department of electronics and communication engineeringvlsi, embedded system etc. pso2: ability to...
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Department of Electronics and
Communication Engineering
To develop self-motivated, creative & Ethical
Skilled Engineers and Researchers to meet
the Social Commitment.
M1: To impart State-of-Art Technical
Education.
M2: To encourage the students for
professional ethics & social responsibilities.
M3: To inculcate team work & leadership
qualities to make the students industry ready
& employable.
M4: To carry out research leading to the
realization of knowledge and intellectual
property.
M5: To facilitate graduates to become an
entrepreneur.
Departmental Vision
Departmental Mission
1
Department of Electronics and
Communication Engineering
PEO1: Knowledge of Basic Engineering Sciences: To exhibit knowledge in Mathematics,
Engineering Fundamentals, Electronics & Communication Engineering and related fields for
professional achievement in industry and organizations.
PEO2: Engineering Design Skills: To equip the
students with the necessary problem solving skills relevant to the general practice of Engineering design.
PEO3: Problem Solving Ability: To produce
engineering graduates who have the problem solving ability to pursue advanced studies and research in all
disciplines.
PEO4: Technical Knowledge: To impart the
knowledge of theory and practices of ECE and its applications in areas of modern research and current industry trends to the students.
PEO5: Professional Skill: To inculcate
professional and ethical attitude, effective communication skills, teamwork skills, leadership
qualities, managerial skills & multidisciplinary approach in the students for successful career and
entrepreneurship.
Program Educational Objectives
(PEO)
2
Department of Electronics and
Communication Engineering
PO1: Engineering knowledge: Apply the knowledge of
mathematics, science, engineering fundamentals, and an engineering specialization to the solution of complex
engineering problems.
PO2: Problem analysis: Identify, formulate, review
research literature, and analyze complex engineering problems reaching substantiated conclusions using first principles of mathematics, natural sciences, and engineering sciences.
PO3: Design/development of solutions: Design
solutions for complex engineering problems and design system components or processes that meet the specified needs with appropriate consideration for the public health and safety, and the cultural, societal, and environmental considerations.
PO4: Conduct investigations of complex problems: Use research-based knowledge and research methods including design of experiments, analysis and interpretation of data, and synthesis of the information to
provide valid conclusions.
PO5: Modern tool usage: Create, select, and apply
appropriate techniques, resources, and modern engineering and IT tools including prediction and modeling to complex engineering activities with an understanding of the limitations.
PO6: The engineer and society: Apply reasoning
informed by the contextual knowledge to assess societal, health, safety, legal and cultural issues and the consequent responsibilities relevant to the professional engineering practice.
Program Outcome (PO)
3
Department of Electronics and
Communication Engineering
PO7: Environment and sustainability: Understand
the impact of the professional engineering solutions in societal and environmental contexts, and demonstrate the knowledge of, and need for sustainable development.
PO8: Ethics: Apply ethical principles and commit to
professional ethics and responsibilities and norms of the engineering practice.
PO9: Individual and team work: Function effectively
as an individual, and as a member or leader in diverse teams, and in multidisciplinary settings.
PO10: Communication: Communicate effectively on
complex engineering activities with the engineering community and with society at large, such as, being able to comprehend and write effective reports and design documentation, make effective presentations, and give and receive clear instructions.
PO11: Project management and finance: Demonstrate knowledge and understanding of the
engineering and management principles and apply these to one’s own work, as a member and leader in a team, to manage projects and in multidisciplinary environments.
PO12: Life-long learning: Recognize the need for, and
have the preparation and ability to engage in independent and life-long learning in the broadest context of technological change.
Program Outcome (PO)
4
Department of Electronics and
Communication Engineering
PSO1: Ability to Identify, Formulate & Solve
problems of basics of Electronics &
Communication Engineering and to apply
them to various areas like Analog & digital
Circuits, Signal & systems, Communication,
VLSI, Embedded System etc.
PSO2: Ability to design the systems of
Electronics & Communication Engineering
using advanced hardware and software tools
with analytical skills to achieve the Societal
needs.
PSO3: Knowledge of social & environmental
awareness along with ethical responsibility to
achieve a successful career addresses the real
world applications using optimal resources as
an entrepreneur.
Program Specific Outcome
(PSO)
5
Department of Electronics and
Communication Engineering
Course Code
Course Title
Total Number of contact hours
Credits Lecture
(L) Tutorial (T)
Practical (P)
Total Hours
Semester I
M 101 Mathematics-I 3 1 0 4 4
CH 101 Chemistry-I 3 1 0 4 4
EE 101 Basic Electrical Engineering
3 1 0 4 4
HU 101 Communicative English
2 0 0 2 2
ME 101 Engineering Mechanics
3 1 0 4 4
HU181 Extra-Curricular Activity (NSS)
0 0 2 2 1
HU191 Lang. Lab. and Seminar Presentation
0 0 2 2 1
CH 191 Chemistry Lab 0 0 3 3 2
EE 191 Basic Electrical Engineering Lab
0 0 3 3 2
ME 191 Engineering Drawing &
Graphics
0 0 3 3 2
Semester II
M 201 Mathematics -II 3 1 0 4 4
PH 201 Physics - I 3 1 0 4 4
EC 201 Basic Electronics Engineering
3 1 0 4 4
CS 201 Computer Fundamentals & Principle of Computer
3 1 0 4 4
Departmental Curriculum
Structure
6
Department of Electronics and
Communication Engineering
Programming
ME 201 Engineering Thermodynamics & Fluid Mechanics
3 1 0 4 4
CS291 Computer Fundamentals
& Principle of Computer Programming Lab
0 0 3 3 2
PH291 Physics -I Lab 0 0 3 3 2
EC 291 Basic Electronics Engineering Lab
0 0 3 3 2
ME 291 Workshop Practice
0 0 3 3 2
CS291 Computer Fundamentals & Principle of Computer Programming Lab
0 0 3 3 2
PH291 Physics -I Lab 0 0 3 3 2
MC 281 Soft Skill
Development
0 0 2 2 0
Semester III
M 301 Mathematics-III 3 1 0 4 4
M(CS) 301 Numerical Methods
3 0 0
3 3
EC 301 Solid State Devices
3 0 0
3 3
EC 302 Circuit Theory & Networks
3 1 0
4 4
CS(ECE) 301
Data Structure 3 0 0
3 3
M(CS) 391 Numerical Methods Lab
0 0 3
3 2
7
Department of Electronics and
Communication Engineering
EC 392 Circuit Theory & Network Lab
0 0 3
3 2
CS(ECE) 391
Data Structure Lab
0 0 3
3 2
MC381 Technical Skill Development
0 0
2 2 2Units
Semester IV
PH(ECE)401
Physics II 3 0
0 3 3
EC 401 Signals & Systems
3 0
0 3 3
EC 402 Analog Electronic Circuits
3 1
0 4 4
EC 403 Digital Electronic And
Circuits
2 2 0 4 3
EC 404 Analog Communication
3 0
0 3 3
PH(ECE) 491
Physics II Lab 0 0 3 3 2
EC 492 Analog Electronic
Circuits Lab
0 0 3 3 2
EC 493 Digital Electronic And Circuits Lab
0 0 3 3 2
EC 494 Analog Communication Lab
0 0 3 3 2
HU 481
Technical Report Writing & Language Practice
0 0 2 2 1
Semester V
HU 501 Environmental Science
2 0
0 2 2
EC 501 Digital Communication Systems
2 2 0 4 3
8
Department of Electronics and
Communication Engineering
EC 502 Microprocessor & Micro Controller
3 0 0 3 3
EC 503 Digital Signal Processing
3 0 0 3 3
EC 504A
EC 504B EC504C
Power Electronics
Electrical & Electronics Measurement Telecommunication Systems
3 0 0 3 3
EC 591 Digital Communication
Systems Lab
0 0 3 3 2
EC 592 Microprocessor & Micro Controller Lab
0 0 3 3 2
EC 593 Digital Signal Processing Lab
0 0 3 3 2
EC 581 Mini Project -I 0 0 4 4 2
MC 581 Group Discussion Practice
0 0 2 2 2 Units
Semester VI
EC 601 EM Wave Propagation & Antenna
2 2 0 4 3
EC 602 Information Theory & Coding
2 2 0 4 3
EC 603 Control System 3 0 0 3 3
EC 604A EC 604B
Object Oriented Programming Advanced Microcontroller & Embedded
3 0 0 3 3
9
Department of Electronics and
Communication Engineering
EC 604C
System Optical Fibre Communication
EC 605A
EC 605B EC 605C
Engineering
System Design & Analysis
Material Science & Engineering Computer Communication & Networks
3 0 0 3 3
EC 691 EM Wave Propagation & Antenna Lab
0 0 3 3 2
EC 693 Control System Engineering Lab
0 0 3 3 2
EC 694A EC 694B
EC 694C
Object Oriented Programming Lab Advanced Microcontroller & Embedded
System Lab Optical Fibre Communication Lab
0 0 3 3 2
EC 681 Mini Project -II 0 0 12 12 6
EC 682 Industrial Training (4 Weeks)
0 0 0
0 1
Semester VII
HU 701 Organizational Behaviour, Values & Ethics
2 1 0 3 2
10
Department of Electronics and
Communication Engineering
EC 701 RF & Microwave Engineering
3 0 0 3 3
EC 702 VLSI & Microelectronics
3 1 0 4 4
EC 703A
EC 703B EC 703C
Digital Image Processing
Computer Organization & Architecture Data Base Management Systems
3 0 0 3 3
EC 704A
EC 704B EC 704C
Artificial
Intelligence & Robotics Biomedical Electronics & Imaging Renewable Source & Applications
3 0 0 3 3
EC 791 RF & Microwave Engineering
Lab
0 0 0
3 2
EC 792 VLSI & Microelectronics Lab
0 0 0
3 2
EC 793A EC 793B EC 793C
Digital Image Processing Lab Computer Organization & Architecture Lab Data Base Management
0 0
0
3 2
11
Department of Electronics and
Communication Engineering
Systems Lab
EC 781 Project I 0 0 6 3
MC 782 Technical Seminar Presentation
0 0 3
3 3 Units
Semester VIII
HU 801 Industrial & Financial Management
2 1 0 3 2
EC 801 Advanced Communication Systems
3 0 0 3 3
EC 802A EC 802B EC 802C
Advanced Semiconductor Devices EMI / EMC Mobile
Communication And Network
3 0 0 3 3
EC 803A EC 803B
EC 803C
Software Engineering Physical
Design, Verification & Testing Soft Computing
3 1 0 4 4
EC 891 Advanced Communication Lab
0 0 3 3 2
EC881 Project II 0 0 12 12 6
EC882 Grand Viva 0 0 0 0 2
Total 198
12
Department of Electronics and
Communication Engineering
CO1 Able to explain the applicability of determinant
and matrix in the different types of engineering
problem.
CO2 Able to apply Mean value theorems &
expansion of function in engineering field.
CO3 Able to apply the area & volume integrals in
different engineering problems.
CO4 Able to apply vector concepts in numerous
engineering experiments and problems.
CO5 Application of improper integral in engineering
field.
Course Outcome (CO)
M101: Mathematics I
13
Department of Electronics and
Communication Engineering
CO1 Able to apply fundamental concepts of
thermodynamics in different engineering
applications.
CO2 Able to analyze & design simple and
technologically advance electrical and energy
storage devices
CO3 Able to prepare composites, Synthetic
polymers, etc.
CO4 Able to apply the knowledge of chemical
reactions to industries and scientific and
technical fields.
CO5 Able to apply the knowledge of corrosion to
prevent corrosion in different industries.
CO6 Capable to evaluate theoretical and practical
aspects relating to the transfer of the
production of chemical products from
laboratories to the industrial scale, in
accordance with environmental considerations.
Course Outcome (CO)
CH101: Chemistry
14
Department of Electronics and
Communication Engineering
CO1 Able to understand basics of R , L , C circuit
elements and voltage and current sources.
CO2 Able to Appreciate and analyze DC , AC and
magnetic circuits using KVL and KCL.
CO3 Able Understand working principle of various
analogue electrical measuring instruments.
CO4 Able to Comprehend the working of DC
machines, transformers and induction Motors.
EE101: Basic Electrical Engineering
Course Outcome (CO)
15
Department of Electronics and
Communication Engineering
CO1 Able to understand basic grammar principles.
CO2 Able to write clear and coherent passages,
effective letters for job application and
complaints, technical reports.
CO3 Able to enhance reading comprehension.
CO4 Able to comprehend English speech sound
system, stress and intonation.
Course Outcome (CO)
HU101: Communicative English
16
Department of Electronics and
Communication Engineering
CO1 Able to determine the resultant force and
moment for a given system of forces.
CO2 Able to analyze planar and spatial systems to
determine the forces in members of trusses,
frames and problems related to friction.
CO3 Able to calculate the motion characteristics of
a body subjected to a given force system.
CO4 Able to determine the deformation of a shaft
and understand the relationship between
different material constants.
CO5 Determine the centroid and second moment of
area.
Course Outcome (CO)
ME101: Engineering Mechanics
17
Department of Electronics and
Communication Engineering
CO1 Able to understand advanced skills of
Technical Communication in English through
Language Laboratory.
CO2 Able to apply listening, speaking, reading and
writing skills in societal and professional life.
CO3 Able to demonstrate the skills necessary to be
a competent Interpersonal communicator.
CO4 Able to analyse communication behaviours.
CO5 Able to adapt to multifarious socio-economical
and professional arenas with the help of
effective communication and interpersonal
skills.
Course Outcome (CO)
HU191: Language Laboratory & Seminar
Presentation
18
Department of Electronics and
Communication Engineering
CO1 Able to analyse different parameters of water
considering environmental issues.
CO2 Able to operate different types of instruments
for estimation of small quantities chemicals
used in industries and scientific and technical
fields.
CO3 Able to work as an individual also as an team
member
CO4 Able to synthesize Nano and polymer
materials.
CO5 Capable to design innovative experiments
applying the fundamentals of chemistry
Course Outcome (CO)
CH191: Chemistry Laboratory
19
Department of Electronics and
Communication Engineering
CO1 Able to determine of B/H curve of a magnetic
material.
CO2 Able to analyze AC series, parallel and
balanced three phase circuits.
CO3 Able to determine Voltage regulation and
efficiency of a single phase transformer by
direct loading.
CO4 Able to control the Speed of a DC motor by
varying: - a. field current with armature
voltage kept constant b. armature voltage with
field current kept constant.
CO5 Able to study the Reversal of direction of
rotation of a three phase induction motor.
Course Outcome (CO)
EE191: Basic Electrical Engineering
Laboratory
20
Department of Electronics and
Communication Engineering
CO1: Able to draw Orthographic projections of Lines,
Planes, and Solid.
CO2: Able to construct Isometric Scale, Isometric
Projections and Views.
CO3: Able to draw Sections of various Solids
including Cylinders, cones, prisms and
pyramids.
CO4: Able to draw projections of lines, planes,
solids, isometric projections and sections of
solids including Cylinders, cones, prisms and
pyramids using AutoCAD.
Course Outcome (CO)
ME191: Engineering Drawing &
Graphics
21
Department of Electronics and
Communication Engineering
CO1: Able to up-to-date, in-depth knowledge of an
academic specialty, as well as a broad range of cultural and general knowledge.
CO2: Able to exhibit the professional knowledge and accepting ethical responsibility to the problems
of industry and society.
CO3: Able to develop Character, Comradeship, Discipline, Leadership, Secular Outlook, Spirit of Adventure and Ideals of Selfless Service
amongst the Youth of the Country;
CO4: Able to develop confidence for self-education for lifelong learning of advancements being happened around the world.
Course Outcome (CO)
XC181: Extra-Curricular Activity
(NSS/ NCC)
22
Department of Electronics and
Communication Engineering
CO1: Able to apply the knowledge of first order
differentiation in engineering field.
CO2: Able to analyse type of higher order equations and apply in numerous engineering application.
CO3: Able to analyze graph theory concepts in
explaining the behavior of electrical, communication and electromagnetic field.
CO4: Able for application of Laplace Transform for solving various engineering problems.
Course Outcome (CO)
M201: Mathematics II
23
Department of Electronics and
Communication Engineering
CO1: Able to explain the different types of
vibrations.
CO2: Able to apply the laser principles to holography.
CO3: Able to analyze the problems of black body radiation.
CO4: Able to evaluate X-ray in different
experiments/processes.
Course Outcome (CO)
PH201: Physics I
24
Department of Electronics and
Communication Engineering
CO1 Able to identify semiconductor materials, draw
energy band diagram, distinguish between
intrinsic and extrinsic semiconductor,
calculate drift and diffusion current
component.
CO2 Able to characterize semiconductors, diodes,
transistors and operational amplifiers.
CO3 Able to know the application of Diode, BJT &
OPAMP.
CO4 Able to identify functions of digital Multimeter,
cathode ray oscilloscope and transducers in
the measurement of physical variables.
Course Outcome (CO)
EC201: Basic Electronics Engineering
25
Department of Electronics and
Communication Engineering
CO1 Able to develop algorithms for mathematical
and scientific problems.
CO2 Able to understand the components of
computing systems.
CO3 Able to choose data types and structures to
solve mathematical and scientific problem.
CO4 Able to develop modular programs using
control structures.
CO5 Able to write programs to solve real world
problems using object oriented features.
Course Outcome (CO)
CS201: Computer Fundamentals &
Principle of Computer Programming
26
Department of Electronics and
Communication Engineering
CO1 Able to apply fundamental concepts of
thermodynamics to engineering applications.
CO2 Able to estimate thermodynamic properties of
substances in gas and liquid states
CO3 Capable to determine thermodynamic
efficiency of various energy related processes
CO4 Able to Know the basic principles of fluid
mechanics
CO5 Able to analyze fluid flow problems with the
application of the momentum and energy equations
Course Outcome (CO)
ME201: Engineering Thermodynamics &
Fluid Mechanics
27
Department of Electronics and
Communication Engineering
CO1 Able to know some basic commands of DOS,
Windows and Linux Operating System, File handling and Directory structures, file permissions, creating and editing simple C
program, compilation and execution of C program..
CO2 Able to write C Programs on variable, expression, operator and type-casting using Writing C Programs using different structures
of if-else, switch-case, loop (for loop, while loop and do-while loop) and use of break and
continue statement and functions.
CO3 Able to write C Programs demonstrating
concept of Single & Multidimensional arrays, Function and Recursion, Pointers, address of operator, declaring pointers and operations on
pointers, structures, union and pointer to structure, String and command line arguments, dynamic memory allocation and
File Programming.
CO4 Able to implement modular programs using
functions.
Course Outcome (CO)
CS291: Computer Fundamentals &
Principle of Computer Programming
Laboratory
28
Department of Electronics and
Communication Engineering
CO1: Able to use CRO, Signal generator,
spectrometer, polarimeter and GM counter for making measurements.
CO2: Able to test optical components using principles of interference and diffraction of
light.
CO3: Able to determine the selectivity parameters in electrical circuits.
CO4: Able to determine the width of narrow slits, spacing between close rulings using lasers and
appreciate the accuracy in measurements.
PH291: Physics I Laboratory
Course Outcome (CO)
29
Department of Electronics and
Communication Engineering
CO1 Knowledge of Electronic components such as
Resistors, Capacitors, Diodes, Transistors
measuring equipment like DC power supply,
Multimeter, CRO, Signal generator, DC power
supply.
CO2 Analyze the characteristics of Junction Diode,
Zener Diode, BJT & FET and different types of
Rectifier Circuits.
CO3 Determination of input-offset voltage, input
bias current and Slew rate, Common-mode
Rejection ratio, Bandwidth and Off-set null of
OPAMPs.
CO4 Able to know the application of Diode, BJT &
OPAMP.
Course Outcome (CO)
EC291: Basic Electronics Engineering
Laboratory
30
Department of Electronics and
Communication Engineering
CO1: Able to study and practice on machine tools
and their operations.
CO2: Able to practice on manufacturing of components using workshop trades including fitting, carpentry, foundry and welding.
CO3: Able to identify and apply suitable tools for
machining processes including turning, facing, thread cutting and tapping.
CO4: Able to apply basic electrical engineering knowledge for house wiring practice.
Course Outcome (CO)
ME292: Workshop Practice
31
Department of Electronics and
Communication Engineering
CO1: Able to handle emotions including tolerance
and behavioural responses, building positive friendships and bonding with peers and classmates, learning to show understanding
and to demonstrate respect for the opinions, personal space and beliefs of others.
CO2: Able to develop the self-motivation, raised aspirations and belief in one’s own abilities, defining and committing to achieving one’s
goals.
CO3: Able to assess the requirements of a task, identifying the strengths within the team,
utilising the diverse skills of the group to achieve the set objective, awareness of risk/safety.
CO4: Able to demonstrate the clear briefing and
listening skills, not being afraid to ask for help and support when necessary.
CO5 Able to develop the employability skills – time and resource management, conflict resolution,
teaching and mentoring others
Course Outcome (CO)
MC281: Soft Skill Development
32
Department of Electronics and
Communication Engineering
CO1: Able to apply the knowledge of Fourier series
and transform in engineering problems like finding the frequency of wave propagation.
CO2: Able to apply the knowledge of Complex Analysis viz the Cauchy Residue Theorem to
evaluate integrals and sum series.
CO3: Able to solve the stochastic model of engineering problems using the idea of different kind of engineering problems.
CO4: Able to know that differential equation is a
very important mathematical model of many problems in the application of engineering and also be able to utilize theories and methods
learned in the course to analyze and solve a differential equation.
Course Outcome (CO)
M301: Mathematics III
33
Department of Electronics and
Communication Engineering
CO1: Able to numerically approximate functions
with polynomials.
CO2: Able to understand basics of finite precision arithmetic, conditioning of problems and stability of numerical algorithms.
CO3: Able to solve numerically a scalar nonlinear
equation.
CO4: Able to solve dense systems of linear equations and have a working knowledge of LU factorizations for these problems.
Able to use the method of lines to solve basic
partial differential equations.
Course Outcome (CO)
M(CS)301: Numerical Methods
34
Department of Electronics and
Communication Engineering
CO1: Able to understand the Energy band diagram,
charge carrier transport phenomenon and recombination-generation process of different types of semiconductor materials.
CO2: Able to study and analyze the Characteristics
& Current flow of semiconductor devices like BJT, JFET, MOSFET, MESFET, HEMT & Metal-Semiconductor Junction & Hetero
Junction Devices.
CO3: Able to analyze the design parameters of MOSFET i.e- Channel length & width,
depletion width, surface field and potential, ON resistance, trans conductance, equivalent circuits, amplification factors, capacitances,
noise margins, scaling & short channel effects MOSFET .
CO4: Able to Illustrate rectifying properties of different types of junction diode, Importance of reverse current in optical detectors, photo-
diodes, solar cells, Tunnel diode, LED & Thyristors.
Course Outcome (CO)
EC301: Solid State Devices
35
Department of Electronics and
Communication Engineering
CO1: Able to understand basics electrical circuits
with nodal and mesh analysis.
CO2: Able to appreciate electrical network theorems.
CO3: Able to apply Laplace Transform for steady state and transient analysis.
CO4: Able to determine different network functions.
Course Outcome (CO)
EC302: Circuit Theory & Networks
36
Department of Electronics and
Communication Engineering
CO1: Able to access how the choices of data
structure & algorithm methods impact the performance of program.
CO2: Able to Solve problems based upon different data structure & also write programs.
CO3: Able to Choose an appropriate data structure
for a particular problem.
Course Outcome (CO)
CS (ECE) 301: Data Structure
37
Department of Electronics and
Communication Engineering
CO1: Able to numerically approximate functions
with polynomials.
CO2: Able to understand basics of finite precision arithmetic, conditioning of problems and stability of numerical algorithms.
CO3: Able to solve numerically a scalar nonlinear
equation.
CO4: Able to solve dense systems of linear equations and have a working knowledge of LU factorizations for these problems.
CO5 Able to use the method of lines to solve basic
partial differential equations.
Course Outcome (CO)
M (CS) 391: Numerical Methods
Laboratory
38
Department of Electronics and
Communication Engineering
CO1: Explain the concept of circuit laws and
network theorems and apply them to laboratory measurements.
CO2: Become proficient with computer skills (e.g., TSPICE and PSPICE) for the analysis and
design of circuits.
CO3: Understand Transient Response in Series & Parallel Resonant circuits, R-L & R-C Networks;
CO4: Understand of Impedance (Z), and Admittance
(Y) parameters of Two-port networks.
Course Outcome (CO)
EC392: Circuit Theory & Network
Laboratory
39
Department of Electronics and
Communication Engineering
CO1: Able to design and analyze the time and space efficiency of the data structure.
CO2: Capable to identity the appropriate data structure for given problem.
CO3: Able to gathered practical knowledge on the
application of data structures.
Course Outcome (CO)
CS (ECE) 391: Data Structure
Laboratory
40
Department of Electronics and
Communication Engineering
CO1: Able to design electronic circuits using passive components.
CO2: Able to design DC power supplies.
CO3: Able to design Amplifier & Analog Filter Circuits.
CO4 Able to design Simple Digital electronics
circuits using logic gates.
Course Outcome (CO)
MC 381: Technical Skill Development
41
Department of Electronics and
Communication Engineering
CO1: Able to understand basic laws of electromagnetism using vector calculus.
CO2: Able to apply Schrodinger equation to solve quantum mechanical problems.
CO3: Able to explain the behavior of electromagnetic
waves.
CO4 Able to discriminate between different
statistics.
Course Outcome (CO)
PH (ECE) 401: Physics II
42
Department of Electronics and
Communication Engineering
CO1: Able to characterize and analyze the properties
of continuous time and discrete time signals
and systems
CO2: Able to analyze continuous time and discrete
time systems in time domain.
CO3: Able to represent continuous and discrete
systems in the Frequency domain using
Fourier Analysis tools like CTFS, CTFT, DTFS
and DTFT.
CO4 Able to understand the effects of sampling a
continuous time signal
Able to analyze continuous time and discrete
time systems using Laplace transforms and Z
Transforms.
Course Outcome (CO)
EC401: Signal & Systems
43
Department of Electronics and
Communication Engineering
CO1 Able to design filters, regulators for dc power
supply and SMPS circuits
CO2 Able to illustrate voltage amplifier and power
amplifier using BJT
CO3 Able to analyze feedback amplifier and RC &
LC sinusoidal oscillator circuits.
CO4 Able to implement mathematical circuits,
precision rectifier, voltage to current and
current to voltage converter using op-Amp.
CO5 Able to develop multivibrator circuits using
555 timer, VCO Circuits.
Course Outcome (CO)
EC402: Analog Electronic Circuits
44
Department of Electronics and
Communication Engineering
CO1 Able to understand number systems
conversions and Boolean algebra and design
logic circuits using logic gates to their simplest
forms using DeMorgan’s Theorems; Karnaugh
Maps.
CO2 Able to design & analyze combinational
circuits and logic circuits with Programmable
Logic Devices.
CO3 Able to design and analyze of various
synchronous and asynchronous sequential
circuits using State Diagrams & Tables.
CO4 Able to understand Digital To Analog
Conversion, Analog To Digital Conversion
technique and corresponding circuits.
CO5 Able to Analyze logic family interfaces,
switching circuits & memory storage devices to
Plan and execute projects.
Course Outcome (CO)
EC403: Digital Electronic & Circuits
45
Department of Electronics and
Communication Engineering
CO1 Able to describe different types of noise and
predict its effect on various analog
communication systems.
CO2 Able to analyze energy and power spectral
density of the signal.
CO3 Able to express the basic concepts of analog
modulation schemes
CO4 Able to evaluate analog modulated waveform in
time /frequency domain and also find
modulation index.
CO5 Able to develop understanding about
performance of analog communication
systems.
CO6 Able to calculate bandwidth and power
requirements for analog systems.
CO7 Able to analyze different characteristics of
receiver.
Course Outcome (CO)
EC404: Analog Communication
46
Department of Electronics and
Communication Engineering
CO1 Able to understand the motion of
electrons in crossed electric and
magnetic field.
CO2 Able to explain the photoelectric effect.
CO3 Able to demonstrate the Hall effect in
conductors and semi-conductors.
CO4 Able to measure the band gap for semi-
conductors.
CO5 Able to understand the motion of
electrons in crossed electric and
magnetic field.
Course Outcome (CO)
PH (ECE) 491: Physics II Laboratory
Laboratory
47
Department of Electronics and
Communication Engineering
CO1 Able to construct Regulated Power
Supply.
CO2 Able to design Transistor based single
stage R-C coupled voltage amplifier and
different classes of power amplifier
circuit with given specification.
CO3 Able to construct a-stable, bi-stable and
mono-stable mode timer circuit using IC
555.
CO4 Able to design Inverting and Non-
inverting amplifier, Integrator,
differentiator, Wien bridge and RC
phase shift oscillator using Op-Amp.
EC492: Analog Electronic Circuits
Laboratory
Course Outcome (CO)
48
Department of Electronics and
Communication Engineering
CO1: Able to understand the fundamental concepts
and techniques used in digital electronics.
CO2: Able to understand and examine the structure
of various number systems, De-Morgan’s law,
Boolean algebra and its application in digital
design.
CO3: Able to understand, analyse the timing
properties (input setup and hold times,
minimum clock period, output propagation
delays) and design various combinational and
sequential circuits using various metrics:
switching speed, throughput/latency, gate
count and area, energy dissipation and power.
CO4: Able to understand different digital circuits
using Programmable Logic Devices.
CO5: Able to know how to interface digital circuits
with ADC & DAC.
EC493: Digital Electronic Circuits
Laboratory
Course Outcome (CO)
49
Department of Electronics and
Communication Engineering
CO1: Able to analyse energy and power spectral density of the signal and Calculate bandwidth and power requirements for analog systems.
CO2: Able to express the basic concepts of analog
modulation schemes.
CO3: Able to describe different types of noise and predict its effect on various analog communication systems.
CO4: Able to evaluate analog modulated waveform in
time /frequency domain and also find modulation index.
CO5: Able to analyse different characteristics of receiver.
Course Outcome (CO)
EC494: Analog Communication Laboratory
50
Department of Electronics and
Communication Engineering
CO1: Able to develop listening skills and its sub
skills through language lab audio device.
CO2: Able to acquire various experience on speaking skills and its sub skills.
CO3: Able to practice different master linguistic and paralinguistic features.
CO4: Able to practice conversation using language
lab audio visual input.
CO5: Able to participate in group discussion through audio visual input and acquainting them with key strategies for success.
CO6: Able to enhance writing skills and its sub
skills.
Course Outcome (CO)
HU481: Technical Report Writing &
Language Practice Laboratory
51
Department of Electronics and
Communication Engineering
CO1: Able to get the knowledge of General Basic ideas of environment.
CO2: Understand the Environmental degradation, Elements of ecology, Structure and function of
ecosystem, Biogeochemical Cycle and Biodiversity.
CO3: Able to know the Air pollution and control Atmospheric Composition.
CO4: Able to get the knowledge of Energy balance,
Green house effects, Lapse rate, Atmospheric dispersion, Definition of pollutants and contaminants, Primary and secondary
pollutants, Depletion Ozone layer.
CO5: Understand the Water Pollution and Control, Land Pollution, Noise Pollution and Environmental Management.
Course Outcome (CO)
HU501: Environmental Science
52
Department of Electronics and
Communication Engineering
CO1: Able to apply the knowledge of statistics in Digital communication and its modelling.
CO2: Able to understand the concepts of signal, geometrical representation of signal and the
performance of digital communication system in the presence of noise.
CO3: Able to analyze sampling, quantization in digital transmission, PAM, PCM, companding,
DPCM, Adaptive Modulation.
CO4: Apply the concept of line coding techniques and their PSD, ISI in digital communication.
CO5: Analyze the digital modulation techniques, generation and detection, power spectra and
their probability of error performance.
Course Outcome (CO)
EC501: Digital Communication Systems
53
Department of Electronics and
Communication Engineering
CO1: Able to correlate the architecture, instructions,
timing diagrams, addressing modes, memory interfacing, interrupts, data communication of
8085.
CO2: Able to interpret the 8086 Microprocessor-Architecture, Pin details, memory segmentation, addressing modes, basic
instructions, interrupts.
CO3: Able to recognize 8051 micro controller hardware, input/output pins, ports, external memory, counters and timers, instruction set,
addressing modes, serial data i/o, interrupts.
CO4: Able to apply instructions for assembly language programs of 8085, 8086 and 8051.
CO5: Able to design peripheral interfacing model using IC 8255, 8253, 8251 with IC 8085, 8086
and 8051.
Course Outcome (CO)
EC502: Microprocessor &
Microcontroller
54
Department of Electronics and
Communication Engineering
CO1: Able to find DFT of a given signal through Fast
Fourier Transform Techniques.
CO2: Able to design FIR and IIR type digital filters.
CO3: Able to identify filter structures and evaluate the coefficient quantization effects.
CO4: Able to understand sample rate conversion techniques.
CO5: Able to compare the architectures of DSP and
General Purpose Processors.
Course Outcome (CO)
EC503: Digital Signal Processing
55
Department of Electronics and
Communication Engineering
CO1: Able to know concepts of semiconductor
switches.
CO2: Able to understand operation and applications of different power electronic converters
CO3: Able to appreciate working of PWM techniques.
CO4: Able to comprehend operation of inverter
Course Outcome (CO)
EC504A: Power Electronics
56
Department of Electronics and
Communication Engineering
CO1: Able to understand and estimate errors in a
measurement system.
CO2: Able to identify the instrument suitable for specific measurements.
CO3: Able to estimate accurately the values of R, L and C employing suitable bridges.
CO4: Able to understand the basic principles of
transducers for displacement, velocity, temperature and pressure.
CO5: Able to operate special measuring instruments such as Wave Analyser, Harmonic Distortion
Analyser and Spectrum Analyser.
CO6: Able to identify data acquisition system for a specific application.
Course Outcome (CO)
EC504B: Electrical & Electronics
Measurement
57
Department of Electronics and
Communication Engineering
CO1: Able to understand the components and
Instruments of different Switching System.
CO2: Able to enumerate co-axial fibre optic cable, PCM technique.
CO3: Able to illustrate Traffic Engineering and Subscriber loop system.
CO4: Able to describe Stored Program Control
System.
CO5: Able to outline about the standards of Modems and IP Telephony.
Course Outcome (CO)
EC504C: Telecommunication Systems
58
Department of Electronics and
Communication Engineering
CO1: Able to understand basic theories of Digital
communication system in practical.
CO2: Understand the concepts of signal, geometrical representation of signal and the performance
of digital communication system in the presence of noise.
CO3: Analyze sampling, quantization in digital transmission, PAM, PCM, companding, DPCM,
Adaptive Modulation.
CO4: Able to use the Polar, Unipolar, Bipolar NRZ, RZ and Manchester line coding techniques and their PSD, ISI in digital communication.
CO5: Analyze the digital modulation techniques,
generation and detection, power spectra and their probability of error performance.
EC591: Digital Communication Laboratory
Course Outcome (CO)
59
Department of Electronics and
Communication Engineering
CO1: Able to Understand and apply the
fundamentals of assembly level programming of microprocessors and microcontroller.
CO2: Work with standard microprocessor real time interfaces including GPIO, serial ports, digital-
to-analog converters and analog-to-digital converters;
CO3: Analyze abstract problems and apply a combination of hardware and software to
address the problem;
CO4: Use standard test and measurement equipment to evaluate digital interfaces.
Course Outcome (CO)
EC592: Microprocessor & Microcontroller
Laboratory
60
Department of Electronics and
Communication Engineering
CO1: Ability to analyze sampled Sinusoidal signal,
various sequences and different arithmetic operations, convolution properties of convolution, circular convolution,
differentiation between linear and circular convolutions, sectioned convolution.
CO2: Understand and analyze z-transform of various sequences - verification of the properties.
CO3: Acquired knowledge of Twiddle factors, DFT,
FFT, and IDFT.
CO4: Ability to design of Butterworth Filter design with different set of design parameters, using Rectangular, Hamming, Hamming, Bartlett
windows and comparisons of these designs.
CO5: Acquired knowledge of Hardware Laboratory using DSP Processors.
EC593: Digital Signal Processing
Laboratory
Course Outcome (CO)
61
Department of Electronics and
Communication Engineering
CO1: Able to learn the basic concepts of
electromagnetic wave radiation and reception.
CO2: Able to acquired knowledge for the analysis of Transmission Lines and Antennas.
CO3: Able to understand important and fundamental antenna engineering parameters
and terminology.
CO4: Able to develop the performance characteristics of array antennas, wire and aperture antennas.
CO5: Able to acquired knowledge of Application of
Different types of Antennas.
Course Outcome (CO)
EC601: EM wave Propagation & Antenna
62
Department of Electronics and
Communication Engineering
CO1: Able to understand the concepts of
information, mutual information and entropy and various source coding techniques
CO2: Able to analyse the need for error control
techniques in a digital communication system channel models, channel capacity and channel coding techniques.
CO3: Able to apply linear algebra, concept of Galois field, conjugate roots, minimal polynomial in
channel coding techniques for error control.
CO4: Able to generate different error control codes like linear block codes, cyclic codes, BCH codes, and perform error detection and
correction.
CO5: Able to design the circuit for different error
control coding techniques.
Course Outcome (CO)
EC602: Information Theory & Coding
63
Department of Electronics and
Communication Engineering
CO1: Able to do mathematical modelling and
derivation of transfer function of various systems.
CO2: Able to determine the stability of system and
analyse the system in time domain.
CO3: Able to analyse the systems in frequency
domain.
CO4: Able to do state space modelling of system and its analysis.
Course Outcome (CO)
EC603: Control System
64
Department of Electronics and
Communication Engineering
CO1: Able to understand fundamental concepts in
object oriented approach.
CO2: Able to analyze design issues in developing
OOP applications.
CO3: Able to write computer programs to solve real
world problems in Java.
CO4: Able to analyze source code API
documentations.
CO5: Able to create GUI based applications.
Course Outcome (CO)
EC604A: Object Oriented Programming
65
Department of Electronics and
Communication Engineering
CO1: Able to design, development, programming,
and testing of a PIC microcontroller & ARM-
based embedded system
CO2: Able to demonstrate a working knowledge of
the necessary steps and methods used to
interface a microcontroller system to devices
such as motors, sensors, etc.
CO3: Able to identify the hardware and software
components of appropriate embedded system
architecture for the given application.
CO4: Able to Know the hardware Design, Software
Development & RTOS for the Embedded
Systems.
CO5: Able to write programs optimized performance
of an embedded system and validate.
Course Outcome (CO)
EC604B: Advanced Micro Controller &
Embedded System
66
Department of Electronics and
Communication Engineering
CO1: Able to identify and characterize different
components of an Optical Fiber Communication link.
CO2: Able to analyze optical source, Fiber and Detector operational parameters.
CO3: Able to compute optical fiber link design
parameters.
CO4: Able to understand WDM, Optical Amplifiers, Optical Switching and networking technology concepts.
Course Outcome (CO)
EC604C: Optical Fiber Communication
67
Department of Electronics and
Communication Engineering
CO1: Able to identify, generalise and adapt
methodologies for analysing designs and systems.
CO2: Able to apply and critique analysis techniques to review and construct arguments for design
or operational decisions under uncertainty.
CO3: Able to synthesise technical engineering discipline knowledge and whole-of-system methodologies to improve outcomes for a real-
world client in a team environment.
CO4: Able to generate concise and coherent documentation for both a technical and general audience am environment.
CO5: Able to design, research and defend an
analysis of a complex engineering problem or system. am environment.
Course Outcome (CO)
EC605A: Engineering System Design &
Analysis
68
Department of Electronics and
Communication Engineering
CO1: Able to correlate the Atoms and their binding,
Bonds, Crystal Systems Amorphous Materials;
Lattice defects, surface and volume defects.
CO2: Able to classify magnetic materials –
Diamagnetism, Paragnetism, Ferrognetism,
Ferrimagnetism, Magnetic Domains, hard and
Soft Materials, SQUID.
CO3: Able to understand the properties and
usefulness of nanomaterials in medicine,
biology and sensing.
CO4: Able to identify Materials for Optical
Communication, Data Storage, Magneto
electronic Materials, Materials for Display
Devices.
CO5: Able to characterize the superconducting
materials.
CO6: Able to understand modelling of composite
materials by finite element analysis.
Course Outcome (CO)
EC605B: Material Science & Engineering
69
Department of Electronics and
Communication Engineering
CO1: Able to understand how communication works
in computer networks and to understand the
basic terminology of computer networks.
CO2: Able to realize the role of protocols in
networking and to analyze the services and
features of the various layers in the protocol
stack.
CO3: Able to recognize design issues in Network
Security and to understand security threats,
security services and mechanisms to counter
them.
Course Outcome (CO)
EC605B: Computer Communication &
Network
70
Department of Electronics and
Communication Engineering
CO1: Able to define, identify and list out types
transmission line, its characteristics in various load conditions also to name, recognize
antennas along with its characteristics in the field of communication.
CO2: Able to analyse, judge, justify and recommend
the suitable transmission line and antenna
with their engineering arithmetic – for the
specific purpose.
CO3: Able to sketch, show, solve and implement
suitably the various Transmission line
component, passive devices, software tools and
measuring instruments in the field of Radio
Frequencies, for the betterment of
communication, research and development
and day to day life, with the utilization of
engineering mathematics.
EC 691: EM Wave Propagation & Antenna
Laboratory
Course Outcome (CO)
71
Department of Electronics and
Communication Engineering
CO1: Able to explain the mathematical techniques of
system module analysis with the software, (i.e. MATLAB & p-SPICE).
CO2: Analyze the step response for the electronic
system along with the continuous and discrete time control techniques, including analog and digital PI, PD, PID controllers, fuzzy logic
controllers, neural network controllers, root locus, Bode-plot, Nyquist Plot.
CO3: Able to design the multivariable control (control of several interacting variables of a
physical process) and strategies for multivariable processes.
CO4: Able to implement some basic concepts in nonlinear control, steady-state error, setup
time, percentage peak overshoots, gain margin, phase margin along with the lead compensator
in forward path transfer functions.
CO5: Design of different types of controller system with servomotor and microprocessor /microcontroller.
Course Outcome (CO)
EC693: Control System Engineering
Laboratory
72
Department of Electronics and
Communication Engineering
CO1: Able to Implement Object Oriented
Programming Concepts (class, constructor,
overloading, inheritance, overriding) in java.
CO2: Able to use and create packages and graphical
user interface in Java programs
CO3: Able to create Applets
CO4: Able to implements exception handling and
multithreading in java.
Course Outcome (CO)
EC694A: Object Oriented Programming
Laboratory
73
Department of Electronics and
Communication Engineering
CO1: Able to familiarize with the Kiel µVision-3/4
and IAR Embedded Workbench tools.
CO2: Able to understand the internal organization of some popular microprocessors (ARM) /microcontrollers (PIC).
CO3: Able to design, development, programming,
and testing of an ARM Processor & PIC microcontroller-based embedded system.
CO4: Able to experience with a set of tools for embedded systems programming and
debugging
CO5: Able to develop existing embedded systems by formulating the system design problem including the design constraints, create a
design that satisfies the constraints, implement the design in hardware and
software, and measure performance against the design constraints.
Course Outcome (CO)
EC694B: Advanced Microcontroller &
Embedded System Laboratory
74
Department of Electronics and
Communication Engineering
CO1: Able to know the fundamentals, advantages
and advances in optical communication system.
CO2: Familiarize with types, basic properties and transmission characteristic of optical fibres.
CO3: Experience with the Knowledge of working and
analysis of optical amplifiers and important parts at the transmitter (Semiconductor lasers/LEDs, modulators etc) as well as at the
receiver sides (optical detector etc.) of the optical communications system.
CO4: Develop the knowledge on Configuration and architecture of coherent optical
communication, advanced system techniques and nonlinear optical effects and their
applications.
Course Outcome (CO)
EC694C: Optical Fiber Communication
Laboratory
75
Department of Electronics and
Communication Engineering
CO1: Able to solve the real world problems
CO2: Able to understand the concepts of design methodologies & its implementation
CO3: Able to implement the testing methodologies.
CO4: Able write a Technical report/thesis
Course Outcome (CO)
EC681: Project-II
76
Department of Electronics and
Communication Engineering
CO1: Able to increase exposure to industries.
CO2: Able to be accustomed with working environment in industries.
CO3: Able to get the opportunity to work with live projects.
Course Outcome (CO)
EC682: Industrial Training
77
Department of Electronics and
Communication Engineering
CO1: Able to be familiarized with various aspects of
organizational behaviour, personality and attitude, perception, motivation etc.
CO2: Able to explain about group behaviour,
communication and leadership.
CO3: Able to analyze various features of leadership
and organizational politics.
CO4: Able to critically analyse the social, political, organisational, economic and environmental
drivers that both enable and limit public policy reform and apply to professional practice.
CO5: Able to use appropriate ethical ideas and reflective practice skills to engage in
professional policy practice and scholarship.
Course Outcome (CO)
HU701: Organizational Behaviour,
Values & Ethics
78
Department of Electronics and
Communication Engineering
CO1: Able to analyze the Microwave waveguide, Planar transmission lines and High frequency circuit elements.
CO2: Able to estimate the direction of waves through
passive waveguide components and representation of Scattering matrix.
CO3: Able to illustrate the construction and working principle of Microwave tubes, Semiconductor
Microwave Devices and their typical characteristics and applications.
CO4: Able to demonstrate the design of microwave amplifier and the working principle of
microwave test bench.
Course Outcome (CO)
EC701: RF & Microwave Engineering
79
Department of Electronics and
Communication Engineering
CO1: Able to describe about VLSI design Flow, types of VLSI chips, ASIC design principles and design domains.
CO2: Able to illustrate the IC fabrication process,
CMOS technology and layout design.
CO3: Able to design digital VLSI circuits using CMOS techniques, TG logic, dynamic logic.
CO4: Able to develop basic building blocks of analog VLSI circuits such as MOS active load /
resistors, CMOS Current source & sink, CMOS Voltage references, CMOS OPAMP and switched capacitor circuits.
CO5: Model and design a heterogeneous FPGA based
embedded system using Cad Tools.
Course Outcome (CO)
EC702: VLSI & Microelectronics
80
Department of Electronics and
Communication Engineering
CO1: Able to explain the structure of human eye, image formation, Brightness, sensing and acquisition, storage, Processing,
Communication, Display Image Sampling and quantization, spectrum analysis.
CO2: Able to illustrate image Enhancement in the Spatial and Frequency Domain, image
transformations, Histogram processing, time and Spatial filtering.
CO3: Able to evaluate Image and video Data Compression, Redundancies.
CO4: Able to develop Morphological Processed Image
using Dilation, Erosion, Opening, closing, Hit -or-miss transformation.
CO5: Able to evaluate Image Segmentation by detection of discontinuities, Edge linking and
Boundary detection, Thresholding, Image Representation schemes, Boundary
descriptors, and Regional descriptors.
Course Outcome (CO)
EC703A: Digital Image Processing
81
Department of Electronics and
Communication Engineering
CO1: Able to recognize the architectures of
processors used in computing systems.
CO2: Able to understand memory hierarchy and virtual memory concept.
CO3: Able to design ALU and IEEE-754 single precision floating point processor.
CO4: Able to realize Micro-programmed control units
for a simple processor and a floating point processor.
CO5: Able to identify I/O data transfer techniques and future trends.
Course Outcome (CO)
EC703B: Computer Organization &
Architecture
82
Department of Electronics and
Communication Engineering
CO1: Able to analyze database requirements and determine the entities involved in the system and their relationship to one another.
CO2: Able to develop the logical design of the
database using data modeling concepts such as entity-relationship diagrams.
CO3: Able to create a relational database using a relational database package.
CO4: Able to manipulate a database using SQL.
CO5: Able to assess the quality and ease of use of
data modeling and diagramming tools.
Course Outcome (CO)
EC703C: Data Base Management System
83
Department of Electronics and
Communication Engineering
CO1: Able to learn to make self-learning/adaptive control systems for robots/intelligent systems.
CO2: Able to program an artificially intelligent robot for applications involving sensing, navigation,
path planning, and navigating with uncertainty.
CO3: Able to characterize the ways in which Artificial Intelligence is organized in robots.
CO4: Able to understand the architectures that
provide exemplars of how to transfer the principles of the paradigm into a coherent, reusable implementation on a single robot or
teams of robots.
CO5: Able to design and develop robotic systems for services and industrial applications, including safety and security, space, home, care of the
elderly, medicine;
Course Outcome (CO)
EC704A: Artificial Intelligence &
Robotics
84
Department of Electronics and
Communication Engineering
CO1: Able to understand the working principles of
the Biomedical Electronic Circuits, measure circuit performance, and solve problems in the areas of biomedical signals.
CO2: Able to understand the physical and medical
principles used as a basis for biomedical instrumentation.
CO3: Able to demonstrate & evaluate appropriate positioning skills to produce a quality
diagnostic radiographic image considering radiation protection and elements of risk for
different instrumentation methods and basic electrical safety.
CO4: Able to conduct themselves in a professional manner interacting with patients and other
members of the healthcare team to attain a common goal in modern hospital care with the profession’s Code of Ethics.
Course Outcome (CO)
EC704B: Biomedical Electronics &
Imaging
85
Department of Electronics and
Communication Engineering
CO1: Able to understand energy demand of world,
nation and the characteristics of available non-conventional energy sources & the techniques to utilize them effectively to fulfil the demand.
CO2: Able to know working of off-grid & grid-
connected renewable energy generation scheme.
CO3: Able to Grasp basics of distributed generation
system.
CO4: Able to understand and perform the various
characterization techniques of fuels.
CO5: Able to acquire the knowledge of modern energy conversion technologies.
Course Outcome (CO)
EC704C: Renewable Energy &
Applications
86
Department of Electronics and
Communication Engineering
CO1: Able to Define, identify and list out special type
transmission line, its characteristics in microwave frequencies and concept of load.
CO2: Able to analyse and use the various sources of microwave energy and the characters of its
operation.
CO3: Able to recognize, memorize, categorize, arrange and implement suitably the various
microwave passive devices with the utilization of engineering mathematics.
CO4: Able to use, compute, solve, demonstrate and apply various hardware, software tools and
measuring instruments in the field of Radio Frequencies, for the betterment of communication engineering, medical science
and various domestic and commercial engineering.
Course Outcome (CO)
EC791: RF & Microwave Engineering Laboratory
87
Department of Electronics and
Communication Engineering
CO1: Introduce digital design techniques using
VHDL and ability to write test benches in VHDL.
CO2: Acquired knowledge about FSM and how to code a FSM & ability to synthesize the VHDL
code.
CO3: Acquired knowledge for EDA tools for VLSI design /FPGA based system design.
CO4: Understand the characteristics and design methodology of combinational & sequential
logic circuits using static and dynamic CMOS logic, CMOS transmission gates logic, Pass Transistor logic, DCVSL, NORA & Domino
logic.
CO5: Ability to design layout of CMOS circuits.
Course Outcome (CO)
EC792: VLSI & Microelectronics
Laboratory
88
Department of Electronics and
Communication Engineering
CO1: Understand image formation and the role
human visual system plays in perception of gray and color image data.
CO2: Get broad exposure to and understanding of various applications of image processing in
industry, medicine, and defense.
CO3: Learn the signal processing algorithms and techniques in image enhancement and image restoration.
CO4: Acquire an appreciation for the image
processing issues and techniques and be able to apply these techniques to real world problems.
CO5: Be able to conduct independent study and
analysis of image processing problems and techniques.
Course Outcome (CO)
EC793A: Digital Image Processing
Laboratory
89
Department of Electronics and
Communication Engineering
CO1: Ability to analyze, design, implement, and test
assembly language programs.
CO2: Ability to describe the structure and functioning of a digital computer, including its overall system architecture, operating system,
and digital components.
CO3: Ability to design the data path and control unit of a simple CPU.
CO4: Able to explain the generic principles that underlie the building of a digital computer,
including data representation, digital logic and processor programming.
Course Outcome (CO)
EC793B: Computer Organization &
Architecture Laboratory
90
Department of Electronics and
Communication Engineering
CO1: Ability to understand, analyze and apply
common SQL statements including DDL, DML and DCL statements to perform different operations.
CO2: Ability to design different views of tables for
different users and to apply embedded and nested queries.
CO3: Ability to design and implement a database for a given problem according to well-known
design principles that balance data retrieval performance with data consistency.
Course Outcome (CO)
EC793C: DBMS Laboratory
91
Department of Electronics and
Communication Engineering
CO1: Ability to develop skills in presentation and
discussion of research topics in a public forum.
CO2: Able to get exposure to a variety of research projects and activities in order to enrich their
academic experience
CO3: Ability to develop and enhance leadership skills.
CO4: Able to improving communication skills, presentation skills and other soft skills.
Course Outcome (CO)
MC782: Technical Seminar Presentation
92
Department of Electronics and
Communication Engineering
CO1: Ability to understand the basic principles,
approaches, functions of management and use appropriate methods/tools of inventory classification and control in industry.
CO2: Able to identify and utilize various techniques
for improving productivity and marketing mix in the formulation of marketing strategies during the life cycle of product using work
study.
CO3: Able to get the knowledge of Cash Flow, Interest & Equivalence, inflation & Price
Change and Economic Decision Trees.
CO4: Able to understand Depreciation, Capital
Allowance Methods, Replacement and Cost Accounting.
CO5: Able to apply the concepts and tools of quality
engineering in the design of products and process controls.
Course Outcome (CO)
HU801: Industrial & Financial
Management
93
Department of Electronics and
Communication Engineering
CO1: Able to architect, interpret, and select
appropriate technologies for implementation of specified Satellite & Optical Fibre communication systems.
CO2: Able to analyse and evaluate a satellite link &
optical fibre link and suggest enhancements to improve the link performance.
CO3: Able to select an appropriate modulation, multiplexing, coding and multiple access
schemes for a given satellite communication link.
CO4: Able to analyze optical source, Fiber and Detector operational parameters.
CO5: Able to understand WDM, Optical Amplifiers,
Optical Switching and networking technology concepts.
Course Outcome (CO)
EC801: Advanced Communication
Systems
94
Department of Electronics and
Communication Engineering
CO1: Able to understand the operating principles of
modern semiconductor devices, to relate terminal properties to their internal structure, and how terminal properties will change with
operating conditions.
CO2: Able to understand the limitations of existing technology on such fast-growing and high-demanding society.
CO3: Able to innovatively project the future
development of semiconductor devices with emerging technology with nano and novel
semiconducting materials.
CO4: Able to develop insight on future development
of electronic devices and applications.
Course Outcome (CO)
EC802A: Advanced Semiconductor
Devices
95
Department of Electronics and
Communication Engineering
CO1: Able to distinguish Measurement Techniques
for Conducted Interference and the effect of power supply components on Conducted Emissions.
CO2: Able to design electronic systems that function
without errors or problems related to electromagnetic compatibility.
CO3: Able to describe the Grounding, Cabling, Shielding, Bonding mechanisms for EMC.
CO4: Able to design & analyze the EMI filters and
components for EMI/EMC standards.
CO5: Able to diagnose and solve basic electromagnetic compatibility problems.
Course Outcome (CO)
EC802B: EMI/EMC
96
Department of Electronics and
Communication Engineering
CO1: Able to identify the most important
components and functions of a mobile communication systems in physical, link and network layer.
CO2: Able to explain & compare the differences in
characteristics between different types of mobile communication systems and areas of applications for different mobile
communication systems.
CO3: Able to define & calculate the trade-offs & key performance metrics between different mobile
communication technologies & Systems.
CO4: Able to apply previous knowledge from
statistics, modelling, programming and data/telecommunications in the area of mobile
communications.
CO5: Able to independently plan, perform and document a research oriented project in the area of mobile communications.
Course Outcome (CO)
EC802C: Mobile Communication &
Network
97
Department of Electronics and
Communication Engineering
CO1: Able to illustrate different phases of developing
high end software in an industry.
CO2: Able to recognize different techniques of software testing, reusability of software and software maintenance.
CO3: Able to identify different challenges in
maintaining or updating old software.
CO4: Able to justify the strategies for testing, reusability etc. to reduce cost of development and / or maintenance.
CO5: Able to demonstrate the role and
responsibilities of software engineers in various phases of software development.
Course Outcome (CO)
EC803A: Software Engineering
98
Department of Electronics and
Communication Engineering
CO1: Able to Identify the significance of formal
verification and testable design
CO2: Able to Understand the concept of yield and identify the parameters influencing the same
CO3: Able to identify the techniques to improve fabrication defects, errors & fault coverage.
CO4: Able to Implement combinational and
sequential circuit test generation algorithms.
CO5: Able to implement simulation based
verification.
Course Outcome (CO)
EC803B: Physical Design, Verification &
Testing
99
Department of Electronics and
Communication Engineering
CO1: Able to explain the fuzzy sets, fuzzy logic
systems and its various applications in real life problem solving.
CO2: Able to illustrate the concept of Artificial Neural Network and its applications
CO3: Able to discuss on the concept of Genetic
Algorithm and its various applications.
CO4: Able to elaborate the basics of Simulated Annealing, Tabu search, Ant colony optimization (ACO), Particle Swarm
Optimization (PSO).
Course Outcome (CO)
EC803C: Soft Computing
100
Department of Electronics and
Communication Engineering
CO1: Analyse and interpret data in communication
engineering using optical fibre communication technology.
CO2: Able to design the different multiplexing schemes in satellite communication scenario.
CO3: Able to Design the wireless & satellite
communication system using ISDN, GSM, GPRS and MPLS system.
CO4: Able to exhibit the professional knowledge and accept ethical responsibilities to solve the
problems of industry and society.
EC891: Advanced Communication
Laboratory
Course Outcome (CO)
101
Department of Electronics and
Communication Engineering
CO1: Able to get an opportunity to apply knowledge
of several courses in developing a new algorithm or circuit or a larger system.
CO2: Able to implement innovative ideas and publish them as a research paper or file a
patent.
CO3: Able to learn working as a team.
CO4: Able to understand, formulate and analyze the
problem resulting into a novel solution.
CO5: Able to gain practical knowledge about the topic including social, commercial,
manufacturing, testing, measurements, simulation, marketing and legal issues (as applicable).
Course Outcome (CO)
EC881: Project II
102
Department of Electronics and
Communication Engineering
CO1: Able to evaluate overall technical knowledge
and industry readiness.
CO2: Able to go under a virtual environment of technical interview.
CO3: Able to analyze various application of Electronics & Communication Engineering in
real life problem solving.
Course Outcome (CO)
EC882: Grand Viva
103
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