CBCGS [2017 - current]

CBGS [2013 - 2016]

Old [2000 - 2012]

## University of Mumbai Semester 3 (SE Second Year) Electrical Network Analysis and Synthesis Revised Syllabus

University of Mumbai Semester 3 (SE Second Year) Electrical Network Analysis and Synthesis and their Unit wise marks distribution

### Units and Topics

# | Unit/Topic | Marks |
---|---|---|

100 | Introduction | - |

200 | Mesh and Node Analysis | - |

300 | Network Theorems ( D.C. and A.C. Circuits) | - |

400 | Circuit Analysis | - |

500 | Time and Frequency Response of Circuits | - |

600 | Two-port Networks | - |

700 | Fundamentals of Network Synthesis | - |

Total | - |

## Syllabus

100 Introduction

- Review of D.C. & A.C. circuits.
- DC Circuits: Current & Voltage Source Transformation, Source Shifting.

200 Mesh and Node Analysis

- Mesh & Node Analysis of D.C. & A.C. circuits with independent & dependent sources. (Introduction to coupled circuits).

300 Network Theorems ( D.C. and A.C. Circuits)

- Superposition.
- Thevenin‘s & Norton‘s Theorem (with independent and dependent sources).
- Maximum power transfer theorem.

400 Circuit Analysis

- Introduction to Graph Theory.
- Tree, link currents, branch voltages, cut set & tie set, Mesh & Node Analysis, Duality.

500 Time and Frequency Response of Circuits

- First & second order Differential equations, initial conditions.
- Evaluation & Analysis of Transient Steady state responses using Classical Technique as well as by Laplace Transform (for simple circuits only).
- Transfer function.
- Concept of poles and zeros.

600 Two-port Networks

- Concept of two-port network.
- Driving point and Transfer Functions.
- Open Circuit impedance (Z) parameters.
- Short Circuit admittance (Y) parameters.
- Transmission (ABCD) parameters.
- Inverse Transmission (A‘B‘C‘D‘) parameters.
- Hybrid (h) parameters.
- Inter Relationship of different parameters.
- Interconnections of two-port networks.
- Terminated two-port networks.

700 Fundamentals of Network Synthesis

- Positive real functions.
- Driving Point functions.
- Properties of positive real functions.
- Testing Positive real functions.
- Testing driving point functions.
- Maximum modulus theorem.
- Properties of Hurwitz polynomials.
- Residue computations.
- Even & odd functions.
- Driving Point Synthesis with L-C, R-C, R-L and R-L-C networks.

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