Importance  Electronics Engineering
List of importance for Second year  Sem 3 and Sem 4
Semester 3
APPLIED Maths III
COMPLEX VARIABLES
CauchyRiemann Equation (Cartisian Coordinates) and constants C.R Equations in PolarCoordinates Harmonic functions Find Analytic function when real and imaginary part are given. Find Analytic function when imaginary part are given. Find Analytic function when U+V and UV is given. Find Analytic function when harmonic function is given. Orthogonal curves (To find orthogonal tragectory means to find imaginary part equation) LAPLASE TRANSFORM Normal L.T  Standard form Evaluation of standard L.T Change of scale property First shifting theorem Evaluation of such integrals. (put exact value of s) Evaluation of such integrals. (put the value of s) Effect of multiply by 't' Effect of Divide by 't' Problems on simple Inverse Laplase transform Methods of obtaining I.L.T a) use of standard results b) Use of shifting theorem c)Method of partial fraction d)Use of change of scaleproperty e)Convolution Theorem f) Use of differentiation. g)Use of Integration Laplase transform of periodic function 
FOURIER SERIES
Fourier Expansion for f(x) in Interval Fourier series in (c, c+2l) Fourier series of even and odd function(l,l) Half range series COMPLEX FORMS OF FOURIER SERIES Complex forms in (c, c+2l) and other intervals. Orthogonal and Orthonormal Fourier Integral theorem Fourier Sine and Cosine Integrals VECTOR ALGEBRA Scalar product Scalar triple product Vector product Volume of Parallelopiped Volume of tertahedron Vector triple product BESSEL FUNCTION Solution of Bessel Differential Equation: Series method, recurrence relation, properties of Bessel function of order +1/2 and 1/2 Bessel Fourier series of functions 
ED
1. Zener diode as voltage regulator
2. Construction and VI characteristics of IGBT 3. Explain two terminal MOS structure 4. Short note : HBT 5. Discuss EbersMoll model for BJT in detail 6. Construction and working of SCR 7. Explain working and characteristics of Tunnel diode 8. Explain types of junction breakdown in case of zener diode 9. Compare Enhancement type and Depletion type MOSFET on the basis of their construction, working principle, characteristics and biasing 10. Short note on: MESFET, DIACTRIAC 11. Working of Solar cell explain construction, working and VI characteristics also explain what is the need to connect solar cells in series on in parallel fashion 12. Explain structure, construction and working of IMPATT diode. 
13. Characteristics of Schottky diode
14. How PUT is different than UJT 15. What do you mean by different transistor models, explain Hybrid Pi model 16. Give advantages of MESFET over MOSFET, explain basic principle of operation of MESFET 17. Derive equation of threshold voltage of a N channel MOSFET, also derive threshold voltage equation in generalized form 18. Explain working of BJT considering all possible current density components in a NPN transistor operating in Active mode 19. Explain channel length modulation in MOSFET 20. Explain UJT relaxation oscillator 21. Short note on: Optocoupler, Gunn diode 22. Derive equation of threshold voltage of a N channel MOSFET, also derive threshold voltage equation in generalized form. 
DCD
1. Write VHDL code for full adder
2. Shift register and its applications 3. Explain PLA and PAL 4. Interfacing between CMOS and TTL 5. Design Mealy sequence detector using D flipflops and logic gates 6. Construct ring counter using IC 74194 and the output waveform 7. Implementation of the following function using N:1 MUX and logic gates 8. Sums based on Kmap 9. Short note on: JTAG and BIST 10. XC 4000 FGPA architecture block diagram 11. Design 6bit up counter using IC 74163 and draw circuit diagram along with its working 12. Xilinx XC 9500 CPLD architecture 
13. Short note on: Multiplexers
14. Design 4 bit Johnson counter using JK FF. Explain operation using waveforms 15. Noise Margin 16. Compare synchronous and asynchronous counter 17. Explain fan in , fan out, power dissipation and noise immunity with reference to digital ICs 18. Automatic test pattern Generation 19. Draw circuit diagram for CMOS inverter. Draw transfer characteristics and explain its operation. 20. Explain Mealy Moore sequential machine 21. Internal block diagram of IC 7490 
CT
1. Obtain transmission parameters (ABCD) in terms of Zparameters
2. List types of damping in series RLC circuit diagram and mention the condition for each damping
3. Sums based on Source shifting technique
4. Sums based on FosterI, FosterII, CauerI and CauerII using RC or RLC or RL
5. Obtain S domain equivalent circuit diagram of an inductor and capacitor with initial condition
6. Designing of short circuit shunt stub match using Smith chart
7. Sums based on Thevinin’s theorem
8. Explain various types of filters
9. Derive expression for characteristics equation of a transmission line. Also obtain α, ß and γ of the line
10. Sums based on determining currents when t=0 i.e. closed switch, t>0 and t<0 i.e. open switch.
11. Sums based on Superposition theorem
12. What are scattering parameters. State its properties
13. State the condition for reciprocity of hparameter and prove it
14. Define tparameter and relate them to other parameters
15. What are standing waves. Define reflection coefficient and VSWR of a transmission line.
2. List types of damping in series RLC circuit diagram and mention the condition for each damping
3. Sums based on Source shifting technique
4. Sums based on FosterI, FosterII, CauerI and CauerII using RC or RLC or RL
5. Obtain S domain equivalent circuit diagram of an inductor and capacitor with initial condition
6. Designing of short circuit shunt stub match using Smith chart
7. Sums based on Thevinin’s theorem
8. Explain various types of filters
9. Derive expression for characteristics equation of a transmission line. Also obtain α, ß and γ of the line
10. Sums based on determining currents when t=0 i.e. closed switch, t>0 and t<0 i.e. open switch.
11. Sums based on Superposition theorem
12. What are scattering parameters. State its properties
13. State the condition for reciprocity of hparameter and prove it
14. Define tparameter and relate them to other parameters
15. What are standing waves. Define reflection coefficient and VSWR of a transmission line.
EIM
1. Write specifications of analog multimeter
2. Compare electronic voltmeter and Conventional Analog voltmeter 3. Draw and explain Maxwell bridge 4. Block diagram of CRO 5. Wheatstone bridge 6. Liquid level measurement using capacitive type method and LVDT 7. PC based instrumentation system 8. Explain multichannel data acquisition system 9. Discuss working principle of RTD, Thermistor and Thermocouple. 10. Discuss role of delay line in CRO 11. Explain linear variable differential transformer 12. Define error and explain classification of errors and methods to eliminate it during measurement. 13. Explain various flow meter 14. Resistance strain gauge 15. Explain DSO along with applications 16. Draw Schering bridge and give its applications 
17. Explain importance of Lissaious figure in detection of frequency and phase
18. Draw and explain low, medium and high measurement techniques in detail 19. Short note on: Data logger 20. Explain capacitive transducer for displacement measurement along with its expression 21. Explain classification and selection criteria of transducer 22. Construction of magnetic flow meter 23. Short note: Dead Weight Tester 24. Compare Maxwell bridge and Hey bridge for measurement of inductance 25. Explain digital multimeter 26. Explain monitoring instruments 27. Capacitance sensor 
Semester 4
dec  Importance
Chapter No 1 : Frequency Response and Multistage Amplifiers
Chapter No 2 : Differential Amplifiers
Chapter No 3 : Integrated circuits Biasing techniques

Chapter No 4 : Power Amplifiers
Chapter No 5 : Fundamentals of OPAMP
Chapter No 6 : Application of OPAMP
Chapter No 7 : DC regulated power supply

Maths iv  Importance
MODULE 1
Chapter No 1 : Calculus of variation Euler's Langrange Equation and its solutions. Independent of variables Independent of differentiation of a variable Find extremal (Types problems) RayleighRitz method. MODULE 2 Chapter No 2 : Linear Algebra vector Space Vectors in ndirectional vector space (dot product, cross product, norm & Distance property) Cauchyschwartz inequality Orthogonal Subspaces Gram Schmidt Method 
MODULE 3
Chapter No 3 : Linear Algebra Matrix Theory Prove Eigen values of Hermitian matrix are real Eigen values and Eigen vectors Functions of Square matrix , Derogatory and nonderogatory matrix Quadratic forms CayleyHamilton theorem MODULE 4 Chapter No 4 : Complex VariablesIntegration Complex Integration Taylor's and Laurent's series Zero's,singularities,Poles and Residues Cauchy's Residue theorem 
mpp  Importance
Chapter No 1 : Basic laws of electromagnetic and Maxwell’s equations
Give significance for boundary conditions for electric field. Boundary conditions  Short Note Can you use CRO for the ratio of charge and mass of electron. Solve the given Laplase equation (any equation will be given) Write the Maxwell equation in the point form and integral form explain the significance of each equation. What is magnetic dipole how does it differ from electric dipole. Write the integral form of Ampere’s law and interprete the same. Give boundary conditions for Electric and magnetic field for interface between good conductor and dielectric. Prove that static electric field is irrotational and static magnetic field is solenoidal. Chapter No 2 :Uniform Plane wave equation and power balance Solution of the wave equation in the free space Define intrinsic Impedance and find its value for the free space. State poyntingtheorem .what are the pointing vector. Explain scalar and vector potential. Derive wave equation for good dielectric medium. Chapter No 3 : Plane wave propagation. Write a note on propagation of wave in different mediums. Give the behaviour of wave for normal incidence in dielectric media Explain the parallel and perpendicular polarization of wave. What is depth of penetration. Explain Reflection of Uniform plane wave at oblique incidence. 
Chapter no 4 : Computational electromagnetics
Numerical problems based on FEM, FDM and MOM Compare FDM,MOM and FEM What are the advantages of using the triangular Mesh in the FEM Give and explain various steps involved in finding characteristic impedance for microstrip line using finite difference Method. Derive an expression for magnetic field intensity due to finite long straight element. Chapter No 5 : Radio Wave propagation Explain plane earth reflection on horizontally and vertically polarized wave. Explain super refraction and tropospheric fading. What do you mean by fading ?how it can be minimised ? Chapter no 6 : Sky wave propagation Derive relation between MUF and skip distance. Explain Ray path and critical frequency. Write a note on Ionospheric propagation. 
pcs  Importance
Chapter No 2: Introduction to intel 8085 Miucroprocessor
Chapter No 3: Intel 8086 Architecture
Chapter No 4: Instruction set of 8086 and programming
Chapter No 5: Assembly Language programming and debugging
Chapter No 7: 8086 Interrupt structure
Chapter No 8: IC 8259 Programmable Interrupt controller

Chapter No 9: 8255 Programmable Peripheral interface
Chapter no 10: 8254 Programmable interval Timer
Chapter No 11: 8257 DMAC
Chapter No 12: ADC,DAC Interfacing with 8086 and its applications
Chapter No 13: 8087 Math Coprocessor and Multiprocessor system
Chapter No 14: 8086 Microprocessor interfacing Design 8086 Microprocessor based system (specification will be given) Chapter No 15: Advanced Microprocessors

fce  importance
Chapter No 1 : Overview of System and signals (15 Marks)
Chapter No 2 : Classification of Systems
Chapter No 3 : Linear Time invariant systems
Chapter No 4 : Laplace Transform

Chapter No 5 : ZTransform
Chapter No 6 : Analysis of Discrete Time LTI systems using Ztransform
Chapter No 7 : Fouries series
Chapter No 8 : Continuous Time Fourier Transform
Chapter No 9 : Discrete time Fourier transform
