18EC-305C: Network Analysis Syllabus for Electronics & Communication Engineering 3rd Sem C18 Curriculum TSSBTET

Network Analysis detailed Syllabus for Electronics & Communication Engineering (DECE), C18 curriculum has been taken from the TSSBTET official website and presented for the diploma students. For Course Code, Course Name, Lectures, Tutorial, Practical/Drawing, Internal Marks, Max Marks, Total Marks, Min Marks and other information, do visit full semester subjects post given below.

For all other Diploma in Electronics & Communication Engineering (DECE) Syllabus for 3rd Sem C18 Curriculum TSSBTET, do visit Diploma in Electronics & Communication Engineering (DECE) Syllabus for 3rd Sem C18 Curriculum TSSBTET Subjects. The detailed Syllabus for network analysis is as follows.

Prerequisites:

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Course Outcome:

After completion of the course the student should be able to

1. Solve simple problems related to Ohms law, KVL and KCL
2. Apply Mesh current and Node voltage methods to simplify and find solution to electrical circuits
3. Solve simple problems on DC transients
4. Design simple passive filters and attenuators for given specifications
5. Find various two port parameters of simple Two port networks
6. Apply various Network theorems to simplify and find solution to electrical circuits

Unit 1: Basics of Electrical Circuits and Kirchoffs Laws:

Active and passive elements- resistance, capacitance and inductance parameters- Energy source and classify the energy sources- Ideal voltage source and Ideal current sourceIdeal voltage source to ideal current source and vice versa- Introduction to Alternating voltages and currents-Phasor representation of alternating quantities -Phasor relationships for circuit Elements-Impedance and Admittance of circuit elements-AC analysis of series RL,RC circuits.

Unit 2: Mesh Current and Node Voltage Analysis:

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Unit 3: Transient Analysis:

Initial conditions, steady state and transient- DC response for an RL circuit- Expression for current for an RL circuit- DC response for an RC circuit- Expression for current for an RC circuit- DC response for an RLC circuit-Solve simple problems on series RL,RC circuits of DC excitation- RC differentiator circuit – Input/output waveforms for RC differentiator circuit- RC integrator circuit- Input/output waveforms for RC integrator circuit

Unit 4: Filters and Attenuators

Definition of neper, decibel, characteristic impedance, propagation constant, Attenuation- Definition of filter- LPF, HPF, BPF, BSF- Characteristic curves for the above- Expression for characteristic impedance for T and n network- Expression for fc for constant k-LPF, HPF-Design of a simple LPF and HPF for a given cut off frequency and given impedance- Design of a T-type attenuator for the given attenuation and characteristic impedance.- Design of a n-type attenuator for the given attenuation and characteristic impedance- Equalizer circuit-.- Applications of equalizer circuit.

Unit 5: Two Port Networks:

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Unit 6: Network Theorems and Resonance:

Thevenins, and Nortons theorems – Solve networks- Use of above theorems in electronic circuits- Superposition theorem – Maximum power transfer theorems-Solve simple problems using the above theorem- Importance of impedance matching for maximum power transfer- Reciprocity theorem- Importance of Reciprocity theorem -advantages and limitations of above theorems- Star and Delta configurations of resistances- Formulas from Star to Delta & Delta to Star (no derivation)-Solve simple problems on Star/Delta and Delta/Star transformation. Resonance in A.C. Circuits – Series and parallel resonance. – curves, effect of resistance on Q factor selectivity and bandwidth. Suggested Learning Outcomes: After completing the course student will be able to

Basics of Electrical Circuits and Kirchhoffs Laws

• Define active and passive elements.
• Define energy source and classify the energy sources.
• Explain ideal voltage source and ideal current source
• Convert ideal voltage source to ideal current source and vice versa.
• Explain Phasor representation of sinusoids.
• Derive the expression for I,Z, and power in an R-L series circuit.
• Draw the vector and phasor diagrams for the above.
• Derive the expression for I,Z, and power in an R-C series circuit.
• Draw the vector and phasor diagrams for the above.
• Derive the expression for I,Z, and power in an R-L-C series circuit.
• Draw the vector and phasor diagrams for the above.
• Explain the methods for solving parallel circuits.

Mesh Current Analysis and Node Voltage Analysis

• Explain the concept of graph of a network
• Define, branch, nodes, junction and loop in circuits.
• Identify the mesh currents.
• Determine the number of mesh equations required to solve the given Network
• Write the mesh current equations for a given network and arrange them in matrix form.
• Solve for mesh currents using Crammers rule.
• Identify the nodes in a network.
• Determine the number of node voltage equations.
• Write the node voltage equation for a given network and arrange them in matrix form.
• Solve for node voltages using Crammers rule.
• Explain duality of a network
• Draw the dual of given network.
• Explain the concept of graph of a network

Transient Analysis.

• Define the terms initial conditions, steady state and transient.
• Explain the dc response for an RL circuit.
• Derive expression for current for an RL circuit.
• Explain the dc response for an RC circuit.
• Derive expression for current for an RC circuit.
• Explain the dc response for an RLC circuit.
• Solve simple problems on series RL, RC circuits of DC excitation.
• Explain RC differentiator circuit
• Draw input/output waveforms for RC differentiator circuit
• Explain RC integrator circuit
• Draw input/output waveforms for RC integrator circuit

Filters and Attenuators

• Define neper, decibel, characteristic impedance, propagation constant, Attenuation
• Define filter, LPF, HPF, BPF, BSF.
• Draw the characteristic curves for the above
• Derive the expression for characteristic impedance for T and n network.
• Give the expression for fc for constant k-LPF, HPF.
• Design a simple LPF and HPF for a given cut off frequency and given impedance.
• Design a T-type attenuator for the given attenuation and characteristic impedance.
• Design a n-type attenuator for the given attenuation and characteristic impedance.
• Define the equalizer circuit
• Draw the circuit of equalizer circuit.
• List the applications of equalizer circuit.

Two Port Networks

• Define port.
• Explain the open circuit impedance (Z) parameters with equivalent circuit.
• Explain the short circuit admittance(Y) parameters with equivalent circuit.
• Explain the hybrid (h) parameters with equivalent circuit.
• Give the conditions for symmetry in terms of Z, Y, h parameters.
• Give conditions for reciprocity in terms of Z, Y, h parameters
• Find the Z- parameters for a given T- network and Y parameters for a n-network
• Express Z- parameters in terms of Y- parameters
• Express Y- parameters in terms of Z- parameters
• Give Examples for symmetric networks
• Give Examples for Reciprocal networks

Network Theorems and Resonance

• State Thevenins and Nortons theorem.
• Apply the above theorems to solve networks.
• Explain the use of above theorems in electronic circuits
• State superposition theorem
• Solve simple problems using the above theorem
• State Maximum power transfer theorem.
• Solve simple problems using the above theorem.
• Explain the importance of impedance matching for maximum power transfer.
• State Reciprocity theorem
• Explain the importance of Reciprocity theorem by giving examples like Co axial cable and flat twin lead cable used in Television systems.
• List the advantages and limitations of above theorems.
• Explain star and Delta configurations of resistances.
• Give transformation formulas from Star to Delta & Delta to Star (no derivation).
• Solve simple problems on Star/Delta and Delta/Star transformation.
• Explain resonance in RLC series circuit
• Derive the formula for series resonance
• State the conditions for series resonance
• Define bandwidth of a resonant circuit
• Define lower cut off and upper cut off frequencies
• Give formula for lower cut off and upper cut off frequencies
• Solve simple problems on series Resonance.
• Explain Resonance in parallel circuits
• State the conditions required for parallel resonance
• Derive Equation for resonant frequency.
• Compare Series and parallel resonance
• Solve problems on Resonance
• Explain effect of Resistance on Bandwidth.

Recommended Books

1. Engineering circuit analysis by W.H.Hayt, J.E.Kemmerly and S.M.Durbin, Tata Mc Graw Hill, New Delhi.
2. Fundamentals of Electric circuits by Charles K. Alexander and Matthew N.O. Sadiku, Mc Graw Hill publishers.
3. Network Analysis by M.E Van Valkenberg, Prantice Hall India, 3rd Edition
4. Electric Circuits -Joseph Edminister ,Schaum Series publishers.

Suggested E-Learning references

For the complete Syllabus, results, class timetable, and many other features kindly download the iStudy App
It is a lightweight, easy to use, no images, and no pdfs platform to make students’s lives easier.
.

Suggested Student Activities

1. Participate in the Quiz
2. participate in Group discussion
3. Search internet for more literature.
4. Surprise test.

Course Outcome:

1. Solve simple problems related to Ohms law, KVL and KCL
2. Apply Mesh current and Node voltage methods to simplify and find solution to electrical circuits
3. Solve simple problems on DC transients
4. Design simple passive filters and attenuators for given specifications
5. Find various two port parameters of simple Two port networks
6. Apply various Network theorems to simplify and find solution to electrical circuits Design simple passive filters and attenuators for given specifications

For detail Syllabus of all other subjects of Electronics & Communication Engineering, C18 curriculum do visit Diploma In Electronics & Communication Engineering 3rd Sem Syllabus for C18 curriculum.

For all Electronics & Communication Engineering results, visit TSSBTET DECE all semester results direct links.