Third year Electronics Engineering Syllabus - Mumbai University

The Third year Electronics Engineering Syllabus of mumbai university is given below with in detail of each subject along with books recommended.

Mumbai University Engineering Syllabus

Here is the syllabus for Third year Engineering by Mumbai university for the subject Electronic Engineering.

Continuous Time Signal & System

Lectures: 4 hours / week Theory Paper: 3 hours and 100 marks
Practicals: 2 hours / week Termwork: 25 marks Oral Exam:25 Total:150
Objective
1. To introduce the student to the idea of signals and systems analysis and
characterization in continuous domain.
2. To provide a foundation to numerous other courses that deal with signal and system
concepts directly or indirectly: viz: communication, control, statistical signal processing
etc
Pre-requisite: Basic knowledge of Fourier analysis ,Laplace Transform and sampling
theorem
Hours 10

Chapters

1 Introduction to signals & Systems
Definition of Signal
Elementary Continuous Time (CT) signals like unit step, Impulse, ramp, exponential,
sinusoidal etc.
Operations on signal like shifting, flipping, scaling, addition, multiplication
Breaking of a CT signal in different basic components
Concept of system
Classification of system on the basis of linearity, time variance, causality, memory
,stability, invertibilty etc
System representation by a differential equation
Hours 06
2.Convolution and correlation
Concept of Impulse Response
Convolution integral and system response in CT domain
Properties, Autocorrelation and its property. Relation of autocorrelation to signal energy,
power, ESD, and PSD. Cross correlation and its property.
Hours 12
3. Fourier Series (FS) & Fourier Transform (FT) for CT systems
Review of Trigonometric series, Exponential series
properties and uses
Amplitude & phase spectra
Power Spectral Density
Parseval's relation, Relation between Trigonometric and Exponential Fourier series,
Gibbs Phenomenon
The Fourier Transform (FT)
FT of basic signals
Properties of FT and derivations
FT of periodic signals
Conceptual introduction to C.T. short time Fourier Transform (STFT)
Energy Spectral Density
Analog to Digital conversion & its Reconstruction
Hours 06
4. Fundamentals of Random processes
Introduction, concept of random variable, PDF of uniform, Gaussian and exponential
random variable. Properties of Mean, variance and moments. Two or more random
variables , Random processes
Hours08
5. Laplace transform analysis of signals and systems
Definition & properties of Two-sided & one-sided Laplace Transform.
Region of Convergence (ROC)
inverse Laplace transform
Relationship with Fourier Transform & mapping
BIBO stability and ROC
Pole-zero diagram
Impulse response of a system, and impulse response of cascade and parallel systems
Time domain analysis for first and second order systems
Solution to differential equations and system behavior.
Zero state & zero input responses
System response to complex exponential inputs.
Hours06
6. State -Variable Techniques
State –Variable concepts and state variable model ,
TF from state variable model and vice versa.
Digonalization
State equations & their time domain and frequency domain solutions
State transition matrix
System state equations
Text- Books:
1. S. Haykin, Signals and Systems , Wiley Eastern Publication
2.M J. Roberts, Fundamentals of Signals and Systems, second reprint, Tata McGraw-
Hill, 2008
3.J.G. Proakis, D. G. Manolakis, Digital Signal Processing: Principles, Algorithms and
applications, Prentice Hall of India, 1995
4.Ashok Ambardar, Analog and Digital Signal Processing, Thomson Learning, second
edition, 2001
5.B.P.Lathi, linear systems and signals Oxford University Press second Indian
Impression, 2007
6.D.D. Shah & A.C. Bhagali, Signals and systems, MPH publication.
Additional Reading:
1.R.F. Ziemer, W.H. Tranter and D.R. Fannin, "Signals and Systems - Continuous and
Discrete", 4th edition, Prentice Hall, 1998
2.A.V. Oppenheim, A.S. Willsky and I.T. Young, "Signals and Systems", Prenice Hall,
1983.
3.R.A.Gabel,Signals and linear systems,John wiley and Sons.
4.chen,Signals and Systems Oxford University Press Third Indian Impression, 2007
5.I J Nagrath, S N Sharma, R Ranjan, and S Kumar , "Signals and Systms", Tata
Mcgraw Hill
Suggested list of simulations
1. Generation and transformations of basic C.T. signals(2 simulations)
2.Verification of sampling theorem
3.Impulse and step response of a C.T. system
4.Demonstration of Fourier series coefficients
5.Demonstration of Fourier transform of signals
6.Demonstration of Laplace transform of signals
7.Finding Mean, variance and standard deviation of random data
8.State space to TF and TF to state space conversion
T.W. / Oral Examination:
Term work:
The term work shall consists of at least four assignments and six MATLAB or C
simulations covering the whole of syllabus, duly recorded and graded. This will carry a
weightage of fifteen marks. A test shall be conducted and will carry a weightage of ten
marks.
The distribution of marks for term work shall be as follows:
Laboratory work (Experiments and Journal) : 10 marks.
Test (at least one) : 10 marks.
Attendance (Practical and Theory) : 05 marks.
The final certification and acceptance of term-work ensures the satisfactory performance
of laboratory work and minimum passing in the term-work.
Theory Examination:
1. Question paper will be comprise of total 7 questions, each of 20 marks.
2. Only 5 questions need to be solved.
3. Question number 1 will be compulsory and will cover all modules.
4. Remaining questions will be mixed in nature. (e.g.- suppose Q.2 has part (a) from,
module 3 then part (b) will be from any module other than module 3.)
5. In question paper weightage of each module will be proportional to number of
respective lecture hours as mentioned in the syllabus.
6. No question should be asked from pre-requisite module

[2] Microprocessor and Microcontroller-I

Lectures: 4 hours / week Theory Paper: 3 hours and 100 marks
Practicals: 2 hours / week Practical Exam: 3 marks:25
Term work: 25 marks Total:150
Objective: Objective of this course is to introduce to the students the fundamentals of
microprocessor and microcontroller.
Pre-Requisite: Concept of Basic Electronics and Digital Logic Systems.
Hours 08

Chapters
1. Basics 8085:
Basic 8085 microprocessor architecture and its functional blocks. 8085 microprocessor
IC pin outs and signals, address, data and control buses. 8085 features. Interrupt system
of 8085. Stack and subroutine. Types of memory and memory interfacing. Decoding
techniques-absolute and partial. Mapping techniques -I/ O mapped I /O and memory
mapped-I/O. Serial I/O lines of 8085 and the implementation asynchronous serial data
communication using SOD and SID.
Hours 09
2. Programming with 8085:
Basic instruction set, timing states, machine cycles and instruction cycles. Instruction
timing diagram and, interrupt process and timing diagram of interrupt instruction
execution. Writing assembly language programs. Looping, counting and indexing
operations related programs. Stacks and subroutines operations related programs.
Conditional call and return instructions operations related programs. Debugging
programs.
Hours06
3. Study and Interfacing of peripherals 8155, 8255, 8253/8254, 8259 with 8085.
Hours08
4. Basics of 8051:
Comparison of microprocessor and microcontroller. Architecture and pin functions of
8051 chip controller. CPU timing and machine cycles. Internal memory organization.
Program counter and stack. Input/output prots. Counters and timers. Serial data
input and output interrupts. Power saving modes.
Hours09
5. Programming with 8051:
Instruction set, addressing modes. Immediate, registers, direct and indirect data
movement and exchange instructions. Push and pop op-codes. Arithmetic and
logic instructions, bit level operations, jump and call instructions, input/output port
programming, programming timers, asynchronous serial data communications
and hardware interrupt service routines interfacing of LCD display hex keyboard
ADC0808. DAC0808 and stepper motor with 8051 current trends in
microprocessors and practical implementation.
Hours08
6.Introduction to ARM Processor
1.ARM family architecture, register architecture, memory access and addressing
modes, arithmetic and logical instructions, branching instructions.
Comparative study of salient features of 8051 and its derivatives like 89C51,
89C52, 89C2051 and 89C2052. Current processor and controller survey. (cost,
availability, popularity)
Recommeded Books:
1.Mazidi & Mazidi, The 8085 microcontroller & embedded system, using
assembly and C, 2nd edi, pearson edu.
2.Microprocessor and interfacing 8085, Douglas V Hall, Tata Mc Gram Hill.
3.Microprocessor-Architecture, programming and application with 8085, gaonkar,
penram international.
4.Crisp, introduction to microprocessor & microcontrollers, 2e Elsevier, 2007.
5.ARM system-on-chip architecture, 2e pearson education.
6.Calcut, 8051 microcontrollers: An applications based introduction, Elsevier.
7.DV kodavade, S.Narvadkar, 8085-86 microprocessors Architecture progg and
interfaces, wiley.
8.Udyashankara V., Mallikarjunaswamy, 8051 microcontroller, TMH.
9.Han-way Huang, using The MCS-51 microcontroller, Oxford university press.
10.Ayala, 8051 microcontroller, cengage(Thomson).
11.Rout, 8085 microcontroller-architecture, programming and application, 2nd edi,
penram international.
term-work
The distribution of marks for term work shall be as follows,
Tutorials : 10 marks.
Test (at least one) : 10 marks.
Attendance (Tutorials and Theory) : 05 marks.
The final certification and acceptance of term-work ensures the satisfactory performance
of Tutorials work and minimum passing in the term-work.
Theory Examination:
1. Question paper will comprise of total 7 questions, each of 20 marks.
2. Only 5 questions need to be solved.
3. Question number 1 will be compulsory and will cover all modules.
4. Remaining questions will be from the same module or mixed in nature. (e.g.-
suppose Q.2 has part (a) from, module 3 then part (b) will be from any
module other than module 3.)
5. In the question paper, weightage of each module will be proportional to
number of respective lecture hours as mentioned in the syllabus.
6. No question should be asked from pre-requisite module.

[3]Electromagnetic Engineering

Lectures: 3 per week Theory Paper: 3 hours and 100 marks
Tutorial: 1 ( each of 60min) Term work: 25 marks Total:125
Objective: Electromagnetic Field Theory deals with electric and magnetic field vectors,
whereas circuit theory deals with voltages and currents that are the integrated effects of
electric and magnetic fields. An understanding of Electromagnetic is a must to
appreciate Wave Propagation, Antenna Theory, Microwave and Optical Fiber System.-
Pre-requisite: Vector Algebra
Hours06

Chapters

1. Basics of Electromagnetics
Co-ordinate systems, line, Surface & Volume Integral, Curl, Divergence & Gradient,
Electric Charge, Coulomb's law, Charge distribution, Electric Field Intensity, field due
to distributed charges, Electric Flux, Gauss's law, Divergence Theorem, Electric
Potential & Potential Gradient, Ampere's Law, Magnetic Flux, Faraday's Law,
Poisson & Laplace's Equations
Hours06
2. Maxwell Equations:
Formation of Maxwell's Equations
Derivation of various basic electro magnetic laws using Maxwell's Equations,
Conditions at Boundary Surfaces
Hours05
3. Electromagnetic Waves
The wave equation for free space & conducting medium, Uniform Plane wave,
Intrinsic Impedance, Helmoltz Equations, Propagation characteristics of
Electromagnetic Wave, Polarization, Poynting's Theorem, Instantaneous, Average &
Complex Poynting vector
Hours06
4. The uniform plane wave Propagation
plane wave reflection and dispersion, reflection of uniform plane waves at normal
incidence, standing wave ratio, wave reflections from multiple interfaces, plane wave
propagation in general directions, plane wave reflection at oblique incidence angles,
total reflection and total transmission of obliquely incident waves, wave propagation
in dispersive media, pulse broadening in dispersive media.
Hours06
5. The uniform plane wave Propagation
plane wave reflection and dispersion, reflection of uniform plane waves at normal
incidence, standing wave ratio, wave reflections from multiple interfaces, plane wave
propagation in general directions, plane wave reflection at oblique incidence angles,
total reflection and total transmission of obliquely incident waves, wave propagation
in dispersive media, pulse broadening in dispersive media.
Hours05
6. The uniform plane wave Propagation
plane wave reflection and dispersion, reflection of uniform plane waves at normal
incidence, standing wave ratio, wave reflections from multiple interfaces, plane wave
propagation in general directions, plane wave reflection at oblique incidence angles,
total reflection and total transmission of obliquely incident waves, wave propagation
in dispersive media, pulse broadening in dispersive media.
Text Books:
1.E. C. Jordan & K. G. Balmain-Electromagnetic Waves & Radiating Systems,2e,
PHI, 1988.
2.G.S.N.Raju, Electromagnetic Field Theory and Transmission Lines, Pearson
Education, 2e, 2008
3.R.K.Shevgaonkar, Electromagnetic Waves, Tata McGraw-Hill,2006
Additional Reading:
1.John D Krauss, Engineering Electromagnetics, McGraw-Hill, 6e, 2001.
2.Edminister, Engineering Electromagnetics, Schaum series, Tata McGraw-Hill,
2e, 1992.
3.Samuel Liao, Microwave Devices and Circuits ,Prentice Hall publication, 3e -
1994
4.Edgar Hund., Microwave Communication Components & Circuits,Glencoe/
3e,Mc-Graw- Hill
5.Nannapaneni Narayana Rao, Elements of Engineering Electromagnetics, 6e,
Pearson Education
6.Ashutosh Pramanik, Electromagnetism- Theory & Applications, PHI, 2e-2004
7.David K. Cheng, Field and Wave Electromagnetics, 2e,Pearson Education
Tutorials:
ıAt least eight tutorials based on the above syllabus out of which one tutorial should
based on transmission line problems using Smith Chart only.
ıStudent shall write some simple Electromagnetic Fields Related simulation programs
using MATLAB/SCILAB to demonstrate the applications of field theory.
Term-work:
A journal shall be consisting of solved problems in tutorials based on teachings in
the lectures, in addition to assignments along-with some simple Electromagnetic
Fields Related Simulation programs using MATLAB/SCILAB which will
demonstrate the applications of field theory. A test based on the above contents
shall be conducted and the test paper shall be attached to the journal as a part of
term-work
The distribution of marks for term work shall be as follows,
Tutorials : 10 marks.
Test (at least one) : 10 marks.
Attendance (Tutorials and Theory) : 05 marks.
The final certification and acceptance of term-work ensures the satisfactory performance
of Tutorials work and minimum passing in the term-work.
Theory Examination:
1. Question paper will comprise of total 7 questions, each of 20 marks.
2. Only 5 questions need to be solved.
3. Question number 1 will be compulsory and will cover all modules.
4. Remaining questions will be from the same module or mixed in nature. (e.g.-
suppose Q.2 has part (a) from, module 3 then part (b) will be from any
module other than module 3.)
5. In the question paper, weightage of each module will be proportional to
number of respective lecture hours as mentioned in the syllabus.
6. No question should be asked from pre-requisite module

[4]Linear Integrated Circuit and Design

Lectures: 4 per week Theory Paper: 3 hours and 100 marks
Practical: 2 ( each of 60min) Practical exam: 3hours Marks 25
Term work: 25 marks Total:150
Objective: To teach the basic concepts in the design of electronic circuits using linear
integrated circuits and their applications in the processing of analog signals. Also to
introduce a few special function integrated circuits such as Regulator ICS, Waveform
generator etc.
Pre-requisite: Passive circuit analysis and transistor behavior. single or two stage
amplifier, Diff-Amp and Current Mirror concepts
Hours08

Chapters
1. Operational Amplifier Fundamentals
Basic Op Amp Configurations,
Ideal Op Amp Circuits Analysis,
Simplified Op Amp Circuits Diagram,
Input Bias and Offset Currents,
Low-Input-Bias-Current Op Amps,
Input Offset Voltage,
Low-Input-Offset-Voltage Op Amps,
Input Offset-Error Compensation,
Maximum Ratings.
Open-Loop Response,
Closed-Loop Response
Input and Output Impedances
Transient Response
Effect of Finite GBP on Integrator Circuits
Effect of Finite GBP on Filters
Current-Feedback Amplifiers
The Stability Problem,
Stability in Constant-GBP Op Amps Circuits,
Internal Frequency Compensation
External Frequency Compensation
Stability in CFA Circuits
Composite Amplifiers
Op Amp Powering.
Slew rate and methods of improving slew rate.
Hours 08
2. Linear Applications of OP-AMP
Current shunt feedback (Inverting Amplifier)
Current Series feedback (Non-Inverting Amplifier)
Summing Amplifier, Averaging Amplifier
Difference Amplifier,
Instrumentation Applications,
Integrator/Differentiator using OP-AMP
Current-to-Voltage Converters,
Voltage-to-Currents Converters,
Grounded load V/I Converter
V-F and F-V Converters.
Sample-and-Hold Amplifiers
Hours08
3. Active Filter
The Transfer function,
First-Order Active Filters,
Audio Filter Applications,
Standard Second- Order Responses, KRC Filters,
Multiple-Feedback Filters,
State-Variable and Biquad Filters,
Sensitivity, Filter approximations,
Cascade design,
Generalized impedance converters,
Direct design,
Switched capacitor filters.
Hours08
4. Non Linear Applications of OP-AMP
Voltage Comparators
Comparator Application
Schmitt Triggers,
Precision Rectifier
Peak Detectors
Mono-shot Multi-vibrator
Astable Multi-vibrator
Triangular /saw-tooth waveform Generator
Hours10
5. Data Converters and Regulators
Analog Switches
A-D Conversion Techniques
D-A Conversion Techniques
Integrated ICs employing above techniques and their applications
Functional block diagram of Voltage Regulators
Fixed voltage Regulators(78XX and 79XX)
Variable Voltage Regulators (LM317 and CA723)
Hours06
6. 6.Waveform Generators and synthesizers
Oscillators using OP-AMP (RC –Phase shift and Wien Bridge oscillators)
Monolithic Timer – NE555
Phase-Locked Loops, Monolithic PLLs
Text Books:
1.Sergio Franco, Design with operational amplifiers and analog integrated circuits, Third
edition, McGraw Hill International edition, 2002.
2.Ramakant A.Gayakwad, 'OP-AMP and Linear IC's', Prentice Hall / Pearson Education,
1994.
3.Robert Coughlin and F Driscoll, Operational Amplifiers and Linear Integrated circuits,
sixth edition, Pearson Education Asia, 2001
4.D.Roy Choudhry, Shail Jain, "Linear Integrated Circuits", New Age International Pvt.
Ltd., 2000.
2. James M. Fiore, Op Amps and Linear Integrated circuits, First reprint, Thomson
Asia Pte. Ltd., 2001
3. K.R.Botkar, 'Integrated Circuits'. Khanna Publishers, 1996.
Additional Reading:
1.Donald A. Neamen, Electronic Circuit Analysis and Design, Second edition,
McGraw Hill International edition 2001
2. James M. Fiore, Op Amps and Linear Integrated circuits, First reprint, Thomson
Asia Pte. Ltd., 2001
3.K.R.Botkar, 'Integrated Circuits'. Khanna Publishers, 1996.
Practical/ Oral Examination:
Practical Examination will be based on experiments performed from the list of
experiment given in the syllabus and the evaluation based on the same experiment.
Oral will be based on any experiment performed from the list of experiment given in
the syllabus and the entire syllabus.
Termwork:
The term-work shall consist of at least six laboratory experiments covering the whole
of syllabus, duly recorded and graded as well as at least four computer simulations
using EDA tools like PSPICE duly recorded and graded. This will carry a weightage
of Ten marks. A test shall be conducted and will carry a weightage of ten marks.
The distribution of marks for term work shall be as follows
Laboratory work (Experiments and Journal) : 10 marks.
Test (at least one) : 10 marks.
Attendance (Practical and Theory) : 05 marks.
The final certification and acceptance of term-work ensures the satisfactory
performance of laboratory work and minimum passing in the term-work.
Theory Examination:
1. Question paper will comprise of total 7 questions, each of 20 marks.
2. Only 5 questions need to be solved.
3. Question number 1 will be compulsory and will cover all modules.
4. Remaining questions will be from the same module or mixed in nature. (e.g.-
suppose Q.2 has part (a) from, module 3 then part (b) will be from any
module other than module 3.)
5. In the question paper, weightage of each module will be proportional to
number of respective lecture hours as mentioned in the syllabus.
6. No question should be asked from pre-requisite module.

[5]Digital Communication and Coding Techniques

Lectures: 4 hours / week Theory Paper: 3 hours and 100 marks
Practicals: 2 hours / week Oral Exam: 25marks,Term work: 25 marks
Total:150
Objective: The increase in demand for data transmission coupled with the availability of
wideband communication channels and sophisticated integrated circuits have led to the
development of efficient and reliable digital communication systems. This course
emphasizes impact of the channel limitations and characteristics on data transmission
using digital data.
Pre-Requisite:Concepts of basic communication techniques – Modulation and
Demodulation, Sampling, Fourier Transform.
Hours03

Chapters
1.Concept of Probability Theory in communication systems
Random variables, Mean and Variance of Random variables and sum of random
variables,
Useful PDFs & CDFs : Gaussian , ,Rayleigh pdf & Rician Distribution , Binomial and
Poisson Distributions, Central-Limit Theorem.
Hours05
2. Information Theory and Source Coding
Measure of Information, Entropy, Information rate, Channel capacity, Capacity of a
Gaussian channel, Bandwidth - S/N trade-off, Source. coding theorem, Coding to
increase the average information per bit - Huffman coding, Lempel Ziv coding.
Examples and application of source coding.
Hours13
3. Error Control Codes
Channel coding theorem. Rationale for coding and types of codes, Discrete
memoryless channel , some Algebraic concepts - code efficiency and Hamming
bound , linear block codes, Cyclic codes, Convolutional codes , Code tree, state and
Trellis diagram. Decoding of convolutional codes using Viterbi algorithm.
Hours06
4. Pulse Shaping for optimum transmission
Concept of Inter channel and Inter symbol Interference, Eye Pattern, Nyquist's
Criterion for distortion less Baseband Binary Transmission, Correlative Coding.
Hours15
5. Digital Modulation Techniques
Digital Modulation formats , coherent and non modulation. Digital modulation
techniques-BPSK, Modifications of BPSK, QPSK,M-ary PSK,ASK, QAM, BFSK, Mary
FSK and MSK – Transmitter- Receiever, Power spectra, Bandwidth efficiency,
Euclidian distance.
Integrate and dump receiver, Matched filter, correlator. The optimum Receiver.
Hours06
6. Spread Spectrum Modulation – Spread Spectrum Modulation –Pseudo noise
Sequences, Processing Gain and Jamming Margin, Direct-sequence spread
spectrum, Frequency –hop Spread Spectrum. Application of spread spectrum : DSCDMA
Text Books:
1. Simon Haykin- Communication Syatem, , John Wiley and sons
2. Taub Schilling & Saha - Principles of communication systems - Tata McGraw
Hill, Third edition.
3. Bernad Sklar,-Digital Communication, Pearson Education , 2nd ed
4. Amitabha Bhattacharya,-Digital communication , Tata McGraw Hill
5. Lan A. Glover, Peter M. Grant -Digital Communications, Pearson education,
econd edition.
6. Simon Haykin Digital communication, John Wiley and sons
Reference Books:
7. John G. Proakis,- Digital Communications, McGraw Hill , 5th ed
8. William D. Stanley & John m. Jeffords, Electronic Communications Principles
and Systems, Cengage Learning.
9. Lathi B.P.,- Modern Digital and Analog communications systems - PRISM Indian
edition
10. PROAKIS & SALEHI - Communication system engineering, Pearson Education
Proposed Practical list
1.BPSK
2.QPSK
3.BFSK
4.QASK
5.BER calculation for a digital communication system
6.Huffman coding
7.Lempel Ziv coding
8.Linear Block code - Code generation, dmin, syndrome.
9.Cyclic Code - Systematic and non-systematic code generation, syndrome.
10.Convolution Code – code generation from generator sequences
11.Direct sequence spread spectrum
T.W. / Oral Examination:
Oral will be based on any experiment performed from the list of experiment given in the
syllabus and the entire syllabus.
Term Work:
Term work shall consist of minimum eight experiments, Two Assignments and a written
test.
The distribution of marks for term work shall be as follows:
Laboratory work (Experiments and Journal) : 10 marks.
Test (at least one) : 10 marks.
Attendance (Practical and Theory) : 05 marks.
The final certification and acceptance of term-work ensures the satisfactory performance
of laboratory work and minimum passing in the term-work.
Theory Examination:
1. Question paper will comprise of total 7 questions, each of 20 marks.
2. Only 5 questions need to be solved.
3. Question number 1 will be compulsory and will cover all modules.
4. Remaining questions will be from the same module or mixed in nature. (e.g.-
suppose Q.2 has part (a) from, module 3 then part (b) will be from any
module other than module 3.)
5. In the question paper, weightage of each module will be proportional to
number of respective lecture hours as mentioned in the syllabus.
6. No question should be asked from pre-requisite module.

[6]Environmental Studies

Lectures: 2per week Theory Paper: 2 hours and 50 marks
Tutorial: 1 ( each of 60min) Term work: 25 marks Total:75
Objective :Objective of this course is to create environmental awareness, of
variety of environmental concerns.
Hours01

Chapters
1. The multidisciplinary nature of environmental studies:
Definition, Scope and importance need for public awareness.
Hours04
2. Natural Resources
Renewable and non- renewable resources
Natural resources and associated problems
a.Forest resources: use and over-exploitation, deforestation, case studies,
timber extraction, mining, dams and their effects on forests and tribal people.
b.Water resources: use and over utilization of surfaces and ground water,
floods drought, conflicts over water, dams-benefits and problems.
c.Mineral resources: use and exploitation, environmental effects of extracting
and using mineral sources, case studies.
d.Food resources: World food problems overgrazing, effects of modern
agriculture, fertilizers-pesticides problems, Water logging, salinity, case studies.
e.Energy resources: Growing energy needs, Renewable and non- renewable
sources,use of alternate energy sources, case studies
f. Land resources: Land as a resource, Land degradation, man induced
landslides, soil erosion and desertification
Role of an individual in conservation of natural resources. Equitable use resources
for sustainable lifestyles
Hours03
3. Ecosystems
Concepts of ecosystems
Structure and function of an ecosystem
Producers, consumers and decomposers
Energy flow in ecosystems
Ecological succession
Food chains, food web and ecological pyramids
Introduction, types, characteristics features, structure and function of following
ecosystems
a. Forest ecosystems
b. Grassland ecosystems
c. Desert ecosystems
d. Aquatic ecosystems( ponds, streams, lakes, rivers, oceans, estuaries)
Hours04
4. Biodiversity and its conservation
Introduction- definition: genetic species and ecosystem diversity
Bio-geographical classification of India
Value of biodiversity: consumptive use, productive use, social, ethical, aesthetic and
option values
Biodiversity at global, national, local level
India as a mega diversity nation
Hot spots of bio diversity
Threats to biodiversity: habitat loss, poaching of wild life, man wild life conflicts
Endangered and endemic species of India
Conservation of bio-diversity: In-situ and Ex-situ conservation of biodiversity
Hours04
5. Environmental Pollution Definition-
Causes, effects and control measures of:-
a.Air pollution
b.Water pollution
c.Soil pollution
d.marine pollution
e. Noise pollution
f. Thermal pollution
g. Nuclear hazards
Solid waste management: Causes, effect and control measures of urban and
industrial wastes
Role of an individual in prevention of pollution
Pollution case studies
Disaster management: floods, earthquake, cyclone and land slides.
Hours04
6. Social Issues and environment
From unsustainable to sustainable development.
Urban problems related to energy
Water conservation rain water, harvesting, water-shed management.
Resettlement and rehabilitation of people, its problem and concerns case studies.
Environmental ethics, issues and possible solution
Climate change, global warming, acid rain, ozone layer depletion, nuclear accidents
and holocaust case studies.
Waste-land reclamation
Consumerism and waste product
Environmental protection act
Air( prevention and control of pollution) act
Water ( prevention and control of pollution) act
Wide-life protection act.
Forest conservation act.
Issues involved in enforcement of environmental legislation.
Public awareness
Hours04
7. Human population and the environment
Population growth variation among nations
Population explosion-family welfare program
Environment and human health
Human rights
Value education
HIV/AIDS
Women and child welfare
Role of information technology in environment and human health
Case studies
Hours06
8. Understanding existence and co-existence:
Interrelation and cyclicity between material order, bio-order, animal-order and
human-order.
Understanding the human conduct:
Relationship in family, justice in relationship, relationship of human with
nature(environment), human behavior, human values, nature and morality
Understanding the human society:
Dimensions of humans Endeavor and objectives, inter-relationship in society, mutual
fulfillment and cyclicity in nature.
Theory Examination:
1. Question paper will be comprising of total 7 questions, each of 10 marks.
2.Only 5 questions need to be solved.
3.Question number 1 will be compulsory and covering the all modules.
4.Remaining questions will be mixed in nature. (e.g.- suppose Q.2 has part (a) from,
module 3 then part (b) will be from any module other than module 3.)
5.In question paper weightage of each module will be proportional to number of
respective lecture hours as mentioned in the syllabus.
Term work:
Term work shall consist of minimum five projects (PROJECTS SHALL BE
DESIGNED ON THE SAME GUIDE- LINE OF GIVEN TEXT BOOK) and a written
test.
The distribution of marks for term work shall be as follows,
Laboratory work (Tutorial/Project and Journal) : 15 marks.
Test (at least one) : 10 marks.
The final certification and acceptance of term-work ensures the satisfactory
performance of laboratory work and minimum passing in the term-work.
Recommended Books:
1.Jagdish Krishnawamy , R J Ranjit Daniels, " Environmental Studies", Wiley India
Private Ltd. New Delhi
2.Anindita Basak, Environmental Studies, Pearson
3.Deeksha Dave , "Textbook of Environmental Studies", Cengage learning,
THOMSON INDIA EDITION
4.Benny Joseph" Environmental Studies"Tata McGRAW HILL
5.D. L. Manjunath, Environmental Studies, Pearson
6.R.Rajgopalan, Environmental Studies, Oxford
7.Erach Bharucha, Textbook of Environmental Studies , Universities Press/Orient
BlackSwan
8.Alok Debi, Environmental science and engineering, university press
9.A. Nagraj, Jeevan Vidya- A Primer.

[7] Electronic Workshop-II

Practical: 04 per week Oral : 50
Tutorial: - Term work: 25 marks Total:50
Objective: This syllabus is designed to encourage students to design and implement
innovative ideas. The syllabus will give them in depth practical knowledge from
design to the final verification stage. Documentation of any project is an important
part of the project and students are expected to document their work properly in
standard IEEE format.
Every group of students should select different projects. Number of students should
not be less than TWO and not more than THREE in one group.
1. Computer Architecture
Demonstration of various parts of PC, Installation, Network Configuration and
Troubleshooting of PC.
2. Microcontroller/Microprocessor Based Project
Students are expected to design any* microcontroller/microprocessor based
system/application. PCB design, simulation and physical verification of the project
should be carried out. Documentation of the project is to be done in standard IEEE
format using Latex/WinTex. Project report should include abstract in maximum 100
words, keywords, introduction, design, simulation, implementation, results,
conclusion and references.
3. VHDL Based Project
Students are expected to design any* VHDL based application. Simulation,
synthesis and implementation on FPGA/CPLD should to be carried out.
Documentation of the project is to be done in standard IEEE format using
Latex/WinTex. Project report should include abstract in maximum 100 words,
keywords, introduction, design, simulation, implementation, results, conclusion and
references.
** To be approved by the subject in-charge
Oral Exam include —Project report +Presentation (PPT)
References:-
1.Govindarajalu B., "IBM Pc and clones: Hardware, Troubleshooting and
Maintenance", Tata McGraw Hill.
2.Gilster Ron, 'PC Hardware: A Beginner's Guide", Tata McGraw Hill
3.Minasi Mark, "PC Upgrade and Maintenance Guide", BPB Pub.
4.Hallberg Bruce A., "Networking a Beginners Guide", Tata McGraw Hill
5.Ingram, Peter, "Networking in easy Steps", Dreamtech Press
6.Bigelow Stephen, "Troubleshooting, Maintenance and Reparing PC's", Tata
McGraw Hill
7.Brown Stephen and Vranesic Zvonko, "Fundamentals of digital logic with VHDL
design", Tata McGraw Hill
8.Perry Douglas, "VHDL Programming by Example", Tata McGraw Hill
9.Bhasker J. "VHDL Primer", Pearson Edu.
10.VHDL Reference Manual
11.Reference Manuals for Selected Microcontrollers/Microprocessors