power sources diodes, transistors, tubes (thermionic emission), and amplifiers. RF signals, capacitors, and inductors RC, RL, and RLC circuits d.c. This course serves to instruct sound recording technology through the concepts of voltage, current, power, resistance and Ohm's law series, parallel and resonant circuits, Kirchhoff's voltage and current laws the Wheatstone bridge, Thevenin equivalent circuits and maximum power transfer theorem magnetism, electromagnetism, electromagnetic devices, and transformers a.c. Fundamentals of Sound Recording (Formerly 16.214) Description Students will also be introduced to DC and AC motors and generators, first and second order filters as well as basic sensors. Different techniques like Superposition theorem, Thevenin equivalent circuit or Maximum Power will be presented.
#CMOS TRANSISTOR SCHEMATIC ECE 2020 SERIES#
Cover also the design and use of multi-range voltmeters, ammeters, and ohmmeters, series, parallel and series parallel circuits, the use of bridges, phasor analysis of AC circuits, transformers, relays, solenoids, etc. Covers the explanation of basic components (resistor, capacitor and inductor) and their use in electronics. This course serves as an introduction to direct current (DC) and alternating current (AC) analysis of electric circuits, with emphasis on energy and power. Fundamentals of Electricity I (Formerly 16.211/213) Description Pre-Req: EECE 2070 Basic EE Lab I Co-Req: EECE 2020 Circuit Theory II. Experiments cover: Kirchhoff's laws for phasors, magnitude and phase measurements of impedance, network theorems, frequency response, resonance, inductance, maximum power transfer, and MATLAB techniques. Experiments are integrated with Circuit Theory II. Waveform measurements with DC and AC meters as well as advanced use of the oscilloscope are also discussed. Presents experimental work designed to emphasize electrical measurement techniques of linear systems with time-varying signals. Basic Electrical Engineering Lab II (Formerly 16.208) Description PrerequisitesĬo-Req: EECE.2010 Circuit Theory I. MATLAB will be utilized throughout the course. Experiments are correlated with Circuit Theory I and concern: resistive measurements, Kirchhoff's laws, network theorems, conservation of power and maximum power transfer, inductance and capacitance, and first and second-order transients, operational amplifiers. Basic Electrical Engineering Laboratory I (Formerly 16.207) DescriptionĮxperimental work designed to verify theory and to acquaint students with electrical measurement techniques: experiments on meters, bridges, and oscilloscopes. Pre-Req: C- or better in EECE 2010 Circuit Theory I, or Spring 2020 grade of "P" and Co-Req: EECE 2080 Basic EE Lab II. Introduction to transfer functions, poles and zeroes in the s-plane. Introduction to magnetic coupling, mutual inductance, and the ideal transformer. Covers power in the frequency domain, including RMS values, average power, reactive power, and apparent power. Introduces the use of complex numbers, phasors, impedance and admittance for the application of circuit laws introduced in Circuit Theory I: Thevenin and Norton's theorems, source transformation, superposition, maximum power transfer, nodal and mesh analysis. This course covers AC circuits under sinusoidal steady-state conditions using the concept of the frequency domain. Circuit Theory II (Formerly 16.202) Description Pre-req: MATH.1320 Calculus II, and Co-req: EECE.2070 Basic Electrical Engineering Lab I, and a 'C' or higher in MATH.1320. Also covers ideal inductance and capacitance in simple circuits with the study of transient response and behavior under DC conditions. Introduces concepts of network topology, independent and dependent variables, mesh and nodal analysis, the definition and consequences of linearity, source transformation, the superposition principle, Thevenin's and Norton's theorems, and maximum power transfer.
It introduces and applies Ohm's Law and Kirchoff's Laws. This course covers ideal elements, active and passive. "Variable credit course, student chooses appropriate amount of credits when registering." Circuit Theory I (Formerly 16.201) Description Curricula Practical Training DescriptionĬurricula Practical Training.
Students learn to use basic test equipment such as an Oscilloscope, Function Generator, Volt Meter. In the second part of the course students program a micro-controller and learn about the function of basic electronic components. The first half of the course focuses on application programming in Matlab where students learn basics of Programming, Digital Signal Processing, and Data Analysis. This course is divided into two parts in which students focus on core skills to help them thrive in electrical and computer engineering.
Introduction to Electrical and Computer Engineering (Formerly 25/16.107) Description
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