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DEPARTMENT OF ELECTRONICS
GOVERNMENT SCIENCE COLLEGE (AUTONOMOUS), HASSAN - 573 201
LESSON PLAN OF PAPER I(Basic electronics and Network theorems)
I SEMESTER
Title of the paper: Basic electronics and Network theorems
Sl. No.
Unit 1
Session Topics covered in the session Duration
(hours)
1. 1 Introduction and definition of Electronics. 1
2. 2 Classification of components: Active and Passive. 1
3. 3 Switches: definition and the types of switches (SPST, SPDT,
DPST and DPDT) 1
4. 4 Electric fuse, electromagnetic relay and electronic circuit
bakers and its types. 2
5. 5 Network theorems: Ohm’s law, Kirchoff’s laws (KCL and
KVL): statement and mathematical expression. 1
6. 6 Voltage and current divider theorems. 1
7. 7 Open and Short circuits (in series and parallel), branch
current analysis with related problems 1
8. 8 Mesh analysis, Nodal analysis and steps involved in analysis
procedure and related problems. 2
9. 9 Superposition theorem: statement and steps involved in
theorem 1
10. 10 Thevenin’s theorem, Norton’s theorem and derivation for
inter-conversion. 1
11. 11 Derivation for T to π inter-conversion and related problems 2
12. 12
Reciprocity theorem: statement and explanation
Maximum power transfer theorem: statement and derivation
and problems
2
Total 16
Sl. No.
Unit 2
Session Topics covered in the session Duration
(hours)
1. 1 Introduction to Transient response 1
2. 2
Series RC circuit excited by DC source
1) Charging of a capacitor through a resistor
2) Discharging Of a capacitor through a resistor and
problems
2
3. 3
Series RL circuit excited by DC source
1) Rising current in series RL circuit
2) Decaying current in series RL circuit and Problems
2
4. 4 Series RC circuit connected to an AC source
1) Vector Diagram of the Resultant voltage and Problems 1
5. 5 Series RL circuit connected to an AC source
1) Vector Diagram of the Resultant Voltage and problems 1
6. 6 AC applied to a series RLC circuit and problems 1
7. 7 AC applied to a parallel RLC circuit and problems 1
8. 8
Series resonance
1) Bandwidth of a Series Resonance Circuit
2) Quality factor of the series resonant circuit and problems
3
9. 9
Parallel resonance
1) Frequency response of a parallel resonance circuit
2) Bandwidth and selectivity of a parallel resonance circuit
and problems
3
10. 10 Numerical problems and recap 1
Total 16
Sl. No.
Unit 3 : Electronic active components and applications:
Session Topics covered in the session Duration
(hours)
1. 1 Introduction to electronic active components and
applications. 1
2. 2 Construction, working and characteristics of diodes: PN
junction diode – DC load line, Zener diode and LED. 2
3. 3 Rectifiers: Half wave rectifier, Full wave rectifier - centre
tapped and bridge. 2
4. 4
Circuit diagrams, working and waveforms - ripple factor &
efficiency (with derivations), comparison and numerical
problems
2
5. 5
Filters: Types - Capacitor filter (with derivation for ripple
factor), series inductor filter, LC filter, CLC filter, circuit
diagram and explanation. Ripple factor equations (mention
only)
3
6. 6
Zener diode regulator: Circuit diagram and explanation for
load and line regulation, disadvantages of Zener diode
regulator, numerical problems.
3
7. 7 Transistor series regulator circuit diagram and working. 1
8. 8
Pulse Circuits: Clippers and clampers: Construction and
working – positive, negative and biased.
2
Total 16
Sl No
Unit-4 Transistors and Special Purpose devices
Session Topics covered in the session Duration
(hours)
1 1 BJT: Giving introduction to transistor, its definition,
terminals, different types. 1 hr
2 2 Construction and working principle, different
configuration 1
3 3 Definition of α, β and γ. Their interrelation,
numerical problems 2
4 4 Characteristics of transistor CE mode, working of a
transistor as a switch. 1
5 5 FET: introduction, its definition, terminals and
different types. 1
6 6 Construction and working principle of N channel
FET, its characteristics 1
7 7 FET Parameter and their relation Numerical
problems. 1
8 8 Comparison of FET with BJT, introduction to
MOSFET, its types. construction ,working 1
9 9 Characteristics of depletion type and enhancement
type MOSFET 1
10 10 UJT: introduction, construction and working. 1
11 11 Characteristics, intrinsic standoff ratio, numerical
problems. 2
12 12 Relaxation oscillator, derivation of frequency of
oscillation 1
13 13 SCR and its V-I characteristics, DIAC, TRIAC
construction and its working. 1
14 14 Tunnel diode, Varactor diode and Schottky diode. 1
Total hours 16
DEPARTMENT OF ELECTRONICS
GOVERNMENT SCIENCE COLLEGE (AUTONOMOUS), HASSAN - 573 201
LESSON PLAN OF PAPER II (Analog Electronic Circuit Design)
II SEMESTER
Title of the paper: Analog Electronic Circuit Design
Sl.No. Session Topics covered in the session Duration
(hours)
Unit 1 Transistor Biasing and H parameter
1. 1 Transistor Biasing: Introduction and need for biasing 1
2. 2 DC load line, Thermal runaway, and derivation for stability factor 1
3. 3 Base bias (or fixed bias): derivation with circuit diagram and their
advantages and disadvantages 2
4. 4 Derivation for Base bias with emitter feedback with circuit
diagram. 1
5. 5 Derivation for Base bias with collector feedback with circuit
diagram 1
6. 6 Derivation for Base bias with collector feedback with circuit
diagram 2
7. 7 Voltage divider bias: circuit analysis with diagram and derivation 1
8. 8 H-parameter: introduction and definition 1
9. 9 Hybrid equivalent circuit of a CE, CC and CB configurations 3
10. 10 Derivation for input impedance, output impedance, current gain,
voltage gain and power gain 2
11. 11 Merits and demerits of h-parameters 1
Total 16
Unit – 2 : Small Signal Amplifiers
12. 1 Introduction: Single Stage Amplifiers 1
13. 2 Single Stage Amplifiers: Classification of amplifiers based on
different criteria, 1
14. 3 small signal CE amplifier-circuit, working, frequency response,
Gain in decibel,Bandwidth, 2
15. 4 Hybrid model for CE amplifier - derivation for Av, Zin and Zout.
Numerical problems. Swamped amplifier, 2
16. 5 CC amplifier - circuit diagrams& applications (mention only), 2
17. 6 Darlington pair and its applications (mention only). 2
18. 7 Multistage amplifiers: Qualitative study of cascaded stages,
overall gain of multistage amplifier, loading effect. Problems 2
19. 8
Types of coupling – RC coupled, transformer coupled and direct
coupled amplifiers (working, frequency response graph,
advantages and disadvantages for each).
3
20. 9 JFET amplifier in CS mode: Circuit and operation, equivalent
circuit and expression for voltage gain (derivation).Problems. 1
Total 16
Unit 3 : Power and Tuned amplifiers
21. 1 Difference between voltage and power amplifier, classification of
power amplifiers 2
22. 2 Class A, Class B, Class AB, Class C,Class-D 3
23. 3 Class-S amplifiers and their comparisons 2
24. 4 Class A single ended power amplifier–working (Basic Class – A
Amplifier) - overall efficiency (with derivation), 2
25. 5 Transformer coupled Class A power amplifier-working, overall
efficiency (with derivation). 2
26. 6 Circuit operation of Class B push pull power amplifier overall
efficiency (with derivation), 1
27. 7
Circuit operation of complementary symmetry class B push pull
power amplifier overall efficiency (with derivation), crossover
distortion, heat sinks.
2
28. 8
Tuned amplifiers: Single tuned and double tuned amplifiers –
circuit diagram, working and frequency response for each,
limitations of single tuned amplifier, brief note on use of tuned
amplifiers in communication circuits.
3
Total 16
Unit 4 - Feedback circuits and Oscillators
29. 1 Feedback circuits: Types, Effect on gain, input, output resistances
and bandwidth – with derivations. 2
30. 2 Oscillators: Classification, basic principle of oscillations 2
31. 3 Barkhausen criterion (Derivation). 2
32. 4 Tuned Collector, Colpitt’s oscillator 2
33. 5 Hartley oscillators 1
34. 6 Phase shift oscillators 1
35. 7 Wien bridge oscillators 1
36. 8 Frequency and condition for sustained oscillations, 2
37. 9 Crystal oscillators. 1
38. 10
Multivibrators: Monostable, Bistable and Astable multivibrators,
Numerical Problems.
2
Total 16
DEPARTMENT OF ELECTRONICS
GOVERNMENT SCIENCE COLLEGE (AUTONOMOUS), HASSAN - 573201
LESSON PLAN OF PAPER 3:
LINEAR INTEGRATED CIRCUITS AND INSTRUMENTATION
Ill SEMESTER
Title of the paper: Linear Integrated circuits and instrumentation
Sl.No. Session Topics covered in the session Duration
(hours)
Unit 1 : Fundamentals of op-amps and Feedback Amplifiers
1. 1 Introduction to Fundamentals of operational amplifiers 1
2. 2
Fundamentals of operational amplifiers: Block diagram,
Differential amplifier: circuit, working, expression for output
voltage
2
3. 3 Types of differential amplifier connections; op-amp- equivalent
circuit, symbol, pin diagram of IC 741 : Block diagram 1
4. 4 Differential amplifier: circuit, working, expression for output
voltage, types of differential amplifier connections 2
5. 5 Op-amp- equivalent circuit, symbol, pin diagram of IC 741 1
6. 6
Op-amp parameters: input &output offset voltages, input offset
current, input bias current, differential input resistance, input
voltage range, CMRR, SVRR, output resistance, output short
circuit current, supply current, power consumption, slew rate
2
7. 7 Characteristics of ideal and practical op-amps,ideal voltage
transfer curve 1
8. 8 Open loop op-amp configurations: inverting, non-inverting and
differential amplifiers and its limitations 1
9. 9
Op-amp with negative feedback: Inverting amplifier-derivations
for AV, input resistance, output resistance, bandwidth, total output
offset voltage, voltage follower and its features, concept of virtual
ground
3
10. 10
Non-inverting amplifier - derivations for AV, input resistance,
output resistance, bandwidth, total output offset voltage, current to
voltage converter.
2
Total 16
Unit – 2 : Applications of op-amp
11. 1 Introduction: Summing, scaling and averaging amplifiers, 1
12. 2 Inverting and non-inverting configuration – summing, scaling and
averaging amplifiers. 3
13. 3 Differential configuration – subtractor, summing amplifier. 1
14. 4 Instrumentation amplifier: Instrumentation amplifier using
transducer bridge, derivation for output voltage, 2
15. 5 List of applications of instrumentation amplifier. 1
16. 6 Voltage to current converter with floating load, voltage to current
converter with grounded load. Current to voltage converter. 2
17. 7 Integrator and Differentiator: Derivation for the output voltage, 2
output waveforms for sine square and triangular wave inputs.
18. 8 Oscillators: Principles of oscillations 1
19. 9 Types of oscillator- Phase-shift and Wein bridge oscillator-circuit,
working, &expression for frequency of oscillation. 2
20. 10 Square wave generator, triangular wave generator. 1
Total 16
Unit 3 : Active filters and open loop applications
21. 1 Active filters:Definition, Types, advantages and disadvantages
over passive filters. 2
22. 2
First order filters: Low pass, high pass, band pass, band reject and
all pass filters - Circuit diagrams, derivation for gain and cut-off
frequency.
3
23. 3
Second order filters:Low pass, high pass – circuit diagrams,
derivation for gain and cut-off frequency.Higher order filtersand
its advantages and disadvantages.
2
24. 4
Open-loop applications: Comparators -circuit and characteristics,
Schmitt trigger – circuit, expression for VUT, VLT and Vhy,
waveforms.
2
25. 5 Digital to analog converter& its types: binary weighted resistors,
R-2R resistors – circuit, working with derivations. 2
26. 6 Analog to digital converter, successive approximation ADC. 1
27. 7 Clippers and clampers: positive and negative clippers, positive
and negative clampers. 2
28. 8 Small signal rectifiers: Half wave rectifiers, full wave rectifiers –
circuit, working. 2
Total 16
Unit 4 - Timers, Regulators and instrumentation
29. 1 IC 555 Timer : Equivalent circuit and working 1
30. 2
Monostable and Stable multivibrator : Circuit, working
derivations for frequency and duty cycle applications ( Mention
only)
2
31. 3 Voltage regulators : Block diagram, Fixed positive and negative
voltage regulators circuits and it's working 2
32. 4 Adjustable positive and negative voltage regulators circuits and
it's working 1
33. 5 Transducers and Sensors : Classification of transducers, basic
requirement/ characteristics of transducers 1
34. 6 Active and passive transducers 1
35. 7 Resistive ( potentiometer, strain gauge - Theory, types,
temperature compensation and applications) 1
36. 8 Capacitive (variable area type - variable Air gap type - variable
permittivity type) 1
37. 9 Inductive (LVDT) and piezoelectric transducers 1
38. 10 Measurement of displacement velocity and acceleration
(transnational and rotational) 1
39. 11 Measurement of pressure (monometers, diaphragm, bellows) 1
40. 12 Measurement of temperature (RTD, thermostat, thermocouple,
semiconductor IC sensors) 2
41. 13 Light transducers ( photo resistors, photovoltaic cells, photo
diodes) 1
Total 16
DEPARTMENT OF ELECTRONICS
GOVERNMENT SCIENCE COLLEGE (AUTONOMOUS), HASSAN - 573201
LESSON PLAN OF PAPER 4 DIGITAL ELECTRONICS AND VHDL
IV SEMESTER
Digital Electronics and VHDL
Sl.No. Session Topics covered in the session Duration
(hours)
Unit 1: Number systems and Boolean algebra
1. 1. Introduction to Number systems: Binary, Octal and
Hexadecimal number systems. 1
2. 2. Conversion from one system to the another with
examples 1
3. 3. Addition, subtraction, multiplication and division in
binary systems. 1
4. 4.
Representation of negative numbers in binary system.
1’s and 2’s complement, subtraction of binary numbers
using 2’s complement method.
1
5. 5. Boolean algebra: Constants, variables, operators 1
6. 6. Basic logic gates-AND, OR, NOT, logic symbol, truth
table. 1
7. 7. Positive and negative logic, Boolean laws, Duality
Theorem, De Morgan’s Theorem, 1
8. 8. Simplification of Boolean expressions-SOP and POS.
Derived logic gates (NAND, NOR, XOR & XNOR). 2
9. 9. Universal property of NOR and NAND gates. Minterm,
Maxterm, SSOP and SPOS. 1
10. 10. K-Map: 3 and 4 variable expressions simplifications.
Tri-state buffer. 1
11. 11. Logic Families:Pulse characteristics, Logic Families-
classification of digital ICs. 1
12. 12. Characteristics of logic families, circuit description of
TTL NAND gate with totem pole and open collector. 2
13. 13. TTL IC terminology. Circuit description of CMOS
inverter, comparison of TTL and CMOS families.
2
Total 16
Unit 2: VHDL
14. 14. Introduction to Basic Language Elements: Identifiers,
Data Objects, Data Types, Operators 2
15. 15. Behavioural Modelling: Entity Declaration,
Architecture Body 1
16. 16. Process Statement, Variable Assignment Statement 1
17. 17. Signal Assignment Statement, Wait Statement 1
18. 18. If Statement, Case Statement, Null Statement 1
19. 19. Loop Statement, Exit Statement, Next Statement 2
20. 20. Assertion Statement, Report Statement, More on Signal Assignment statement, Other Sequential statements
2
21. 21. Dataflow Modelling: Concurrent Signal Assignment
Statement 2
22. 22. Concurrent versus, Sequential Signal Assignment 2
23. 23. Conditional Signal Assignment Statement Selected
Signal Assignment Statement, The unaffected value. 2
Total 16
Unit 3: Combinational logic circuits
24. 24. Intruduction to combinational circuits 1
25. 25. Half adder and full adder 1
26. 26. Half subtractor and full subtractor 1
27. 27. Parallel adders 1
28. 28. Parity checking codes 2
29. 29. Weighted codes:8421 and 2421 1
30. 30. Self complementary codes 1
31. 31. Non weighted codes: Excess 3 code 1
32. 32. Gray code, Alphanumeric codes 1
33. 33. Multiplexers and De-multiplexers 2
34. 34. Encoders: 2 to 4 line, 3 to 8 line 1
35. 35. Decimal to BCD encoders 1
36. 36. Decoders : 2 to 4 line, 3 to 8 line 1
37. 37. BCD to decimal, Seven segment display 1
Total 16
Unit 4: Sequential logic circuits
38. 38. Introduction to Sequential logic circuits 1
39. 39. RS and clocked flip flops 1
40. 40. Level triggered RS, D, JK and T flip flops 1
41. 41. Race around condition ,edge triggering concept and master slave JK flip flops
2
42. 42. Shift registers : 4-bit SISO,SIPO, PISO and PIPO
registers 2
43. 43. Counters: 3-bit binary ripple counter, 4-bit synchronous
binary counter 2
44. 44. MOD counters : MOD 3,Mod 5 and decade counters
(Design using k-map technique) 1
45. 45. Memory: ROM-diode matrix ROM, on-chip decoding 1
46. 46. RAM : Memory addressing - linear addressing, matrix
addressing 1
47. 47. DRAM and SRAM, Basic memory cell(FF)- reading
from and writing into a memory unit 2
48. 48. List of programmable logic devices - SPLDs, ROM,
PLA, PAL and GAL, CPLD and FPGA 2
Total 16
DEPARTMENT OF ELECTRONICS
GOVERNMENT SCIENCE COLLEGE (AUTONOMOUS), HASSAN - 573 201
LESSON PLAN OF PAPER 5 MICROCONTROLLER
V SEMESTER
Title of the paper: Microcontroller
Sl. No.
Unit 1: Introduction to Microcontrollers
Session Topics covered in the session Duration
(hours)
1. 1 Introduction to microprocessors and Microcontrollers 1
2. 2 A microcontroller survey, (8051, PIC, ARM family) 1
3. 3 Development systems for Microcontrollers 1
4. 4 RISC and CISC CPU Architectures 1
5. 5 Harvard and Von-Neumann CPU Architecture 1
6. 6 Introduction to 8051 architecture 1
7. 7 Pin-out diagram of 8051 microcontroller 1
8. 8 Input/Outputpins 1
9. 9 ports and circuits 1
10. 10 External memory 1
11. 11 Counter and Timers 2
12. 12 Serial Data Input/Output 2
13. 13 Interrupts 1
Total 15
Unit 2: 8051 Addressing modes and Moving Data
14. 1 Introduction to addressing modes and types with examples 1
15. 2 Data transfer instruction, PUSH & POP , XCHG instrucations 1
16. 3 Logical operations, bit level logical operations with examples 1
17. 4 Byte level logical operations, rotate and swap operations 1
18. 5 Instruction affecting flages, incrementing and decrementing
Operations with examples 1
19. 6 Addition, subtraction,multiplication, division operations 2
20. 7 Decimal arithmetic, unsigned and signed addition 1
21. 8 Multiple –byte signed arithmetic, unsigned and signed
subtraction, examples 2
22. 9 Branching instructions 1
23. 10 Bit jumps and Byte jumps, examples 1
24. 11 NOP, Calls and subroutines, return 1
25. 12 Interrupts and interrupt returns 1
26. 13 Difference between RET and RETI 1
total 15
Unit 3
27. 1 Brief Introduction To Counter/ Timer 1
28. 2 Counter/Timer Programming in 8051And relevant
problems 1
29. 3 Programming 8051 Timers/Counters. 1 30. 4 Interrupts Programming:8051 Interrupts 2
31. 5 Programming Timer Interrupts, 1
32. 6 Programming External hardware Interrupts, 1
33. 7 Programming the Serial Communication Interrupts 1
34. 8 Interrupt Priority in the 8051. 1
35. 9 8051 Interfacing and Applications 1
36. 10 Interfacing 8051 to ADC, DAC, And relevant
problems 2
37. 11 Interfacing 8051 to Stepper Motor, 8255, And
relevant problems 2
38. 12 External Memory Interfacing. 1
Total 15
DEPARTMENT OF ELECTRONICS
GOVERNMENT SCIENCE COLLEGE (AUTONOMOUS), HASSAN - 573 201
LESSON PLAN OF PAPER 6 VHDL
V SEMESTER
Title of the paper: VHDL
Sl. No.
Unit 1
Session Topics covered in the session Duration
(hours)
1. 1 Introduction to VHDL 1
2. 2 Identifiers and data objects 1
3. 3 Data types 1
4. 4 Operators 2
5. 5 Entity and architecture declaration 1
6. 6 Process, variable and signal declaration 1
7. 7 Wait and if statement 1
8. 8 Case, null and loop statements 1
9. 9 Exit, next, assertion and report statements 1
10. 10 Inertial and transport delay models 1
11. 11 Creating signal waveforms, signal drivers 1
12. 12 Effect of transport and inertial delay on signal drivers 3
Total 15
Unit 2
13. 1 Brief Introduction Dataflow Modelling:
Other Examples, 1
14. 2 Explain the concept of Concurrent Signal Assignment
Statement, 1
15. 3 Distinguish between Concurrent versus, Sequential Signal
Assignment, 1
16. 4 Explain the concept of Multiple Drivers, 1
17. 5 Conditional Signal Assignment Statement Selected Signal
Assignment Statement, 2
18. 6 The UNAFFECTED Value, Block Statement 1
19. 7 Concurrent Assertion Statement, Value of Signal. 1
20. 8 Brief Introduction to Structural Modeling and its Example, 3
21. 9 Component Declaration, 1
22. 10 Component instantiation, 1
23. 11 Resolving Signal Values and relevant problems 2
Total 15
Unit 3
24. 1 Generics and configurations 1
25. 2 Configuration specifications and configuration declarations 2
26. 3 Conversion functions, direct instantiation and incremental
binding 3
27. 4 Subprograms, functions and procedures 3
28. 5 Subprograms overloading and operator overloading and signatures
2
29. 6 Package declaration and package body 1
30. 7 Design file and design libraries 1
31. 8 Implicit and explicit visibility, library and use clause 2
Total 15
DEPARTMENT OF ELECTRONICS
GOVERNMENT SCIENCE COLLEGE (AUTONOMOUS), HASSAN - 573 201
LESSON PLAN OF PAPER VII (Electronic Communication)
VI SEMESTER
Title of the paper: Electronic Communication
Sl. No.
Unit 1 :
Session Topics covered in the session Duration
(hours)
1. 1 Brief Introduction Communication system, 1
2. 2 Introduction Amplitude modulation theory 1
3. 3 Frequency spectrum of AM wave, Power relation, current
calculation,. 1
4. 4 Modulation by several sine waves 1
5. 5 Generation of AM-Basic requirement, 1
6. 6 Modulated transistor amplifiers 1
7. 7 Introduction, suppression of carrier, Balanced modulator,
suppression of unwanted 1
8. 8
Sideband-Filter system, phase shift method, vestigial
sideband transmission.
1
9. 9 Theory of frequency and phase modulation, frequency
spectrum of FM, 1
10. 10 Observations, bandwidth, phase modulation, intersystem
comparison – FM and PM, FM and AM 2
11. 11 Generation of FM: Direct FM, Basic reactance modulator,
indirect method 1
12. 12 Frequency and Phase modulation: (block diagram only).
1
13. 13
Pulse communication: PAM, PWM, PPM, PCM – Principles
of PCM, quantizing noise, advantages and applications of
PCM
2
Total 15
Sl. No.
Unit 2 :
Session Topics covered in the session Duration
(hours)
1. 1 Introduction to tuned radio frequency receivers, 1
2. 2 Super heterodyne receiver,sensitivity, selectivity, image
frequency and its rejection, 1
3. 3
Double spotting, detection and AGC (Practical diode
detector).
1
4. 4 Balanced slope detector, phase discriminator. 2
5. 5 Transmission lines: Basic principles, characteristic
impedance, losses in transmission lines, standing waves. 1
6. 6 Radiation and propagation of waves: Electromagnetic radiation, fundamentals of EM waves,
2
7. 7 propagation of waves-ground waves, sky waves, space
waves, tropospheric scatter propagation 1
8. 8 Antennas: Basic considerations, EM radiation, resonant and
non-resonant antennas, 1
9. 9 antenna gain and effective radiated power, field intensity,
antenna resistance, bandwidth, beam width 2
10. 10 Polarization, antenna with parabolic reflector. (Geometry of
parabola, properties of paraboloidal reflector). 2
1. 11 Numerical Problems 1
Total
15
Sl. No.
Unit 3 :
Session Topics covered in the session Duration
(hours)
1. 1 Brief Introduction to Satellite communication 1
2. 2 Introduction, orbits, station keeping, transmission paths, 1
3. 3 path loss, noise considerations. 1
4. 4 The satellite communication system, saturation flux density, 2
5. 5 effective isotropic radiated power, multiple access methods, 2
6. 6 SPADE, TDMA. 1
7. 7 Introduction, Fiber optic systems, characteristics, optical
fiber, 2
8. 8 fiber types, fiber performance, fiber optic sources, 2
9. 9 optical measurement terminology and parameters, 1
10. 10 optical detector, optical wavelength. 1
11. 11 Numerical Problems 1
Total 15
DEPARTMENT OF ELECTRONICS
GOVERNMENT SCIENCE COLLEGE (AUTONOMOUS), HASSAN - 573 201
LESSON PLAN OF PAPER VIII (Digital Signal Processing)
VI SEMESTER
Title of the paper: Digital signal processing
Sl. No.
Unit 1 :
Session Topics covered in the session Duration
(hours)
1. 1 Brief Introduction about fundamentals of signals and systems 2
2. 2 Introduction, basic operations on signals, 1
3. 3 Basic continuous-time signals, 1
4. 4 Basic discrete-time signals, 1
5. 5 Properties of systems, 1
6. 6 Convolution sum. 1
7. 7 Z transforms: 2
8. 8 Introduction, definition, ROC of finite duration and infinite
duration sequences, 2
9. 9 ROC and stability, properties of ROC, 1
10. 10 Transforms of some useful sequences, 1
11. 11 Inverse Z-transforms using partial fraction expansion
method. 2
Total 15
Sl. No.
Unit 2 :
Session Topics covered in the session Duration
(hours)
1. 1 Introduction to DFT and FFT, 1
2. 2 Definition of DFT and IDFT, 1
3. 3 Concepts of circular shift and circular symmetry, 2
4. 4 Properties of DFT, FFT. 2
5. 5 Introduction to IIR filters, 1
6. 6 Analog filter specifications, classification, 2
7. 7 Butterworth filters, 1
8. 8 Frequency transformations/Special transformations, 2
9. 9 Design of low pass Butterworth filters. 2
10. 10 Numerical Problems 1
Total
15
Sl. No.
Unit 3 :
Session Topics covered in the session Duration
(hours)
1. 1 Brief Introduction Design of digital filters 1
2. 2 Digital filters, bilinear transformation, 2
3. 3 Analog design using digital filters. 2
Recommended