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Transmission and Wave Guides – EC 1305 ( TLW ) Previous Year Question Paper for 5th Semester ECE – Anna University


Anna Univ Question Paper

Download Anna University Previous Year Question Paper for  TLW – Transmission & Wave Guides  EC 1305 5th Semester ECE ( ELECTRONICS & COMMUNICATION ENGINEERING ) .



Type          :    Questions

Semester  :    5th Sem

Branch       :    Electronics & Communication Engineering ( ECE )

Exam          :     Nov/Dec ( ODD )

Subject       :     Transmissions and Wave Guides ( TLW )


Download Anna Univ Prev Year Question Paper for TLW

(Regulation 2004)
PART A-[10 x 2 = 20] – Two mark Questions for TLW

1.What is propagation constant ? Which are its two components?
2.State the condition for distortionless line.
3.If the reflection co-efficient of a line is 0.3 ?_?-66?^° ¦ ,calculate the standing wave ratio.
4.What is the value of Z_° for the dissipationless line?
5.What are the characteristics of TEM wave?
6.Write Maxwell’s equations in point form.
7.A rectangular waveguide with dimensions a=8.5cm and b=4.3cm .Determine the cut-off frequency for ?TM?_10 mode of propagation.
8.What is meant by dominant mode of the wave?
9.What is meant by cavity resonator?
10.What is the dominant mode in circular waveguide ? Why ?

PART B ( 16 Mark Questions for TLW ) 

11 . (a)(i) Derive the expression for voltage and current at any point on a transmission line in terms of receiving end voltage and current.[Marks 10] 11.(a)(ii) A line has the following primary constants
R=100 ?/km L=0.001 H/km
G=1.5 µv/km C=0.062 µF/km.
Find the characteristic impedance and the propagation constant .[Marks 6] (or)
11(b)(i) Derive Campbell’s equation.[Marks 8] 11.(b)(ii) A generator of 1V,1kHz supplies power to a 100km transmission line terminated in 200 ? resistance. The line parameters are R=10?/km, L=3.8 mH/km, G=1µv/km, C=0.0085 µF/km Calculate the input impedance and reflection coefficient.[Marks 8]

12(a)(i)Define standing wave ratio and obtain the expression of VSWR in terms of reflection coefficient.[Marks 8] 12.(a)(ii) Derive the input impedance of a quarter wave line and discuss its applications.[Marks 8] (or)
12.(b)(i) Obtain the length and the location of a short circuited stub for impedance
matching on a transmission line.[Marks 10] 12.(b)(ii) A load (50-j100)? is connected to a 50? line. Design a short circuited stub to provide matching between the two at signal frequency of 30Mhz using Smith Chart.[Marks 6]

13.(a)(i) Obtain the solution of field components of a TE wave between parallel plate , propagating in Z direction.[Marks 10] 13.(a)(ii)A pair of perfectly conducting planes are separated by 3.6cm in air. For ?TM?_10 mode determine the cut-off frequency and cut-off wavelength, if the operating frequency is 5Ghz.[Marks 6] (or)
13.(b)(i) Derive the expressions for the field components of TEM waves between parallel conducting planes. Discuss the properties of TEM waves.[Marks 10] 13.(b)(ii)For a frequency of 10 GHz and plane separation of 5cm in air, find the cut-off wavelength, phase velocity and group velocity of the wave.[Marks 6]

14(a) Deduce the expressions for the field components of TM waves guided along rectangular waveguide. [Marks 16] (or)
b ) ( i )Derive the expression of wave impedance for TE and TM waves guided along rectangular waveguide.[Marks 8] (b)(ii) A ?TE?_10 mode is propagated through a waveguide with a=10cm at a frequency of 2.5Ghz.Find the cut-off wavelength, phase velocity, group velocity and wave impedance.[Marks 8]

15.(a)(i) Derive the expressions for the field components of TE waves guided along circular waveguide.[Marks 10] (a)(ii) A circular waveguide has an internal diameter of 6cm.For a 9GHz signal propagated in the ?TE?_11mode,calculate the cut-off frequency and the characteristic impedance [?(ha)?_11^1=1.84].[Marks 6] (or)
(b)(i)Obtain the expression for the resonant frequency of a rectangular cavity resonator.[Marks 8] (b)(ii) Calculate the lowest resonant frequency of a rectangular cavity resonator of dimension a=2cm, b=1cm and d=3cm.[Marks 8]