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Network Analysis Course Objectives Course Outcomes Syllabus.

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1 Network Analysis Course Objectives Course Outcomes Syllabus

2 Dr. Kishore Kumar Pedapenki Email ID: iitr.kis@gmail.com
Know your Faculty Dr. Kishore Kumar Pedapenki Associate Professor Department of EEE ID: Phone No.: Qualification Specialization Institute Year B.Tech. Electrical and Electronics Engineering VITAM College of Engineering, Visakhapatnam 2005 M.Tech. Power and Industrial Drives JNTU College of Engineering, Anantapur 2007 Ph.D. Investigations of the soft computing techniques in shunt active filters Indian Institute of Technology Roorkee (IITR) 2016

3 Course Objectives S. No. Course Objective 1
To understand the basic concepts on RLC circuits. 2 To know the behavior of the steady states and transient states in RLC circuits. 3 To know the basic Laplace transform techniques in periodic waveforms. 4 To understand the two port network parameters. 5 To understand the properties of LC networks and filters.

4 Course Outcomes S. No. Course Outcomes 1
Gain the knowledge on basic network elements 2 will analyze the RLC circuits behavior in detail 3 analyze the performance of periodic waveforms 4 gain the knowledge in characteristics of two port network parameters (Z, Y, ABCD, h & g) 5 analyze the filter design concepts in real world applications

5 Unit – 1: Introduction to Electrical Circuits, A
Unit – 1: Introduction to Electrical Circuits, A.C Fundamentals and Network Topology Lecture No. Topic to be covered Method 1 (a) Introduction to Electrical Circuits : Network elements classification, Electric charge and current, Electric energy and potential Video 2 Active and Passive Elements and their series and parallel combinations PPT 3 Energy sources: Ideal, Non-ideal, Independent and dependent sources 4 Kirchoff’s laws and Source transformation Chalk and Talk 5 Mesh analysis and Nodal analysis 6 Problem solving with Kirchoff's laws, Mesh and Nodal Analyses 7 Problem solving with resistances only including dependent sources also 8 (b) AC Fundamentals : Definitions of terms associated with periodic functions: Time period, Angular velocity and frequency, RMS value, Average value, Form factor and peak factor- problem solving 9 Phase angle, Phasor representation, Addition and subtraction of phasors 10 Mathematical representation of sinusoidal quantities, explanation with relevant theory

6 Unit – 1: Introduction to Electrical Circuits, A
Unit – 1: Introduction to Electrical Circuits, A.C Fundamentals and Network Topology (Cont….) Lecture No. Topic to be covered Method 11 Problem Solving with terms of Periodic Functions Chalk and Talk 12 13 Problem Solving with Phasors and mathematical representation 14 Principle of Duality with examples 15 (c) Network Topology : Definitions of branch, node, tree, planar, non-planar graph 16 Incidence matrix, basic tie set schedule, basic cut set schedule 17 Problem Solving with Graphs 18 Problem Solving with incident matrix and tie and cut sets 19 Class Test (1-7) Exam 20 Class Test (8-14) 21 Class Test (15-18)

7 Unit – 2: Steady State Analysis and Coupled Circuits
Lecture No. Topic to be covered Method 22 (a) Steady State Analysis: Response to sinusoidal excitation - pure resistance, pure inductance, pure capacitance PPT 23 Impedance concept and Complex Impedance 24 Phase angle and phasor notation for R-L, R-C, R-L-C 25 Problem solving using mesh and nodal analysis, Star-Delta conversion Chalk and Talk 26 Problem solving on impedance, Problem solving on phasor notation 27 Problem solving on Star Delta Conversion 28 (b) Coupled Circuits : Self inductance, Mutual inductance, Coefficient of coupling 29 Analysis of coupled circuits 30 Natural current, Dot rule of coupled circuits 31 Conductively coupled equivalent circuits 32 problem solving self and mutual inductances 33 problem solving coupled circuits 34, 35, 36 Class Test (22-25) ; (26-29) ; (30-33) Exam

8 Unit – 3: Resonance and Network Theorems
Lecture No. Topic to be covered Method 37 (a) Resonance : Introduction, Definition of Q Chalk and Talk 38 Series resonance, Parallel resonance, Condition for maximum impedance 39 Current in anti resonance, general case resistance present in both branches, anti resonance at all frequencies. 40 (b) Network Theorems: Thevenin’s, Norton’s, Milliman’s Theorems PPT 41 Reciprocity, Compensation, Substitution Theorems 42 Superposition, Max Power Transfer, Tellegen’s Theorems 43 Problem Solving on Thevenin's and Norton's Theorems, Problem Solving on Super Position and Maximum Power Transfer Theorems 44 Problem Solving on Millman's, Reciprocity, Compensation, Substitution and Tellegen's Theorems, Problems solving on Miscellaneous Theorems 45 Class Test (37-39) Exam 46 Class Test (40-42) 47 Class Test (43-44)

9 Unit – 4: Two Port Networks
Lecture No. Topic to be covered Method 48 Relationship of two port networks, Z-parameters, Y-parameters, PPT 49 Transmission line parameters, Inverse Transmission line parameters, h-parameters, Inverse h-parameters 50 Relationship between parameter sets, Parallel connection of two port networks, Cascading of two port networks, series connection of two port networks, Chalk and Talk 51 Problem solving including dependent sources also 52 Class Test (48) Exam 53 Class Test (49) 54 Class Test (50)

10 Unit – 5: Transients Lecture No. Topic to be covered Method 55
First order differential equations, Definition of time constants PPT 56 R-L circuit, R-C circuit with DC excitation, Evaluating initial conditions procedure 57 Second order differential equations, homogeneous, non homogenous 58 Problem solving using R-L-C elements with DC excitation and AC excitation Chalk and Talk 59 Response as related to s-plane rotation of roots. Solutions using Laplace transform method, Problem solving 60 Class Test (55-56) Exam 61 Class Test (57-58) 62 Class Test (59)

11 Prescribed Text Books S.No. Name of theTitle Authors Rating Type 1
Network Analysis M. E. Van Valkenburg 9 Concept 2 Engineering Circuit Analysis William H. Hayt, Steven M. Durbin, Jack E. Kemmerly 8.8 3 Introductory Circuit Analysis Robert L. Boylestad 8 4 Circuit Theory : Analysis and Synthesis Abhijit Chakrabarti Practice 5 Network Analysis And Synthesis  A Husain 8.5 6 NETWORK ANALYSIS & SYNTHESIS N C Jagan 7 Electrical Circuit Analysis Circuits and Networks : Analysis and Synthesis A. Sudhakar, Shyammohan 7.8 Network Analysis and Synthesis A K Chakraborty, S P Ghosh 10 Networks and Systems D. Roy Choudhury

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