on their problem-solving skills. This information as well as information on student characteristics and characteristics of freshmen and sophomore years are discussed in terms of curriculum modification, available resources, and needed changes…

Discusses computer graphics and computer-aided design in the freshman engineering program at the University of Texas at Austin. Procedure uses interactive modules that do not require any programing skills. An annotated test of modules used and suggested approaches that might be useful at other schools are included. (BC)

Describes an attempt on the part of an engineering faculty to develop problem-solving skills in its undergraduate students. It includes a course description in problem solving. (SA)

Discusses ways in which to help students solve problems effectively. On the basis of her observations of novice and expert problem solvers, the author suggests teaching the processes used by the experts directly to the students. (SA)

Describes the work of a curriculum committee established to create a "transfer curriculum" for engineering technology students transferring from two-year to four-year programs. The resulting program (which allows flexibility while providing some guidance for engineering technology programs), transfer problems, issues, and public response…

A procedure where homework assignments are collected, graded, and returned each week is suggested. Students were used to grade each other's homework against copies of the solutions according to criteria established at the beginning of the course. Student response has been positive. (MVL)

Engineering Practices Introductory Course Sequence (EPICS) is designed to introduce freshmen and sophomores to skills of self education and open-ended problem solving so that high levels of competence can be obtained. Rationale for the program, description of theme projects (including management and instruction), and pilot program evaluation are…

This description of a laboratory experience for engineering students emphasizes guided design, a slow-motion experience in decision making of an open-ended problem. (SA)

Introduces two courses for developing relevant computer use in a civil engineering department. The sophomore course introduces students to a set of problem-formulation methods and computer-based problem-solving tools. The senior course introduces students to representative, professional quality computer-aided engineering tools. Discusses impact of…

Discusses the need to integrate management and technology in engineering education programs. Describes the undergraduate management and technology program at the University of Pennsylvania. Outlines both the four-year and five-year options, describing two integrative courses that were developed specifically for the program. (TW)

Describes the engineering education program at the Aalborg University Center in Denmark. Details the aims of the program. Outlines the programs and multidisciplinary departments of the university. Explains how students are grouped around projects. Reviews the evaluation process. Examines the attitudes of students in the program. (CW)

Addresses several concerns regarding the identity of the field of engineering technology. Discusses engineering technology from the standpoint of its designation as a discipline, its body of knowledge, its professional status, its academic faculty, and the structure and policies that will allow it the most options for the future. (TW)