Discusses algebraic programing languages, availability of these languages, and programing problems. Also discusses the future of these languages in chemical research and chemical education. A program illustrating the general algebraic and algebraic matrix manipulating capabilities of the REDUCE language is included. (JN)

Provides instructions for "seeding" the random number generator (RND) in Apple computer programs. If RND is not seeded, students would see the same examples, questions, graphics features, or other information each time they turn on the microcomputer and run a program. (JN)

Explains the attributes of a good laboratory language and the advantages and disadvantages of specific computer languages such as Forth, Pascal, C, APL, BASIC, and Fortran. Attributes considered focus on user/computer, instrument/computer, and user/user communication. (JN)

Explained and presented is a short GW/BASIC computer program that uses an iterative algorithm for the automatic calculation of equilibrium concentrations for an arbitrary number of reactants and products within a chemical reaction. (JJK)

Discusses topics and issues related to (1) international impact of microcomputers; (2) minimum guidelines for software development; (3) achieving minimum standards; and (4) accomplishments in the areas of introductory chemistry, organic chemistry, analytical chemistry, and physical chemistry. Challenges for the future are noted. (JN)

Presented are sources of information on a wide range of topics related to microcomputers in general and chemistry in particular. Sources described include "Journal of Chemical Education,""Collegiate Microcomputer,""SIAM News,""Creative Computing,""Byte," and others. Types of articles/information found in these publications are briefly considered.…

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 two uses for the programmable calculator in the freshman chemistry laboratory: as a means of determining whether or not a student's raw data from a laboratory experiment fall within acceptable tolerance limits; and as a means of checking the reliability of unknowns and grading on quantitative experiments. (MLH)

Following a discussion of how computers are used to solve chemical problems, offers suggestions for avoiding common problems, reviews successful applications and languages (BASIC and FORTRAN), speculates on future trends, and discusses why chemists need to know about computers. (SK)

Describes six crystallographic programs which have been developed to illustrate the range of usefulness of programmable calculators in providing computational assistance in chemical analysis. These programs are suitable for the analysis of x-ray diffraction data in the laboratory by students. (HM)

Describes the development, content, and implementation of a two-credit graduate course for teachers at the University of Wisconsin at Stevens Point in the use of microcomputers for teaching high school chemistry. (JJD)

Suggests a model of human cognition by describing similarities between human and electronic computers. This model might guide the development of software so that it is sufficiently powerful and flexible to be of value to human computers as they construct new knowledge in chemistry. (JN)

Highlights four workshops held at the Seventh Biennial Conference on Chemical Education (Stillwater, Oklahoma 1982). Workshops focused on microcomputer tools for chemists, writing software for microcomputers, Project SERAPHIM instructional computer programming contest, and preparing three-dimensional photographs of models and structures. (JN)

Describes the design, construction, administration, and results of networked campuswide placement testing for mathematics and chemistry at Stanford University. Reasons for online testing are discussed; software requirements and programing details are explained; and the impact on students and their advisors is considered. (Contains seven…

Uses of Zenith Z-100 microcomputers by chemistry students at Clarkson College are discussed. These include: (1) programing; (2) word processing; (3) numerical methods, statistical/plotting programs; (4) laboratory data acquisition and manipulation; (5) simulations; (6) computer assisted instruction; and (7) computer managed instruction. (JN)