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r2013 notes

EC6702 Optical Communication and Networks Notes Regulation 2013 Anna University

EC6702 Optical Communication and Networks Notes Regulation 2013 Anna University

EC6702 Optical Communication and Networks Notes

EC6702 Optical Communication and Networks Notes Regulation 2013 Anna University free download. Optical Communication and Networks EC6702 Notes pdf free download.

OBJECTIVES: EC6702 Optical Communication and Networks Notes

To Facilitate the knowledge about optical fiber sources and transmission techniques To Enrich the idea of optical fiber networks algorithm such as SONET/SDH and optical CDMA. To Explore the trends of optical fiber measurement systems.

OUTCOMES: EC6702 Optical Communication and Networks Notes

Upon completion of the course, students will be able to: Discuss the various optical fiber modes, configurations and various signal degradation factors associated with optical fiber. Explain the various optical sources and optical detectors and their use in the optical communication system. Analyze the digital transmission and its associated parameters on system performance.

TEXT BOOKS: EC6702 Optical Communication and Networks Notes

1. Gerd Keiser, “Optical Fiber Communication” Mc Graw -Hill International, 4th Edition., 2010.

2. John M. Senior , “Optical Fiber Communication”, Second Edition, Pearson Education, 2007.

REFERENCES: EC6702 Optical Communication and Networks Notes

1. Ramaswami, Sivarajan and Sasaki “Optical Networks”, Morgan Kaufmann, 2009.

2. J.Senior, “Optical Communication, Principles and Practice”, Prentice Hall of India, 3rd Edition, 2008.

3. J.Gower, “Optical Communication System”, Prentice Hall of India, 2001.

A fiber optic data link sends input data through fiber optic components and provides this data as output information. It has the following three basic functions:

 To convert an electrical input signal to an optical signal
 To send the optical signal over an optical fiber
 To convert the optical signal back to an electrical signal

A fiber optic data link consists of three parts – transmitter, optical fiber, and
receiver. Figure 1-1 is an illustration of a fiber optic data-link connection. The
transmitter, optical fiber, and receiver perform the basic functions of the fiber optic data link.

Each part of the data link is responsible for the successful transfer of the data signal. A fiber optic data link needs a transmitter that can effectively convert an electrical input signal to an optical signal and launch the data-containing light down the optical fiber.

A fiber optic data link also needs a receiver that can effectively transform this
optical signal back into its original form. This means that the electrical signal provided as data output should exactly match the electrical signal provided as data input.  (EC6702 Optical Communication and Networks Notes)

Subject Name Optical Communication and Networks
Subject code EC6702
Regulation 2013

EC6702 Optical Communication and Networks Notes click here to download

EC6702 Optical Communication and Networks Syllabus

EC6702 Optical Communication and Networks Important questions

EC6702 Optical Communication and Networks Question Bank

 

Categories
UG syllabus R 2013

EC6702 Optical Communication and Networks Syllabus Regulation 2013 Anna University

EC6702 Optical Communication and Networks Syllabus Regulation 2013 Anna University

EC6702 Optical Communication and Networks Syllabus

EC6702 Optical Communication and Networks Syllabus Regulation 2013 Anna University free download. Optical Communication and Networks EC6702 Syllabus pdf free download.

UNIT I INTRODUCTION TO OPTICAL FIBERS EC6702 Optical Communication and Networks Syllabus

Evolution of fiber optic system- Element of an Optical Fiber Transmission link– Total internal reflection-Acceptance angle –Numerical aperture – Skew rays Ray Optics-Optical Fiber Modes and Configurations -Mode theory of Circular Wave guides- Overview of Modes-Key Modal concepts- Linearly Polarized Modes -Single Mode Fibers-Graded Index fiber structure.

UNIT II SIGNAL DEGRADATION OPTICAL FIBERS EC6702 Optical Communication and Networks Syllabus

Attenuation – Absorption losses, Scattering losses, Bending Losses, Core and Cladding losses, Signal Distortion in Optical Wave guides-Information Capacity determination -Group Delay-Material Dispersion, Wave guide Dispersion, Signal distortion in SM fibers-Polarization Mode dispersion, Intermodal dispersion, Pulse Broadening in GI fibers-Mode Coupling -Design Optimization of SM fibers-RI profile and cut-off wavelength.

UNIT III FIBER OPTICAL SOURCES AND COUPLING EC6702 Optical Communication and Networks Syllabus

Direct and indirect Band gap materials-LED structures -Light source materials -Quantum efficiency and LED power, Modulation of a LED, lasers Diodes-Modes and Threshold condition -Rate equations -External Quantum efficiency -Resonant frequencies -Laser Diodes, Temperature effects, Introduction to Quantum laser, Fiber amplifiers- Power Launching and coupling, Lencing schemes, Fiber -to- Fiber joints, Fiber splicing-Signal to Noise ratio , Detector response time.

UNIT IV FIBER OPTIC RECEIVER AND MEASUREMENTS EC6702 Optical Communication and Networks Syllabus

Fundamental receiver operation, Pre amplifiers, Error sources – Receiver Configuration– Probability of Error – Quantum limit.Fiber Attenuation measurements- Dispersion measurements – Fiber Refractive index profile measurements – Fiber cut- off Wave length Measurements – Fiber Numerical Aperture Measurements – Fiber diameter measurements.

UNIT V OPTICAL NETWORKS AND SYSTEM TRANSMISSION EC6702 Optical Communication and Networks Syllabus

Basic Networks – SONET / SDH – Broadcast – and –select WDM Networks –Wavelength Routed Networks – Non linear effects on Network performance –-Link Power budget -Rise time budget- Noise Effects on System Performance-Operational Principles of WDM Performance of WDM + EDFA system – Solutions – Optical CDMA – Ultra High Capacity Networks.

Subject Name Optical Communication and Networks
Subject code EC6702
Regulation 2013

EC6702 Optical Communication and Networks Syllabus click here to download

EC6702 Optical Communication and Networks Notes

EC6702 Optical Communication and Networks Important questions

EC6702 Optical Communication and Networks Question Bank

 

Categories
question bank

EC6701 RF and microwave engineering Question Bank regulation 2013 anna university

EC6701 RF and microwave engineering Question Bank regulation 2013 anna university

EC6701 RF AND MICROWAVE ENGINEERING Question Bank

EC6701 RF and microwave engineering Question Bank regulation 2013 anna university free download. RF and microwave engineering EC6701 Question Bank pdf free download.

Sample EC6701 RF and microwave engineering Question Bank:

1. What are the principal limitations of conventional negative grid electron tubes?

1) Electron transit time becomes a noticeable proportion at high frequencies.
2) Lumped electrical reactance and low Q resonant circuit.

2. What is frequency pulling and frequency pushing in magnetrons?

Frequency pulling is caused by changes in the load impedance reflected into the
cavity resonators. Frequency pushing is due to the change in anode voltage which alters the orbital velocity of electron clouds.

3.What are the applications of High Q-oscillators and amplifier circuits?

They are used in a)Low power transmitters
b)Parametric amplifier pumps
c)Police radars and intrusion alarms. (EC6701 RF and microwave engineering question bank)

4.What are the Key phenomenon taking place in TRAPATT diode?

The Key phenomena are a)Carrier generation by impact ionization producing a
current pulse of phase delay of 90 degree.
b)An additional phase shift introduced by the drift of carriers.

5.What is the operating frequency of TRAPATT devices?

TRAPATT devices operate at frequencies from 400 MHz to about 12GHz.

6. What are the applications of TRAPATT devices?

The applications are
a)Phased-array Radar systems
b)Intermediate frequency transmitters.
c)Proxity fuse sources (EC6701 RF and microwave engineering question bank)

7.What are ferrites devices.Explain in detail the different ferrite devices

8. Dicuss the high frequency effects in conventional tubes?

9.Explain in detail about spectrum analyzer?

10.Explain in detail about network analyzer

11.Explain the different types of Impedence measurement methods?

12. How do you measure microwave frequency? (EC6701 RF and microwave engineering question bank)

13. Explain the power measuring devices baretter and thermistor?

14.Explain in detail power detecting elements?

15.Explain in detail about microwave detector? (EC6701 RF and microwave engineering question bank)

16.What is Transferred electron effect?Explian some of the TED‟s?
17.What is negative resistance in gunn diode?Desribe the operation of GUNN
diode

18.Explain the operation of TRAPATT diode (EC6701 RF and microwave engineering question bank)

Subject Name RF and microwave engineering
Subject code EC6701
Regulation 2013

EC6701 RF and microwave engineering question bank click here to download

EC6701 RF and microwave engineering Syllabus

EC6701 RF and microwave engineering Notes

EC6701 RF and microwave engineering Important questions

 

 

Categories
Important question

EC6701 RF and microwave engineering Important questions regulation 2013 anna university

EC6701 RF and microwave engineering Important questions regulation 2013 anna university

EC6701 RF AND MICROWAVE ENGINEERING Important questions

EC6701 RF and microwave engineering Important questions regulation 2013 anna university free download. RF and microwave engineering EC6701 Important questions pdf free download.

Sample EC6701 RF and microwave engineering Important questions:

TWO MARK QUESTIONS-ANSWERS

1. Define s-matrix

In a microwave junction there is intersection of three or more
components.There will be an output port ,in addition there may be reflection from
the junction of other ports.Totally there may be many combinations,these are
represented easily using a matrix called S matrix.

2 What are the .Properties of s-matrix?

It possess symmetric property sij =sji
It possess unitary property [s][s]*=[i] (EC6701 RF and microwave engineering Important questions)

3. Why is s-matrix used in MW analysis?

S matrix is used in MW analysis to overcome the problems which occurs when
H,Y,&Z parameters are used in high frequencies.
Equipment is not readily available to measure total voltage &total current at
the ports of the network.
Short and open circuits are difficult to achieve over a broad band of
frequencies.
Active devices,such as power transistor &tunnel diodes,frequently won‟t
have stability for a short or open circuit.

4. Give ABCD matrix for a two port network

V1=A B V2
I1 C D -I2

5. What is ABCD matrix?

ABCD matrix is a transmission matrix. These parameters express voltage and
current at output in terms of those at input port.
V1=AV2-BI2
I1=CV2-DI2 (EC6701 RF and microwave engineering Important questions)

6. What are the advantages of ABCD matrix?

They are used in power transmission lines.
They are very helpful in the case of cascade networks.

16 mark questions (EC6701 RF and microwave engineering Important questions)

1.Explain in detail about 2-cavity klystron amplifier.

2. Explain about the reflex klystron.

3. Explain about TWT amplifiers.

4. Explain about magnetron oscillator.

5. Numerical problems.
-calculation of output voltage, power,efficiency for 2-cavity klystron amplifier, reflex klystron,magnetron,TWTamplifiers.

6.What are the properties of scattering matrix for a lossless junction?

7.What are ferrites devices.Explain in detail the different ferrite devices

(EC6701 RF and microwave engineering Important questions)

Subject Name RF and microwave engineering
Subject code EC6701
Regulation 2013

EC6701 RF and microwave engineering Important questions click here to download

EC6701 RF and microwave engineering Syllabus

EC6701 RF and microwave engineering Notes

EC6701 RF and microwave engineering Question Bank

 

Categories
r2013 notes

EC6701 RF and microwave engineering Notes regulation 2013 anna university

EC6701 RF and microwave engineering Notes regulation 2013 anna university

EC6701 RF AND MICROWAVE ENGINEERING Notes

EC6701 RF and microwave engineering Notes regulation 2013 anna university free download. RF and microwave engineering EC6701 Notes pdf free download.

OBJECTIVES: EC6701 RF and microwave engineering Notes

To inculcate understanding of the basics required for circuit representation of RF networks.

To deal with the issues in the design of microwave amplifier.

To instill knowledge on the properties of various microwave components.

To deal with the microwave generation and microwave measurement techniques.

OUTCOMES: EC6701 RF and microwave engineering Notes

Upon completion of the course, students will be able to:

Explain the active & passive microwave devices & components used in Microwave communication systems.

Analyze the multi- port RF networks and RF transistor amplifiers.

Generate Microwave signals and design microwave amplifiers.

Measure and analyze Microwave signal and parameters.

TEXT BOOKS: EC6701 RF and microwave engineering Notes

1. Reinhold Ludwig and Gene Bogdanov, “RF Circuit Design: Theory and Applications”, Pearson Education Inc., 2011.

2. Robert E Colin, “Foundations for Microwave Engineering”, John Wiley & Sons Inc, 2005.

REFERENCES: EC6701 RF and microwave engineering Notes

1. David M. Pozar, “Microwave Engineering”, Wiley India (P) Ltd, New Delhi, 2008.

2. Thomas H Lee, “Planar Microwave Engineering: A Practical Guide to Theory, Measurements and Circuits”, Cambridge University Press, 2004.

3. Mathew M Radmanesh, “RF and Microwave Electronics”, Prentice Hall, 2000.

4. Annapurna Das and Sisir K Das, “Microwave Engineering”, Tata Mc Graw Hill Publishing Company Ltd, New Delhi, 2005.

Subject Name RF and microwave engineering
Subject code EC6701
Regulation 2013

EC6701 RF and microwave engineering Notes click here to download

EC6701 RF and microwave engineering Syllabus

EC6701 RF and microwave engineering Important questions

EC6701 RF and microwave engineering Question Bank

 

Categories
UG syllabus R 2013

EC6701 RF AND MICROWAVE ENGINEERING SYLLABUS REGULATION 2013 ANNA UNIVERSITY

EC6701 RF AND MICROWAVE ENGINEERING SYLLABUS REGULATION 2013 ANNA UNIVERSITY

EC6701 RF AND MICROWAVE ENGINEERING SYLLABUS

EC6701 RF and microwave engineering syllabus regulation 2013 anna university free download. RF and microwave engineering EC6701 syllabus pdf free download.

UNIT I TWO PORT NETWORK THEORY EC6701 RF and microwave engineering syllabus

Review of Low frequency parameters: Impedance, Admittance, Hybrid and ABCD parameters, Different types of interconnection of Two port networks, High Frequency parameters, Formulation of S parameters, Properties of S parameters, Reciprocal and lossless Network, Transmission matrix, RF behavior of Resistors, Capacitors and Inductors.

UNIT II RF AMPLIFIERS AND MATCHING NETWORKS EC6701 RF and microwave engineering syllabus

Characteristics of Amplifiers, Amplifier power relations, Stability considerations, Stabilization Methods, Noise Figure, Constant VSWR, Broadband, High power and Multistage Amplifiers, Impedance matching using discrete components, Two component matching Networks, Frequency response and quality factor, T and Pi Matching Networks, Microstrip Line Matching Networks.

UNIT III PASSIVE AND ACTIVE MICROWAVE DEVICES EC6701 RF and microwave engineering syllabus

Terminations, Attenuators, Phase shifters, Directional couplers, Hybrid Junctions, Power dividers, Circulator, Isolator, Impedance matching devices: Tuning screw, Stub and quarter wave transformers. Crystal and Schottkey diode detector and mixers, PIN diode switch, Gunn diode oscillator, IMPATT diode oscillator and amplifier, Varactor diode, Introduction to MIC.

UNIT IV MICROWAVE GENERATION EC6701 RF and microwave engineering syllabus

Review of conventional vacuum Triodes, Tetrodes and Pentodes, High frequency effects in vacuum Tubes, Theory and application of Two cavity Klystron Amplifier, Reflex Klystron oscillator, Traveling wave tube amplifier, Magnetron oscillator using Cylindrical, Linear, Coaxial Voltage tunable Magnetrons, Backward wave Crossed field amplifier and oscillator.

UNIT V MICROWAVE MEASUREMENTS EC6701 RF and microwave engineering syllabus

Measuring Instruments : Principle of operation and application of VSWR meter, Power meter, Spectrum analyzer, Network analyzer, Measurement of Impedance, Frequency, Power, VSWR, Q-factor, Dielectric constant, Scattering coefficients, Attenuation, S-parameters.

Subject Name RF and microwave engineering
Subject code EC6701
Regulation 2013

EC6701 RF and microwave engineering Syllabus click here to download

EC6701 RF and microwave engineering Notes

EC6701 RF and microwave engineering Important questions

EC6701 RF and microwave engineering Question Bank

 

Categories
question bank

EC6503 Transmission Lines and Wave Guides question bank Regulation 2013 Anna University

EC6503 Transmission Lines and Wave Guides question bank Regulation 2013 Anna University

EC6503 Transmission Lines and Wave Guides question bank

EC6503 Transmission Lines and Wave Guides question bank Regulation 2013 Anna University free download. Transmission Lines and Wave Guides EC6503 question bank pdf free download.

Sample EC6503 Transmission Lines and Wave Guides question bank:

1. For a symmetrical network, define propagation constant and characteristic impedance. M-11

2. What are the advantages of m-derived filters? M-11

3. A constant-K T-section high pass filter has a cutoff frequency of 10 KHz. The design impedance is 600 ohms. Determine the value of L. N-10 (ec6503 transmission lines and wave guides question bank)

4. What are the advantages of m-derived filters? N-10 N-09

5. If Zoc =1000Ω and Zsc =360Ω, determine the Zo of the symmetrical network. N-09

6. What are the disadvantages of constant-k prototype filter section? M-09 (ec6503 transmission lines and wave guides question bank)

7. Find L and C of a low pass T section constant-k filter having a cutoff frequency of 1.8KHz and load of 500ohms. M-09

8. What are the demerits of constant k filters? N-08

9. Design a prototype low pass filter T section of design impedance Ro =500Ω and cutoff frequency fc=2000Hz N-08

10. Compare constant K and m-derived filters. M-08 (ec6503 transmission lines and wave guides question bank)

11. Determine the value of C required by a prototype high pass T-section filter having a cutoff frequency of 1KHz to work into a 600ohms load resistance.
M-08

12. Draw a simple High-pass filter section and give the values of circuit elements. N-07

13. Draw a simple Band-pass filter network and give the values of circuit elements. N-07

14. What are called cut-off frequencies in the design of filters? M-07 (ec6503 transmission lines and wave guides question bank)

15. What is constant-K filters? M-07

16. What are the properties of band elimination filter? M-07

17. How the resonant frequency is chosen in the m-derived high pass filters? M 07

18. What is constant-k network? N-06

19. How to obtain constant-k high pass filter? N-06

20. Define characteristics impedance of a network. M-06

21. Define constant-k filters. M-06

22. Why constant K filters are also known as prototype filters? N-05 (ec6503 transmission lines and wave guides question bank)

23. Define cutoff frequency N-05

24. A T section low pass filter has series inductance of 80mH and shunt capacitance of 0.022 μF. Determine the cutoff frequency and the nominal impedance. M-05

25. What are called constants K filters and what are the demerits? M-05

26. What are the characteristics of an ideal filter? N-04

27. Why m-derived filter of L-sections are used as terminations of composite filters? N-04

28. What are the merits of m derived filters? M-04

29. Define neper. What is its relation with Decibels? (ec6503 transmission lines and wave guides question bank)

Subject Name Transmission Lines and Wave Guides
Subject Code EC6503
Regulation 2013

EC6503 Transmission Lines and Wave Guides Question Bank click here to download

EC6503 Transmission Lines and Wave Guides Syllabus

EC6503 Transmission Lines and Wave Guides Notes

EC6503 Transmission Lines and Wave Guides important questions

 

 

Categories
Important question

EC6503 Transmission Lines and Wave Guides Important questions Regulation 2013 Anna University

EC6503 Transmission Lines and Wave Guides Important questions Regulation 2013 Anna University

EC6503 Transmission Lines and Wave Guides Important questions

EC6503 Transmission Lines and Wave Guides Important questions Regulation 2013 Anna University free download. Transmission Lines and Wave Guides EC6503 Important questions pdf free download.

Sample EC6503 Transmission Lines and Wave Guides Important questions:

Unit I

1. Discuss in detail about inductance loading of telephone cables and derive the attenuation constant, phase constant and velocity of signal transmission for the uniformly loaded cable

2. Explain in detail about the reflection on a line not terminated in its characteristics impedance. (ec6503 transmission lines and wave guides important questions)

3. A distortion less transmission line has attenuation constant α=1.15×10ˉᶟ Np/m, and capacitance of 0.01 n F/m. the characteristic resistance L/C=50Ω find the resistance inductance and conductance per more of the line.

4. A transmission line operating at 500 MHz has Z₀=80Ω, α= 0.04 Np/m, β=1.5 rad/m. Find the line parameter series resistance (R Ω/m), series inductance (L H/m), shunt conductance (G mho/m) and capacitance between conductors (C F/m). (ec6503 transmission lines and wave guides important questions)

5. Derive expression for the attenuation and phase constant of transmission line in constant R,L,G and C.

6. Draw the L-type equivalent circuit model of a two-conductor transmission line and derive the transmission line equations.

7. discuss the theory of open and short circuited lines with voltage and current distribution diagram and also get the input impedance expression.

8. Derive the expression for the input impedance of a transmission line Hence obtain the input impedance for a loss less line (ec6503 transmission lines and wave guides important questions)

9. A transmission line operating at 10⁶ rad/s has α= 8 d B/m, β= 1 rad/m. and z₀= 60+ j40ohms, and is 2meter long. The line is connected to a source of 10 v, Zg=40ohms and terminated by a load of 20 + j50ohms. Determine the current at the middle of the line.

Unit II EC6503 Transmission Lines and Wave Guides Important questions

1. Explain the application of smith chart A 30 m long loss less transmission line with Z0=50ohms operating at 2 MHz is terminated with a load ZL=60+j40ohms if U=0.6C find the reflection coefficient y, the standing wave ratios and the input impedance

2. Derive equation of attenuation constant and phase constant of transmission line in terms of line constants R, L, C and G and explain the significance of reflection coefficient and insertion loss (ec6503 transmission lines and wave guides important questions)

3. Derive the expression that permit easy measurement of power flow on a line of negligible losses

Subject Name Transmission Lines and Wave Guides
Subject Code EC6503
Regulation 2013

EC6503 Transmission Lines and Wave Guides Important questions click here to download

EC6503 Transmission Lines and Wave Guides Syllabus

EC6503 Transmission Lines and Wave Guides Notes

EC6503 Transmission Lines and Wave Guides Question Bank

 

Categories
r2013 notes

EC6503 Transmission Lines and Wave Guides Notes Regulation 2013 Anna University

EC6503 Transmission Lines and Wave Guides Notes Regulation 2013 Anna University

EC6503 Transmission Lines and Wave Guides Notes

EC6503 Transmission Lines and Wave Guides Notes Regulation 2013 Anna University free download. Transmission Lines and Wave Guides EC6503 Notes pdf free download.

OBJECTIVES: EC6503 Transmission Lines and Wave Guides Notes

To introduce the various types of transmission lines and to discuss the losses associated. To give thorough understanding about impedance transformation and matching. To use the Smith chart in problem solving. To impart knowledge on filter theories and waveguide theories

OUTCOMES: EC6503 Transmission Lines and Wave Guides Notes

Upon completion of the course, students will be able to:

Discuss the propagation of signals through transmission lines. Analyze signal propagation at Radio frequencies.

Explain radio propagation in guided systems. Utilize cavity resonators.

TEXT BOOKS EC6503 Transmission Lines and Wave Guides Notes

1. John D Ryder, “Networks, lines and fields”, 2nd Edition, Prentice Hall India, 2010.

REFERENCES EC6503 Transmission Lines and Wave Guides Notes

1. E.C.Jordan and K.G. Balmain, “Electromagnetic Waves and Radiating Systems”, Prentice Hall of India, 2006.

2. G.S.N Raju “Electromagnetic Field Theory and Transmission Lines” , Pearson Education, First edition 2005.

A TRANSMISSION LINE is a device designed to guide electrical energy from one point to another. It is used, for example, to transfer the output rf energy of a transmitter to an antenna. This energy will not travel through normal electrical wire without great losses.

Although the antenna can be connected directly to the transmitter, the antenna is usually located some distance away from the transmitter.
On board ship, the transmitter is located inside a radio room, and its associated
antenna is mounted on a mast. ec6503 transmission lines and wave guides notes

A transmission line is used to connect the transmitter and the antenna. The transmission line has a single purpose for both the transmitter and the antenna. This purpose is to transfer the energy output of the transmitter to the antenna with the least possible power loss. How well this is done depends on the special physical and electrical characteristics (impedance and resistance) of the transmission line.

Subject Name Transmission Lines and Wave Guides
Subject Code EC6503
Regulation 2013

EC6503 Transmission Lines and Wave Guides Notes click here to download

EC6503 Transmission Lines and Wave Guides Syllabus

EC6503 Transmission Lines and Wave Guides important questions

EC6503 Transmission Lines and Wave Guides Question Bank

 

Categories
UG syllabus R 2013

EC6503 Transmission Lines and Wave Guides Syllabus Regulation 2013 Anna University

EC6503 Transmission Lines and Wave Guides Syllabus Regulation 2013 Anna University

EC6503 Transmission Lines and Wave Guides Syllabus

EC6503 Transmission Lines and Wave Guides Syllabus Regulation 2013 Anna University free download. Transmission Lines and Wave Guides EC6503 Syllabus pdf free download.

UNIT I TRANSMISSION LINE THEORY EC6503 Transmission Lines and Wave Guides Syllabus

General theory of Transmission lines – the transmission line – general solution – The infinite line – Wavelength, velocity of propagation – Waveform distortion – the distortion-less line – Loading and different methods of loading – Line not terminated in Z0 – Reflection coefficient – calculation of current, voltage, power delivered and efficiency of transmission – Input and transfer impedance – Open and short circuited lines – reflection factor and reflection loss.

UNIT II HIGH FREQUENCY TRANSMISSION LINES EC6503 Transmission Lines and Wave Guides Syllabus

Transmission line equations at radio frequencies – Line of Zero dissipation – Voltage and current on the dissipation-less line, Standing Waves, Nodes, Standing Wave Ratio – Input impedance of the dissipation-less line – Open and short circuited lines – Power and impedance measurement on lines – Reflection losses – Measurement of VSWR and wavelength.

UNIT III IMPEDANCE MATCHING IN HIGH FREQUENCY LINES EC6503 Transmission Lines and Wave Guides Syllabus

Impedance matching: Quarter wave transformer – Impedance matching by stubs – Single stub and double stub matching – Smith chart – Solutions of problems using Smith chart – Single and double stub matching using Smith chart.

UNIT IV PASSIVE FILTERS EC6503 Transmission Lines and Wave Guides Syllabus

Characteristic impedance of symmetrical networks – filter fundamentals, Design of filters: Constant K – Low Pass, High Pass, Band Pass, Band Elimination, m- derived sections – low pass, high pass composite filters.

UNIT V WAVE GUIDES AND CAVITY RESONATORS EC6503 Transmission Lines and Wave Guides Syllabus 

General Wave behaviours along uniform Guiding structures, Transverse Electromagnetic waves, Transverse Magnetic waves, Transverse Electric waves, TM and TE waves between parallel plates, TM and TE waves in Rectangular wave guides, Bessel’s differential equation and Bessel function, TM and TE waves in Circular wave guides, Rectangular and circular cavity Resonators.

Subject Name Transmission Lines and Wave Guides
Subject Code EC6503
Regulation 2013

EC6503 Transmission Lines and Wave Guides Syllabus click here to download

EC6503 Transmission Lines and Wave Guides Notes

EC6503 Transmission Lines and Wave Guides important questions

EC6503 Transmission Lines and Wave Guides Question Bank