Download ECE 206 Electronic Circuits Laboratory: Objectives and Goals and more Lab Reports Electrical and Electronics Engineering in PDF only on Docsity! ECE 206 Electric and Electronic Circuits Laboratory Course Goals ECE 206 laboratory is an adjunct to ECE 205 - Introduction to Electric and Electronic Circuits. It is intended to supplement the material of ECE 205 and to assist students in obtaining basic measurement techniques and hands-on experience in assembling and testing electric and electronic circuits using lab instruments. Instructional Objectives 1. Laboratory Introduction (2 hours) At the end of this lab, students will be able to assemble a circuit on a breadboard with resistors, diodes, and power supplies; measure voltages, currents, resistances, and capacitances using multimeters; and verify Ohm’s law, KCL, KVL, and series and parallel resistances. (b) 2. Networks Solving and Equivalent Circuits (2 hours) At the end of this lab, students will be able to calculate, using Thevenin’s theorem, and measure the currents and voltages in a resistive network; demonstrate the equivalence between the resistive network and its Thevenin circuit; and examine the differences between theoretical and experimental values. (b) 3. Transient Response (2 hours) At the end of this lab, students will be able to make time and voltage measurements using an oscilloscope and a function generator and to conduct general analysis and time-constant measurements of RC circuits. (b) 4. Rectifier, Regulator, and Power Supply Circuits (2 hours) At the end of this lab, students will be able to build a power supply containing a step-down transformer, half-wave rectifier, filter, and voltage regulator, and to conduct general analysis of the power supply circuit using an oscilloscope and a function generator. (b) 5. MOSFET Inverter Circuits (2 hours) At the end of this lab, students will be able to construct MOS inverter circuits and to measure, plot, analyze, and interpret the output characteristics. (b) 6. CMOS Logic Circuits (2 hours) At the end of this lab, students will be able to construct CMOS logic circuits; examine CMOS, NAND, and NOR gates by measuring and analyzing the output characteristics; and determine and interpret the truth table for complex CMOS logic circuits. (b) 7. CMOS Transient Analysis (2 hours) At the end of this lab, students will be able to conduct the transient analysis of CMOS inverter circuits by measuring the rise time, fall time, propagation delay, and maximum operating frequency with an oscilloscope and a function generator. (b) 8. BJT Circuits (2 hours) At the end of this lab, students will be able to construct common emitter and emitter follower circuits and to measure, plot, analyze, and interpret the terminal currents and output characteristics. (b) 9. TTL Analysis (2 hours) At the end of this lab, students will be able to construct a basic TTL inverter circuit and a commercial TTL inverter circuit; examine the logic function of TTL gates; and measure, plot, and analyze the output characteristics. (b) 10. Operational Amplifiers (2 hours) At the end of this lab, students will be able to build inverting, noninverting, and summing op-amp amplifiers and to conduct general analysis and measurements using an oscilloscope and a function generator. (b) 11. Non-Linear Op-Amp Circuits (2 hours) At the end of this lab, students will be able to construct voltage comparator and precision rectifier circuits using op amps and to perform general measurements of the circuits using an oscilloscope and a function generator. (b)
