ECE 201 LINEAR CIRCUIT ANALYSIS I l Circuit Analysis Course Outcomes 1. Learn the basic vocabulary, principles, analysis methods, and design techniques of circuit theory. 2. Learn to write equilibrium equations for a prescribed network and solve for any specified voltage or current under d-c or sinusoidal steady-state conditions. 3. Find the step response of single time-constant circuits, and parallel or series RLC circuits. 4. Apply Thevenin’s and Norton’s theorems. 5. Foster the development of rational thinking patterns in the context of circuit analysis and design. 6. Develop students’ abilities to critically evaluate their chosen problem solving techniques and the accuracy of their answers. DC Analysis 1. Resistive Calculations - Ohm’s Law - Nodal Mesh - Mesh Analysis 2. Source-Free Response Calculations - RL and RC Circuits - RLC circuits 3. Complete Response with Batteries and/or Step Response - RL and RC circuits - RLC circuits Phasor Analysis 1. Impedance and Admittance Calculations 2. Nodal and Mesh Analysis 3. Sinusoidal Steady-State Calculations - RL and RC circuits - RLC circuits Network Theorems 1. KVL & KCL (Resistive and Phasors) 2. Voltage and Current Division (Resistive and Phasors) 3. Superposition and Linearity (Resistive and Phasors) 4. Source Transformations (Resistive and with L’s and C’s) 5. Thevenin’s and Norton Equivalent Circuits (resistive and in terms of phasors) Power 1. DC & AC Instantaneous 2. Maximum Power Circuits - resistive circuits - RLC circuits using phasors 3. Average Power 4. Effective Power 5. Complex Power 6. Polyphase Circuits Op Amp Circuits 1. Resistive Only 2. RC Op Amp Circuits excited by Step Inputs 3. Phasor Analysis of RC and RLC Op Amp Circuits Revision Date: 5/11/07COURSE NUMBER: ECE 201 COURSE TITLE: Linear Circuit Analysis I REQUIRED COURSE OR ELECTIVE COURSE: ?? TERMS OFFERED: Fall, Spring and Summer TEXTBOOK/REQUIRED MATERIAL: R. Decarlo and P.M. Lin, Linear Circuit Analysis: Time Domain, Phasor, and Laplace Transform Approaches, 3rd Edition. PRE-REQUISITES: ENGR 126 Engineering Problem Solving And Computer Tools CO-REQUISITES: MA 261 Multivariate Calculus COORDINATING FACULTY: R.A. DeCarlo COURSE OUTCOMES: 1. Learn the basic vocabulary, principles, analysis methods, and design techniques of circuit theory. 2. Learn to write equilibrium equations for a prescribed network and solve for any specified voltage or current under d-c or sinusoidal steady-state conditions. 3. Find the step response of single time-constant circuits, and parallel or series RLC circuits. 4. Apply Thevenin’s and Norton’s theorems. 5. Foster the development of rational thinking patterns in the context of circuit analysis and design. 6. Develop students’ abilities to critically evaluate their chosen problem solving techniques and the accuracy of their answers. COURSE DESCRIPTION: Volt-ampere characteristics for circuit elements; independent and dependent sources; Kirchhoff’s laws and circuit equations. Source transformation; Thevenin’s and Norton’s theorems; superposition. Step response of 1st order (RC, RL) and 2nd order (RLC) circuits. Phasor anlaysis, impedance calculations and computation of sinusoidal steady state responses. Instantaneous and average power, complex power, power factor correction, and maximum power transfer. Instantaneous and average power. ASSESSMENTS TOOLS: ?? PROFESSIONAL COMPONENT: 1. Engineering Science – 2.7 credits (? %) Engineering Design – 0.3 credits (? %) RELATED ME PROGRAM OUTCOMES: ?? NATURE OF DESIGN CONTENT: ?? COMPUTER USAGE: ?? COURSE STRUCTURE/SCHEDULE: 1. Lecture – 3 days per week at 50 minutes. PREPARED BY: R.A. DeCarlo REVISION DATE: May 11,
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