Strategies for incorporating a calculator made within FORTRAN programs and a Response Analysis Scheme during interactive sessions are described highlighting salient features of the programs. (Author/SK)

Suggests that programing can bring about an understanding of several biological concepts which, because of their arithmetic implication, are often considered to be difficult. Population growth is used to illustrate the proposal, in which computing and the study of the topic are integrated. (Author/JN)

Discusses what is meant by a linear program and states and illustrates two of the theorems upon which the methods of linear programing rest. This description is intended as an introduction to linear programing of physics students. (HM)

Describes an easily constructed, small laboratory computer that can be programed in BASIC. The computer is easy to use with analog to digital and digital to analog converters so that it can serve as a control or data logging computer. (Author/JN)

Describes an approach to teaching interactive computing for physics students beginning with the use of BASIC and video terminals during the first year of study (includes writing solution programs for practical problems). Second year students learn FORTRAN and apply it to interpolation, numerical integration, and differential equations. (JM)

Describes physics experiments (including speed, acceleration, and acceleration due to gravity) in which students write programs to obtain and manipulate experimental data using the Atari microcomputer game port. The approach emphasizes the essential physics of the experiments while affording students useful experience of automatic data collection.…

Describes a student programing project using microcomputers in an engineering design course. Provides some instructional procedures and student feedback from the project. (YP)

Describes a course (Introduction to Numerical Techniques of Physics) which can be adapted to such courses as applied mathematics, numerical analysis, mechanical or electrical engineering, chemistry, and biomathematics. Course goals (including emphasis on the distinction between computing, programming and coding) and instructional strategies are…

Discusses the possibility of having chemistry students do their own computer programing that could then be used to solve problems in general chemistry. Describes such an effort at Eastern Washington University. Provides examples of some of the student programs and printouts. (TW)

Lists a BASIC program which computes the equilibrium constant as a function of temperature. Suggests use by undergraduates taking a one-year calculus-based physical chemistry course. Notes the program provides for up to four species, typically two reactants and two products. (MVL)

Discusses programs to provide a knowledge base and use the knowledge in a mode of artificial intelligence. Indicates that two methods of database storage are possible and opts to use a method using many data files while using a small RAM capacity. Lists several programs. (MVL)

Describes two computer programs used to aid in data analysis: (1) Develops a method for the propagation of error involving the direct calculation of the error in the dependent variable using a spreadsheet; (2) Examines a simple numerical method for solving complex equilibria. Lists a FORTRAN 77 program. (MVL)

Discusses a research project that uses artificial intelligence techniques to help teach programing. Describes principles and implementation of the LISP Intelligent Tutoring System (LISPITS). Explains how the artificial intelligence technique was developed and possible future research. (MVL)

Presents examples of didactic computer software developed in a college of engineering, along with a discussion of pedagogical and systems considerations. Discusses the use of the computer in relation to Bloom's Taxonomy. Describes the system approach, which is used to sequentially develop valid and relevant software. (TW)

Computer graphics was selected as the means of teaching students to use the computer as a tool to enhance their comprehension of scientific and technical principles. Discusses strategies used and provides examples of student-generated graphics in mathematics, chemistry, physics, and engineering mechanics. (JN)