Technology — Electronic Engineering Technology Technology — Electronic Engineering Technology Electronic Engineering Technology Major—The student completing the outlined course is prepared to go into industry in any one of many areas where electronic equipment is involved. Bachelor of Science Degree—Electronic Engineering Technology 154, 155, 156, 101, 102, 107, 108, 163, 164, 179, 180, 181, 182, 185, 186, 189 or equivalent. The student must receive a grade of "C" or better in six major 5 credit hour lecture-laboratory combination classes. Chemistry 5 or 11 or 13; Physics 51, 52, 53, 54, 55, 56, or 61, 62, 63, 64, 65, 66; Industrial Engineering Technology 130, 131, 132; Engineering Graphics 50 and 51; Data Processing 67. Not less than 9 additional hours of upper division course work in Electronic Engineering Technology, Industrial Engineering Technology, Manufacturing Engineering Technology, Mathematics, Education, Business or other approved supporting field. Students graduating with an Electronic Engineering Technology major are not required to take a minor. Electronic Engineering Technology Minor—A student may select Electronic Engineering Technology as a supporting minor. Course work should include 27 quarter hours of credit in Electronic Technology 7 and 8, Electronic Engineering Technology 107, 108, 141, 142, 143, 179, and 180 or equivalent. Additional courses in instrument circuits and instrumentation are recommended. Prerequisites: Algebra and Trigonometry. Courses of Instruction 101. Instruments and Measurements Laboratory—Operation of equipment studied in Electronic Engineering Technology 102. Two laboratories. W (2) Horsley 102. Instruments and Measurements—Basic theory pertaining to the function, operation, application, and adjustment of precision type electronic instruments and devices. Methods employed in industry to obtain precise measurements of electronic and electrical parameters. Prerequisite: Sophomore level electronic course work. Three lectures. W (3) Horsley 107. Transistor Circuits Laboratory—A practical laboratory course to give the student additional understanding of the principles taught in Electronic Engineering Technology 108. The student will compare design theory with practical operational circuits. Prerequisite: Elec. Tech. 8. One laboratory. A (1) Jensen 108. Transistor Circuit Analysis—Analysis of Transistor circuits such as biasing, small signal amplifiers, large signal amplifiers, input characteristics, output characteristics, gain considerations, circuit analysis through the use of equivalent circuits. Prerequisites: Elect. Tech. 7 and 8 or equivalent. Four lectures. A (4) Jensen 111. Telemetric Laboratory—Experimental Loops established for the student to become acquainted with telemetric operation. Two laboratories. Su (2) Urie 112. Telemetric Principles—Methods and principles used in various types of systems to transfer measurements by wire and wireless. Three lectures. Su (3) Urie 127. Electronic Equipment Maintenance—Adjustment and maintenance of electronics equipment such as test equipment and electronic equipment used in industrial applications. Supervised study and shop practice. Prerequisite: Elect. Tech. 75 and 76 or equivalent. W S (3) Wright 128. Electronic Equipment Circuits—Procedures used in maintenance of industrial type electronic instruments and fixtures. Supervised study and laboratory practice. Prerequisite: Electronic Engineering Technology 127 or equivalent. S (3) Wright 131. Radar Fundamental Laboratory—Testing and operation of basic circuits studied in Electronic Engineering Technology 132. Two laboratories. S (2) Harris 132. Radar Fundamentals—Theory of circuits used in radar and television; concepts dealing with non-sinusoidal waves and 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: Elect. Tech. 62 and Electronic Engineering Technology 164. Three lectures. S (3) Harris 133. Radar Systems Laboratory—Testing and operation of basic circuits and subassemblies of radar systems. Two laboratories. S (2) Staff 134. 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 132 or equivalent. Three lectures. S (3) Staff 308 309