Technology — Electronic Engineering Technology Technology — Electronic Engineering Technology transients, R-C and R-L time constants, gas tubes, electronic reflectors, voltage doublers, and regulators, video-amplifiers, R-C oscillators, and cathode followers. Prerequisite: Electronic Technology 262, and Electronic Engineering Technology 464. Three lectures. S (3) 433. Radar Fundamental Laboratory—Testing and operation of basic circuits studies in Electronic Engineering Technology 432. Two 3-hour laboratories a week. S (2) 434. Radar Systems—Theory of vacuum tube R-C and R-L circuits used as limiters, clampers, peakers, sawtooth generators, multivibrators, and counters; also, cathode ray tubes, transmission lines, wave guides, cavity resonators, and ultra-high frequency generators. Prerequisite: Electronic Engineering Technology 432 or equivalent. (Offered alternate years.) Three lectures. S (3) 435. Radar Systems Laboratory—Testing and operation of basic circuits and subassemblies of radar systems. (Offered alternate years.) Two 3-hour laboratories a week. S (2) 450. Computer Circuits Applications—Application of basic circuits to digital and analog data handling devices. Three lectures. Prerequisite: Electronic Engineering Technology 324 and 355 or equivalent. S (3) 451. Computer Circuits Laboratory—Operation and adjustment of circuits and related control and readout components in computer type devices. Two 3-hour laboratories a week. S (2) 452. Fundamentals of Analog Computers—An introduction to fundamental analog computing circuits, their design and application. Includes integrating, differentiating, summing, multiplying, dividing, and other special computing circuits. Prerequisite: Electronic Engineering Technology 320, 356, or equivalent. Three lectures. W (3) 453. Analog Computer Laboratory—Application of analog computing circuits to actual laboratory experiences. Will include solution of practical problems discussed in lecture. Prerequisite and/or concurrent: Electronic Engineering Technology 452. Two 3-hour laboratories a week. W (2) 456. Principles of Automation—Introduction to methods used in automatic programming and control of industrial equipment. Three lectures. A (3) 457. Principles of Automation Laboratory—Set-up adjustment and operation of small automatic control and programming systems. Two 3-hour laboratories a week. A (2) 460. Theory of Lines and Networks—Transmission line and filter network theory and configurations. (Offered alternate years.) Three lectures. Su (3) 461. Line and Networks Laboratory—Experiments in line and network principles. (Offered alternate years.) Two 3-hour laboratories a week. Su (2) 464. Micro-Wave Techniques—Elementary study of microwave generation and propagating devices; emphasis on phenomena peculiar to micro-wave signals. Prerequisite: Electronic Technology 262. Three lectures. W (3) 465. Micro-Wave Laboratory—Adjustments and test on devices generating and conducting micro-wave signals. Two 3-hour laboratories a week. A (2) 468. Air-Ground Communications—Special circuits and problems relating to air-ground communication. (Offered alternate years.) Three lectures. Su (3) 469. Air-Ground Communications Laboratory—Adjustment and operation of equipment used in air-ground communications. (Offered alternate years.) Two 3-hour laboratories a week. Su (2) 470. Telemetric Principles—Methods and principles used in various types of systems to transfer measurements by wire and wireless. (Offered alternate years.) Three lectures. Su (3) 471. Telemetric Laboratory—Experimental Loops established for the student to become acquainted with telemetric operation. (Offered alternate years.) Two 3-hour laboratories a week. Su (2) 479. Senior Problems—Special problems covering scope of study during the previous four years. Two lectures. S (2) 480. Senior Project—A course designed to give the senior student an opportunity to further his knowledge in an area of electronics or an area related to electronics by choosing and developing a special project or study under the supervision of one or more of the department faculty. Credit to be determined at the time of registration. Prerequisite: Completion of junior year electronics course work or by special permission from the department chairman. A W S (1-3) 318 319