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 the creation of the computer program "BOUNCE," designed to simulate a weighted piston coming into equilibrium with a cloud of bouncing balls. The model follows the ideal gas law. Utilizes the critical event technique to create the model. Discusses another program, "BOOM," which simulates a chain reaction. (CW)

Points out two areas of difficulty in teaching Newtonian dynamics. Describes several alternatives to physics learning using new technology. Details the use of the LOGO computer language in teaching simple Newtonian environments. Suggests the potential for creating new learning experiences in dynamics with new technology. (CW)

Lists a program for a simulation of Rutherford's gold foil experiment in BASIC for both Apple II and IBM compatible computers. Compares Rutherford's model of the atom with Thompson's plum pudding model of the atom. (MVL)

Presents a ray-tracing procedure based on some ideas of Herzberger and the matrix approach to geometrical optics. This method, which can be implemented on a programmable pocket calculator, applies to any conic surface, including paraboloids, spheres, and planes. (Author/GA)

Discusses approach to integrating computer programing into a calculus-based physics survey college course which stresses three major uses of computers: data reduction, calculation, and simulation. An initial programing exercise and practical constraints--time a student can allot to course and student's level of confidence--are mentioned. (EJS)

Describes techniques in LOGO, which are applicable to A-level and above. The techniques use a dynamic modeling approach, which considers system behavior in terms of state transitions over successive short intervals. Advantages and disadvantages of using LOGO are noted. (JN)

Describes 17 situations in physics which require students to write computer programs to solve. All the projects are general in nature and require students to have a thorough conceptual understanding of the content to apply the algorithm needed to solve the specific type of problem illustrated. (JN)

A problem is detailed which has a solution that embodies geometry, trigonometry, ballistics, projectile mechanics, vector analysis, and elementary computer graphics. It is felt that the information and sample computer programs can be a useful starting point for a user written code that involves missiles and other projectiles. (MP)

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)

Suggests approaches to teaching computer programing and applications to physics instruction. Indicates that the necessity of breaking a problem down into a programable entity ensures that the student will learn programing, logical sequential thinking, as well as physics content. (JN)

Discusses the notion of a musician's workstation and a curriculum for teaching musicians about the use of computers in music. Explains that the curriculum includes elements of physics and psychoacoustics, recording arts and sciences, the philosophy of technology and the musical arts, analog and digital electronic music, ergonomics, and computer…

Suggests that students can learn the physics of a musical note by learning how to synthesize sounds on a computer. Discusses ADSR (attack, decay, sustain, and release of a note) and includes a program (with listing) which students can use to examine ADSR on a Commodore 64 microcomputer. (JN)

Describes how certain concepts basic to electron optics may be introduced to undergraduate physics students by calculating trajectories of charged particles through electrostatic fields which can be evaluated on minicomputers with a minimum of programing effort. (Author/SA)

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)