Exam Details
| Subject | electromagnetic fields | |
| Paper | ||
| Exam / Course | b.e.(electronics and instrumentation engineering) | |
| Department | ||
| Organization | SETHU INSTITUTE OF TECHNOLOGY | |
| Position | ||
| Exam Date | May, 2017 | |
| City, State | tamil nadu, pulloor |
Question Paper
Reg. No.
B.E. B.Tech. DEGREE EXAMINATION, MAY 2017
Fourth Semester
Electronics and Communication Engineering
01UEC403 ELECTROMAGNETIC FIELDS
(Regulation 2013)
Duration: Three hours Maximum: 100 Marks
Answer ALL Questions
PART A (10 x 2 20 Marks)
1. State Divergence theorem.
2. Define Electric potential.
3. State Ampere's circuital law.
4. Define magnetic vector potential.
5. Define polarization.
6. Distinguish between scalar and magnetic vector potential.
7. State Lenz's law.
8. What is displacement current density?
9. Write the equation for skin depth of a conductor.
10. What are the standing waves?
PART B x 16 80 Marks)
11. Using Gauss's law, calculate the E due to infinitely large uniformly charged plate.
Or
Question Paper Code: 31443
2
31443
Given point and vector A yax+ express P and A in cylindrical and spherical coordinates. Evaluate A at P in the Cylindrical and spherical systems.
12. Derive the expression for the magnetic field intensity inside and outside a co-axial conductor of inner radius outer radius b and carrying a current of I amperes in the inner and outer conductors.
Or
Derive a general expression for the magnetic flux density B at any point along the axis of a long solenoid. Sketch the variation of B from point to point along the axis.
13. State and derive electric boundary conditions for a dielectric to dielectric medium and a conductor to dielectric medium.
Or
Conducting spherical shells with radii a 10 cm and b 30 cm are maintained at a potential difference of 100 V such that V(r 0 and V(r 100 V. Determine V and E in the region between the shells. If εr 2.5 in the region, determine the total charge induced on the shells and the capacitance of the capacitor.
14. State Ampere's circuital law and prove the modified form of Ampere's circuital law as Maxwell's first equation in integral form.
Or
Derive and explain Maxwell's equations both in integral and point forms.
15. Derive the electromagnetic wave equations in frequency domain and obtain the expressions for intrinsic impedance and propagation constant for free space, conductor and dielectric medium.
Or
Discuss about normal incidence and oblique incidence with respect to plane waves.
B.E. B.Tech. DEGREE EXAMINATION, MAY 2017
Fourth Semester
Electronics and Communication Engineering
01UEC403 ELECTROMAGNETIC FIELDS
(Regulation 2013)
Duration: Three hours Maximum: 100 Marks
Answer ALL Questions
PART A (10 x 2 20 Marks)
1. State Divergence theorem.
2. Define Electric potential.
3. State Ampere's circuital law.
4. Define magnetic vector potential.
5. Define polarization.
6. Distinguish between scalar and magnetic vector potential.
7. State Lenz's law.
8. What is displacement current density?
9. Write the equation for skin depth of a conductor.
10. What are the standing waves?
PART B x 16 80 Marks)
11. Using Gauss's law, calculate the E due to infinitely large uniformly charged plate.
Or
Question Paper Code: 31443
2
31443
Given point and vector A yax+ express P and A in cylindrical and spherical coordinates. Evaluate A at P in the Cylindrical and spherical systems.
12. Derive the expression for the magnetic field intensity inside and outside a co-axial conductor of inner radius outer radius b and carrying a current of I amperes in the inner and outer conductors.
Or
Derive a general expression for the magnetic flux density B at any point along the axis of a long solenoid. Sketch the variation of B from point to point along the axis.
13. State and derive electric boundary conditions for a dielectric to dielectric medium and a conductor to dielectric medium.
Or
Conducting spherical shells with radii a 10 cm and b 30 cm are maintained at a potential difference of 100 V such that V(r 0 and V(r 100 V. Determine V and E in the region between the shells. If εr 2.5 in the region, determine the total charge induced on the shells and the capacitance of the capacitor.
14. State Ampere's circuital law and prove the modified form of Ampere's circuital law as Maxwell's first equation in integral form.
Or
Derive and explain Maxwell's equations both in integral and point forms.
15. Derive the electromagnetic wave equations in frequency domain and obtain the expressions for intrinsic impedance and propagation constant for free space, conductor and dielectric medium.
Or
Discuss about normal incidence and oblique incidence with respect to plane waves.
Other Question Papers
Subjects
- advanced sensor
- analog circuits
- analog communication
- analytical instruments
- antenna and wave propagation
- application of instrumentation in aerospace and navigation
- applied digital signal processing
- biomedical instrumentation
- circuit theory
- communication engineering
- computer architecture and organization
- control engineering
- data communication and networks
- data structures and algorithm analysis
- data structures and algorithms
- digital communication
- digital electronics
- digital electronics and design
- digital image processing
- digital signal processing
- electrical circuits and networks
- electrical machines
- electrical measurements
- electromagnetic fields
- electronic circuits
- electronic measurements and instrumentation
- embedded and real time systems
- environmental monitoring instruments
- environmental science and engineering
- fibre optics and laser instruments
- high speed networks
- industrial data networks
- industrial electronics
- industrial instrumentation – ii
- industrial instrumentation-i
- information theory and coding
- instrumentation for power plants
- instrumentation system design
- laser and fiber optics instrumentation
- linear control engineering
- linear integrated circuits and applications
- logic and distributed control systems
- microprocessors and interfacing
- microprocessors microcontrollers and applications
- microwave engineering
- mobile ad-hoc networks
- modern electronic instrumentation
- nano electronics
- numerical methods
- optical communication and networks
- principles of electrical machines
- probability and random processes
- process control instrumentation
- project management and finance
- qualitative and quantitative aptitude
- real time embedded systems architecture
- reliability and safety engineering
- robotics and automation
- satellite communication principles and applications
- sensors and transducers
- signals and systems
- thermodynamics and fluid mechanics
- transforms and partial differential equations
- transmission lines and waveguides
- value education and human rights
- vlsi design
- vlsi system design
- wireless communication systems
- wireless sensor networks