ELECTRONICS AND COMMUNICATION ENGINEERING

Over view

The Department of Electronics and Communication Engineering has been established in the year 1999 and it is offering UG program in Electronics and Communication Engineering with an intake of 60 from the academic year 2012-13. It is also offering PG program M.E Communication System in the academic year 2011-2012 and VLSI with an intake of 18 from the academic year 2012-2013.

Situation of students with inabilities in standard schools is the favored educational alternative in Tasmania. To the furthest reaches potential, students with handicaps ought to be taught in the organization of their age peers while likewise being furnished with educational program and backing to address their issues. Definitions Inclusive schooling is the result of endeavoring to accommodate all students, incorporating those with incapacities, in customary schools they have to check that writing resource to make their education easier, especially writing. Consideration suggests accommodating all students inside the educational program of the customary school. The accentuation is on how schools can change to address the issues of students with incapacities. Joining is the way toward bringing students with incapacities into customary schools from a setting wherein they have recently been barred. Reconciliation suggests that students that have been prohibited can be brought into a standard school. The accentuation is on how the student can fit into the current school structure.

Our Vision

  • To produce industry ready, research oriented and socially responsible Electronics and Communication Engineers.

Our Mission

  • To create an ambience for learning.

  • To conduct research, beneficial to the society.

  • To promote industry-academic interaction at all levels.

  • To be continuously agile to the needs of the stakeholders.

Program Educational Objectives (PEOs)

  • Graduates can

  • To provide the students with a strong foundation in the required sciences in order to pursue studies in Electronics and Communication Engineering.

  • To gain adequate knowledge to become good professional in electronic and communication engineering associated industries, higher education and research.

  • To develop attitude in lifelong learning, applying and adapting new ideas and technologies as their field evolves.

  • To prepare students to critically analyze existing literature in an area of specialization and ethically develop innovative and research oriented methodologies to solve the problems identified.

  • To inculcate in the students a professional and ethical attitude and an ability to visualize the engineering issues in a broader social context.

Program Outcomes (POs)

  • Engineering Knowledge: Apply the knowledge of mathematics, science,engineering fundamentals, and an engineering specialization to the solution of complex engineering problems.

  • 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.

  • 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

  • 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.

  • 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.

  • 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.

  • Ethics: Apply ethical principles and commit to professional ethics and responsibilities and norms of the engineering practice.

  • Individual and team work: Function effectively as an individual, and as a member or leader in diverse teams, and in multidisciplinary settings.

  • 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.

  • Project management and finance: Demonstrate knowledge and understanding of the engineering and management principles and apply these to ones own work, as a member and leader in a team, to manage projects and in multidisciplinary environments.

  • 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 Specific Outcomes (PSOs)

  • The Students will be able to

  • Design, develop and analyze electronic systems through application of relevant electronics, mathematics and engineering principles.

  • Design, develop and analyze communication systems through application of fundamentals from communication principles, signal processing, and RF System Design & Electromagnetics.

  • Adapt to emerging electronics and communication technologies and develop innovative solutions for existing and newer problems.

HS3152 PROFESSIONAL ENGLISH I

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: To use appropriate words in a professional context

  • CO2: To gain understanding of basic grammatical Structures and use them in right context.

  • CO3: To read and infer the denotative and connotative meanings of technical texts.

  • CO4: To write definitions, descriptions, narrations and essays on various topics.

MA3151 MATRICES AND CALCULUS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Use the matrix algebra methods for solving practical problems.

  • CO2: Apply differential calculus tools in solving various application problems.

  • CO3: Able to use differential calculus ideas on several variable functions.

  • CO4: Apply different methods of integration in solving practical problems.

  • CO5: Apply multiple integral ideas in solving areas,volumes and other practical problems

PH3151 ENGINEERING PHYSICS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Understand the importance of mechanics.

  • CO2: Express their knowledge in electromagnetic waves.

  • CO3: Demonstrate a strong foundational knowledge in oscillations, optics and lasers.

  • CO4: Understand the importance of quantum physics.

  • CO5: Comprehend and apply quantum mechanical principles Towards the formation of energy bands.

CY3151 ENGINEERING CHEMISTRY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: To infer the quality of water from quality parameter data and propose suitable treatment methodologies to treat water.

  • CO2: To identify and apply basic concepts of nanoscience and nanotechnology in designing the synthesis of nonmaterial’s for engineering and technology applications.

  • CO3: To apply the knowledge of phase rule and composites for material selection requirements.

  • CO4: To recommend suitable fuels for engineering processes and applications.

  • CO5: To recognize different forms of energy resources and apply them for suitable applications in energy sectors.

GE3151 PROBLEM SOLVING AND PYTHON PROGRAMMING

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Develop algorithmic solutions to simple computational problems.

  • CO2: Develop and execute simple Python programs.

  • CO3: Write simple Python programs using conditionals and loops for solving problems.

  • CO4: Decompose a Python program into functions.

  • CO5: Represent compound data using Python lists, tuples, dictionaries etc.

  • CO6: Represent compound data using Python lists, tuples, dictionaries etc.

GE3171 PROBLEM SOLVING AND PYTHON PROGRAMMING LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Develop algorithmic solutions to simple computational problems .

  • CO2: Develop and execute simple Python programs.

  • CO3: Write simple Python programs using conditionals and loops for solving problems.

  • CO4: Deploy functions to decompose a Python program.

  • CO5: Process compound data using Python data structures.

  • CO6: Utilize Python packages in developing software applications.

BS3171 PHYSICS AND CHEMISTRY LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Understand the functioning of various physics laboratory equipment.

  • CO2: Use graphical models to analyze laboratory data.

  • CO3: Use mathematical models as a medium for quantitative reasoning and describing physical reality.

  • CO4: Access, process and analyze scientific information.

  • CO5: Solve problems individually and collaboratively.

  • CO6: To analyse the quality of water samples with respect to their acidity, alkalinity, hardness and DO.

  • CO7: determine the amount of metal ions through volumetric and spectroscopic techniques

  • CO8: To analyse and determine the composition of alloys.

  • CO9: To learn simple method of synthesis of nanoparticles

  • CO10: To quantitatively analyse the impurities in solution by electroanalytical techniques.

GE3172 ENGLISH LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: To listen to and comprehend general as well as complex academic information.

  • CO2: To listen to and understand different points of view in a discussion .

  • CO3: speak fluently and accurately in formal and informal communicative contexts .

  • CO4: describe products and processes and explain their uses and purposes clearly and accurately .

  • CO5: To express their opinions effectively in both formal and informal discussions.

HS3252 PROFESSIONAL ENGLISH – II

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: To compare and contrast products and ideas in technical texts.

  • CO2: To identify and report cause and effects in events, industrial processes through technical texts.

  • CO3: To analyses problems in order to arrive at feasible solutions and communicate them in the written Format.

  • CO4: To present their ideas and opinions in a planned and logical manner

  • CO5: To draft effective resumes in the context of job search.

MA3251 STATISTICS AND NUMERICAL METHODS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Apply the concept of testing of hypothesis for small and large samples in real life problems.

  • CO2: Apply the basic concepts of classifications of design of experiments in the field of agriculture.

  • CO3: Appreciate the numerical techniques of interpolation in various intervals and apply the numerical techniques of differentiation and integration for engineering problems.

  • CO4: Understand the knowledge of various techniques and methods for solving first and second order ordinary differential equations.

  • CO5: Solve the partial and ordinary differential equations with initial and boundary conditions by using certain techniques with engineering applications.

PH3254 PHYSICS FOR ELECTRONICS ENGINEERS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: know basics of crystallography and its importance for varied materials properties .

  • CO2: gain knowledge on the electrical and magnetic properties of materials and their applications .

  • CO3: understand clearly of semiconductor physics and functioning of semiconductor devices .

  • CO4: understand the optical properties of materials and working principles of various optical devices .

  • CO5: appreciate the importance of nanotechnology and nanodevices.

BE3254 ELECTRICAL AND INSTRUMENTATION ENGINEERING

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Explain the working principle of electrical machines .

  • CO2: Analyze the output characterizes of electrical machines .

  • CO3: Choose the appropriate electrical machines for various applications .

  • CO4: Explain the types and operating principles of measuring instruments .

  • CO5: Explain the basic power system structure and protection schemes.

GE3251 ENGINEERING GRAPHICS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Use BIS conventions and specifications for engineering drawing.

  • CO2: Construct the conic curves, involutes and cycloid.

  • CO3: Solve practical problems involving projection of lines.

  • CO4: Draw the orthographic, isometric and perspective projections of simple solids.

  • CO5: Draw the development of simple solids.

EC3251 CIRCUIT ANALYSIS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Apply the basic concepts of circuit analysis such as Kirchoff’s laws, mesh current and node voltage method for analysis of DC and AC circuits.

  • CO2: Apply suitable network theorems and analyze AC and DC circuits .

  • CO3: Analyze steady state response of any R, L and C circuits .

  • CO4: Analyze the transient response for any RC, RL and RLC circuits and frequency response of parallel and series resonance circuits.

  • CO5: Analyze the coupled circuits and network topologies.

GE3271 ENGINEERING PRACTICES LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Draw pipe line plan; lay and connect various pipe fittings used in common household plumbing work; Saw; plan; make joints in wood materials used in common household wood work.

  • CO2: Wire various electrical joints in common household electrical wire work.

  • CO3: Weld various joints in steel plates using arc welding work; Machine various simple processes like turning, drilling, tapping in parts; Assemble simple mechanical assembly of common household equipments; Make a tray out of metal sheet using sheet metal work.

  • CO4: Solder and test simple electronic circuits; Assemble and test simple electronic components on PCB.

EC3271 CIRCUIT ANALYSIS LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Design RL and RC circuits.

  • CO2: Verify Thevinin & Norton theorem KVL & KCL, and Super Position Theorems.

GE3272 COMMUNICATION LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Speak effectively in group discussions held in formal/semi formal contexts.

  • CO2: Discuss, analyse and present concepts and problems from various perspectives to arrive at suitable solutions .

  • CO3: Write emails, letters and effective job applications.

  • CO4: Write critical reports to convey data and information with clarity and precision .

  • CO5: Give appropriate instructions and recommendations for safe execution of tasks.

MA3355 RANDOM PROCESSES AND LINEAR ALGEBRA

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Explain the fundamental concepts of advanced algebra and their role in modern mathematics and applied contexts.

  • CO2:Demonstrate accurate and efficient use of advanced algebraic techniques.

  • CO3: Apply the concept of random processes in engineering disciplines.

  • CO4: Understand the fundamental concepts of probability with a thorough knowledge of standard distributions that can describe certain real-life phenomenon.

  • CO5: Understand the basic concepts of one and two dimensional random variables and apply them to model engineering problems.

CS3353 C PROGRAMMING AND DATA STRUCTURES

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Develop C programs for any real world/technical application.

  • CO2: advanced features of C in solving problems.

  • CO3: Write functions to implement linear and non–linear data structure operations.

EC3354 SIGNALS AND SYSTEMS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: determine if a given system is linear/causal/stable.

  • CO2: determine the frequency components present in a deterministic signal .

  • CO3: characterize continuous LTI systems in the time domain and frequency domain .

  • CO4: characterize discrete LTI systems in the time domain and frequency domain .

  • CO5: compute the output of an LTI system in the time and frequency domains.

EC3353 ELECTRONIC DEVICES AND CIRCUITS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Explain the structure and working operation of basic electronic devices.

  • CO2: Design and analyze amplifiers.

  • CO3: Analyze frequency response of BJT and MOSFET amplifiers .

  • CO4: Design and analyze feedback amplifiers and oscillator principles.

  • CO5: Design and analyze power amplifiers and supply circuits.

EC3351 CONTROL SYSTEMS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Compute the transfer function of different physical systems.

  • CO2: Analyse the time domain specification and calculate the steady state error.

  • CO3: Illustrate the frequency response characteristics of open loop and closed loop system response.

  • CO4: Analyse the stability using Routh and root locus techniques.

  • CO5: Illustrate the state space model of a physical system and discuss the concepts of sampled data control system.

EC3352 DIGITAL SYSTEMS DESIGN

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Use Boolean algebra and simplification procedures relevant to digital logic.

  • CO2: Design various combinational digital circuits using logic gates.

  • CO3: Analyse and design synchronous sequential circuits.

  • CO4: Analyse and design asynchronous sequential circuits.

  • CO5: Build logic gates and use programmable devices.

EC3361 ELECTRONIC DEVICES AND CIRCUITS LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Characteristics of PN Junction Diode and Zener diode.

  • CO2: Design and Testing of BJT and MOSFET amplifiers.

  • CO3: Operation of power amplifiers.

CS3362 C PROGRAMMING AND DATA STRUCTURES LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Use different constructs of C and develop applications.

  • CO2: Write functions to implement linear and non-linear data structure operations .

  • CO3: Suggest and use the appropriate linear / non-linear data structure operations for a given problem .

  • CO4: Apply appropriate hash functions that result in a collision free scenario for data storage and Retrieval .

  • CO5: Implement Sorting and searching algorithms for a given application.

GE3361 PROFESSIONAL DEVELOPMENT

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Use MS Word to create quality documents, by structuring and organizing content for their day to day technical and academic requirements .

  • CO2: Use MS EXCEL to perform data operations and analytics, record, retrieve data as per requirements and visualize data for ease of understanding .

  • CO3: Use MS PowerPoint to create high quality academic presentations by including common tables, charts, graphs, interlinking other elements, and using media objects.

EC3452 ELECTROMAGNETIC FIELDS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: the fundamentals of vector, coordinate system to electromagnetic concepts .

  • CO2: Analyze the characteristics of Electrostatic field .

  • CO3: Interpret the concepts of Electric field in material space and solve the boundary conditions .

  • CO4: Explain the concepts and characteristics of Magneto Static field in material space and solve boundary conditions.

  • CO5: Determine the significance of time varying fields.

EC3401 NETWORKS AND SECURITY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Explain the Network Models, layers and functions.

  • CO2: Categorize and classify the routing protocols.

  • CO3: List the functions of the transport and application layer.

  • CO4: Evaluate and choose the network security mechanisms.

  • CO5: Discuss the hardware security attacks and countermeasures.

EC3451 LINEAR INTEGRATED CIRCUITS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Design linear and nonlinear applications of OP – AMPS.

  • CO2: Design applications using analog multiplier and PLL .

  • CO3: Design ADC and DAC using OP – AMPS.

  • CO4: Generate waveforms using OP – AMP Circuits .

  • CO5: Analyze special function ICs.

EC3492 DIGITAL SIGNAL PROCESSING

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Apply DFT for the analysis of digital signals and systems .

  • CO2: Design IIR and FIR filters.

  • CO3: Characterize the effects of finite precision representation on digital filters .

  • CO4: Design multirate filters .

  • CO5: Apply adaptive filters appropriately in communication systems .

EC3491 COMMUNICATION SYSTEMS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Gain knowledge in amplitude modulation techniques .

  • CO2: Understand the concepts of Random Process to the design of communication systems .

  • CO3: Gain knowledge in digital techniques.

  • CO4: Gain knowledge in sampling and quantization .

  • CO5: Understand the importance of demodulation techniques.

GE3451 ENVIRONMENTAL SCIENCES AND SUSTAINABILITY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: To recognize and understand the functions of environment, ecosystems and biodiversity and their conservation.

  • CO2: To identify the causes, effects of environmental pollution and natural disasters and contribute to the preventive measures in the society.

  • CO3: To identify and apply the understanding of renewable and non-renewable resources and contribute to the sustainable measures to preserve them for future generations.

  • CO4: To recognize the different goals of sustainable development and apply them for suitable technological advancement and societal development.

  • CO5: To demonstrate the knowledge of sustainability practices and identify green materials, energy cycles and the role of sustainable urbanization.

EC3461 COMMUNICATION SYSTEMS LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Design AM, FM & Digital Modulators for specific applications.

  • CO2: Compute the sampling frequency for digital modulation.

  • CO3: & validate the various functional modules of Communication system.

  • CO4: Demonstrate their knowledge in base band signaling schemes through implementation of digital modulation schemes.

  • CO5: Apply various channel coding schemes & demonstrate their capabilities towards the improvement of the noise performance of Communication system.

EC3462 LINEAR INTEGRATED CIRCUITS LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Analyze various types of feedback amplifiers .

  • CO2: Design oscillators, tuned amplifiers, wave-shaping circuits and multivibrators .

  • CO3: Design and simulate feedback amplifiers,oscillators, tuned amplifiers, wave- shaping circuits and multivibrators, filters using SPICE Tool.

  • CO4: Design amplifiers, oscillators, D-A converters using operational amplifiers.

  • CO5: Design filters using op-amp and perform an experiment on frequency response.

EC3501 WIRELESS COMMUNICATION

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Understand The Concept And Design Of A Cellular System.

  • CO2: Understand Mobile Radio Propagation And Various Digital Modulation Techniques.

  • CO3: Understand The Concepts Of Multiple Access Techniques And Wireless Networks.

  • CO4: Characterize a wireless channel and evolve the system design specifications.

  • CO5:Design a cellular system based on resource availability and traffic demands.

EC3461 COMMUNICATION SYSTEMS LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Design AM, FM & Digital Modulators for specific applications.

  • CO2: Compute the sampling frequency for digital modulation.

  • CO3: & validate the various functional modules of Communication system.

  • CO4: Demonstrate their knowledge in base band signaling schemes through implementation of digital modulation schemes.

  • CO5: Apply various channel coding schemes & demonstrate their capabilities towards the improvement of the noise performance of Communication system.

EC3552 VLSI AND CHIP DESIGN

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: In depth knowledge of MOS technology .

  • CO2: Understand Combinational Logic Circuits and Design Principles .

  • CO3: Understand Sequential Logic Circuits and Clocking Strategies .

  • CO4: Understand Memory architecture and building blocks .

  • CO5: Understand the ASIC Design Process and Testing.

EC3551 TRANSMISSION LINES AND RF SYSTEMS

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Explain the characteristics of transmission lines and its losses.

  • CO2: Calculate the standing wave ratio and input impedance in high frequency transmission lines.

  • CO3: Analyze impedance matching by stubs using Smith Charts.

  • CO4: Comprehend the characteristics of TE and TM waves.

  • CO5: Design a RF transceiver system for wireless communication.

EC3561 VLSI LABORATORY

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Write HDL code for basic as well as advanced digital integrated circuit .

  • CO2: Import the logic modules into FPGA Boards .

  • CO3: Synthesize Place and Route the digital Ips .

  • CO4: Design, Simulate and Extract the layouts of Digital & Analog IC Blocks using EDA tools .

  • CO5: Test and Verification of IC design.

ET3491 EMBEDDED SYSTEMS AND IOT DESIGN

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Explain the architecture and features of 8051.

  • CO2: Develop a model of an embedded system.

  • CO3: List the concepts of real time operating systems.

  • CO4: Learn the architecture and protocols of IoT.

  • CO5: Design an IoT based system for any application.

CS3491 ARTIFICIAL INTELLIGENCE AND MACHINE LEARNING

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Use appropriate search algorithms for problem solving.

  • CO2: Apply reasoning under uncertainty.

  • CO3: Build supervised learning models .

  • CO4: Build ensembling and unsupervised models .

  • CO5: Build deep learning neural network models.

EC3711 SUMMER INTERNSHIP

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: System-level design processes, verification and validation techniques, manufacturing and production processes in the firm or research facilities in the laboratory/research institute .

  • CO2: Analysis of industrial / research problems and their solutions .

  • CO3: Documentation of system specifications, design methodologies, process parameters, testing parameters and results .

  • CO4: Preparing of technical report and presentation.

EC3811 PROJECT WORK/ INTERNSHIP

  • COURSE OUTCOMES:

  • At the end of the course, learners will be able

  • CO1: Formulate and analyze problem / create a new product/ process.

  • CO2: Design and conduct experiments to find solution .

  • CO3: Analyze the results and provide solution for the identified problem, prepare project report and make presentation.