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Show Technology Electronic Engineering Technology 345. FCC License Examination Study (2) Material covered in the Federal Communications Commission 2nd class commercial license examination. Two lectures. Prerequisite: Electronic Technology 212 or equivalent. A 346. FCC License Examination Study (2) Material covered in the Federal Communications Commission 1st class commercial license examination. Two lectures. Prerequisite: Electronic-Technology 212 or equivalent. W 354, 355, 356. Calculus for Electronics (3-3-3) Concepts and applications in differentiation and integration as used in electronics. Prerequisite: Related Technical Education 118 or equivalent. Three lectures. A W S 389. Cooperative Work Experience (1-9) Open to all third year students in Electronics Engineering Technology. A continuation of Electronic Technology 289. A W S Su 422. Microelectronics and Integrated Circuits (4) Fundamentals pertaining to design principles for monolithic, hybrid, multi-phase, and thin film circuits. Fabrication principles. Prerequisite: Electronic Engineering Technology 320 or equivalent. Four lectures. A 423. Microelectronic and Integrated Circuits Laboratory (1) Testing and assembly procedures used with micro-miniature circuit modules. One 3-hour lab a week. A 432. Radar Fundamentals (3) Theory of circuits used in radar and television: Prerequisite: Electronic Technology 262 and Electronic Engineering Technology 464. Three lectures. S 433. Radar Fundamental Laboratory (2) Testing and operation of basic circuits studies in Electronic Engineering Technology 432. Two 3-hour labs a week. S 434. Radar Systems (3) Review of key circuits: integration of subassemblies into overall system. Prerequisite: Electronic Engineering Technology 432 or equivalent. (Offered alternate years.) Three lectures. S 435. Radar Systems Laboratory (2) Testing and operation of radar subassemblies making up a radar system. (Offered alternate years.) Two 3-hour labs a week. S 450. Computer Circuits Applications (3) Application of basic circuits to digital and analog data handling devices. Three lectures. Prerequisite: Electronic Engineering Technology 324 and 355 or equivalent. S 451. Computer Circuits Laboratory (2) Operation and adjustment of circuits and related control and readout components in computer type devices. Two 3-hour labs a week. S 452. Fundamentals of Analog Computers (3) An introduction to fundamental analog computing circuits, their design and application. Prerequisite: Electronic Engineering Technology 320, 356, or equivalent. Three lectures. W 453. Analog Computer Laboratory (2) Application of analog computing circuits to actual laboratory experiences. Prerequisite and/or concurrent: Electronic Engineering Technology 452. Two 3-hour labs a week. W 456. Principals of Automation (3) Introduction to methods used in automatic pro- gramming and control of industrial equipment. Three lectures. A 457. Principles of Automation Laboratory (2) Set-up adjustment and operation of small automatic control and programming systems. Two 3-hour labs a week. A 460. Theory of Lines and Networks (3) Transmission line and filter network theory and configurations. (Offered alternate years.) Three lectures. Su 461. Line and Network Laboratory (2) Experiments in line and network principles. (Offered alternate years.) Two 3-hour labs a week. Su 464. Micro-Wave Techniques (3) Elementary study of micro-wave generation and propagating devices: emphasis on phenomena peculiar to micro-wave signals. Prerequisite: Electronic Technology 262. Three lectures. W 465. Micro-Wave Laboratory (2) Adjustments and test on devices generating and conducting micro-wave signals. Two 3-hour labs a week. W 468. Air-Ground Communications (3) Special circuits and problems relating to air-ground communications. (Offered alternate years.) Three lectures. Su 469. Air-Ground Communications Laboratory (2) Adjustment and operation of equipment used in air-ground communications. (Offered alternate years.) Two 3-hour labs a week. Su 470. Telemetric Principles (3) Methods and principles used in various types of systems to transfer measurements by wire and wireless. (Offered alternate years. 1 Three lectures. Su 471. Telemetric Laboratory (2) Experimental Loops established for the student to become acquainted with telemetric operation. (Offered alternate years.) Two 3-hour labs a week. Su 479. Senior Problems (2) Special problems covering scope of study during the previous four years. Two lectures. S 480. Senior Project (1-3) 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 486. Electronic Equipment Maintenance (3) Adjustment and maintenance of electronic equipment such as test equipment and electronic equipment used in industrial applications. Supervised study and shop practice. May be repeated up to three times where work and study is on different types of equipment or systems. Prerequisites: Sufficient work experience or related training in the area of study for the student to benefit from additional supervised instructions. W S 489. Cooperative Work Experience (1-9) Open to all fourth year students in Electronics Engineering Technology. A continuation of Electronic Engineering Technology 389. 264 Technology Industrial Electricity 492. Short Courses, Workshops, Institutes and Special Programs (1-6) In order to provide flexibility and to meet many different needs, a number of specific offerings are possible using this catalog number. When the number is used it will be accompanied by a brief and specific descriptive title. The specific title with the credit authorized for the particular offering will appear on the student transcript. A W S Su 493. Special Topics in Electronic Technology (2-5) Designed primarily for majors and high school teachers who desire to explore areas of electronics not covered in regular course offerings* May be repeated for credit. A W S Su INDUSTRIAL ELECTRICITY The courses listed are designed to give student skills in a variety of electrical applications frequently found in commercial buildings, factories, and other industrial settings. Certificates of skill proficiency will be issued for agreed-upon achievement levels within the program. These courses are scheduled only upon sufficient student demand. INDUSTRIAL ELECTRICITY COURSES 181. Fundamentals of Electricity (3) Electron theory; Ohms law; series and parallel circuits; Kirchhoff's law: work, power, torque, and transmission of power. (Evening) 182. Conductors and Magnetism (3) Current carrying capacity of conductors, voltage drop, and conductivity magnets and magnetic-fields; reluctance, permeability and flux density; magnetic circuits and magnetic applications. (Evening) 183. Armature Winding (3) Voltage in a rotating coil: lap and wire winding; paths and multiplicity : selection of type of winding; slot, segments, coils, and pitch, and armature testing, (Evening) 184. Direct Current Motors, Generators and Controllers (3) Principles of the motor torque, power, and armature reaction; construction of generators: controllers; dynamic braking and reversing controllers. (Evening) 185. Alternating Current and Circuits (3) Resistance, inductance, and capacity in series and parallel circuits; impedance, resonance, and power factor problems and correction; power and reactive power in AC circuits. (Evening) 186. Trasformers and Polyphase Systems (3) Efficiency of transmission; transformer principles and construction; types of transformers; polyphase transformers and induction regulators. (Evening) 187. Alternating Current Motors (3) Rotating magnetic field, speed, torque and efficiency ; types of AC motors; frequency and rotary converters, and stator windings. (Evening) 188. Alternators and AC Controllers (3) Revolving field alternators; across the line, drum, and reversing controllers; compensators and multi-speed controllers. (Evening) 189. Electrical Instruments (3) Permanent magnet, electrodynamic, iron vane inclined coil, and induction-type instruments. (Evening) 190. Industrial Electronics (3) Basic tube and transistor functions; replacement characteristics; amplifiers: amplidynes oscillators; high frequency and dielectric heating: types of power tubes; electronic relays. (Eve-ning) 191. Welding Systems and Electronic Motor Control (3) Constant-voltage generators; arc, resistance, spot, and projection welding; control of welding ignition tubes; non-synchronous and synchronous welders. (Evening) 192. Automation and Instrumentation (3) Servo-mechanisms: amplifier circuits; capacitance control circuits; cathodery control circuits; counting circuits; measuring circuits; timing circuits; photo electric circuits; automatic control theory; miscellaneous industrial instruments. (Evening) 292. Short Courses, Workshops, Institutes and Special Programs (1-6) In order to provide flexibility and to meet many different needs, a number of specific offerings are possible using this catalog number. When the number is used it will be accompanied by a brief and specific descriptive title. The specific title with the credit authorized for the particular offering will appear on the student transcript. A W S Su INSTRUMENT REPAIR PROGRAM The Instrument Repair Emphasis is a three quarter program designed to meet the needs of industry. Students interested in this program should be high school graduates or equivalent or eighteen years of age. They must meet the physical and aptitude requirements necessary to achieve in this area. Prerequisite classes relative to this program are not mandatory; however, one should have a working knowledge of mathematical principles and have a desire to work in the area of electronics. Certificates of skill proficiency will be issued for agreed upon achievement levels within the program and a certificate of proficiency will be awarded for completion of the program. 265 |
