B.E. Third Semester

Course Name : Applied Mathematics-III
Code : BEETE301T
At the end of course Students will be able to –
CO1	Analyse Integral Transform techniques such as Laplace transform and apply Laplace Transform to solve Ordinary Differential Equations.
CO2	Apply Fourier Transform to Solve Integral Equation.
CO3	Calculate the maxima and minima value for functions of two variables.
CO4	Apply Complex variables to solve analytic functions, Taylor’s & Lauren’s series, Contour integration.
CO5	Analyse ordinary and partial differential equations applied To electronics & telecommunication engineering such as electronics & telecommunication vibrations and heat transfer.
CO6	Find the Eigen values and Eigen vectors to diagonalize and reduce a matrix to quadratic form.

Course Name : ELECTRONIC DEVICES AND CIRCUITS
Code : BEETE302T
At the end of course Students will be able to –
CO1	The students will get the basic concepts of different semiconductor components.
CO2	They will be able to understand the use of semiconductor devices in different electronic circuits.
CO3	They will be able to calculate different performance parameters of transistors.
CO4	They will be able to plot and study the characteristics of semiconductor devices.

Course Name : ELECTRONICS MEASUREMENT AND INSTRUMENTATION
Code : BEETE303T
At the end of course Students will be able to –
CO1	Explain basic concepts and definitions in measurement.
CO2	Explain the operation and design of electronic instruments for parameter measurement and operation of different Transducers
CO3	Explain the operation of oscilloscopes and the basic circuit blocks in the design of an oscilloscope.
CO4	Explain the circuitry and design of various function generators.

Course Name : OBJECT ORIENTED PROGRAMMING & DATA STRUCTURE
Code : BEETE304T
At the end of course Students will be able to –
CO1	Be able to implement the concept of object oriented programming in any programming language.
CO2	Explain the basic data structures and algorithms for manipulating them.
CO3	Implement these data structures and algorithms in the C++ language.
CO4	Integrate these data structures and algorithms in larger programs.
CO5	Code and test well-structured programs of moderate size using the C++ language.
CO6	Apply principles of good program design to the C++ language.

Course Name : NETWORK ANALYSIS AND SYNTHESIS
Code : BEETE305T
At the end of course Students will be able to –
CO1	Students will be able to analyze the various electrical and electronic networks using the techniques they learn.
CO2	Students will be able to construct a circuit to suit the need.

B.E. Forth Semester

Course Name : AppliedMathematics-IV
Code : BEETE401T
At the end of course Students will be able to –
CO1	Apply mathematical concepts and principles to perform computations using Numerical methods.
CO2	Solve ordinary differential equations.
CO3	Apply mathematics to solve problems on Z-Transform and Series.
CO4	Find Series solution of differential equation and generate functions of recurrence relations.
CO5	Develop problem-solving techniques needed to accurately calculate probabilities.
CO6	Apply problem-solving techniques to solving real-world events.

Course Name : POWER DEVICES AND MACHINES
Code : BEETE402T
At the end of course Students will be able to –
CO1	Understand the basics of different components used in Power Electronics.
CO2	Understand the working and characteristics of different power devices along with their applications in Electronic circuits.
CO3	Understand the concept of AC-DC converters, Choppers, Inverters which are widely used in industries.
CO4	Understand the different AC/DC machines and their speed control methods

Course Name : ELECTROMAGNETIC FIELDS
Code : BEETE403T
At the end of course Students will be able to –
CO1	Understand the concepts of Electric, Magnetic and Electromagnetic fields required to understand the concepts of Electronic Communication.
CO2	Understand the different coordinate system for mathematical analysis of Electromagnetic Engineering.
CO3	Understand the different theorems and their use in Electromagnetic field.
CO4	Understand the use of waveguides for the transmission of electromagnetic waves at higher frequencies..
CO5	Understand the basic concepts of Radiation and Elements used for radiation along with the basic terminologies.

Course Name : DIGITAL CIRCUITS AND FUNDAMENTAL OF MICROPROCESSOR
Code : BEETE404T
At the end of course Students will be able to –
CO1	At the end of the course the student will be able to analyze, design, and evaluate digital circuits of medium complexity, that are based on SSIs, MSIs, and programmable logic devices.

Course Name : SIGNALS AND SYSTEMS
Code : BEETE405T
At the end of course Students will be able to –
CO1	Get knowledge about different types of signals and systems used in communication Electronics
CO2	Understand the concept of probability and its use in communication system.
CO3	Be able to embed the use of fourier series and fourier transform for feature extraction of different electronic signals.
CO4	Understand different coding schemes and able to apply selective coding scheme for the application needed
CO5	Understand the different analog and digital modulation schemes

B.E. FifthSemester

Course Name : Industrial Economics and Entrepreneurship Development
Code : BEETET
At the end of course Students will be able to –
CO1	Understand and explain supply and demand analysis.
CO2	Define and explain concepts and laws related to production and solve problems of BEP and Depreciation.
CO3	Understand share market & some concepts of macroeconomics like inflation, deflation, stagflation and the types of market structure.
CO4	Understand concept of Creativity, Innovation, Invention, Discovery, Creativity and laws related to IPR and patent.
CO5	Know the Industries.	basics	of	entrepreneurship	and	Small	Scale
CO6	Explain the financial agencies and entrepreneurship support Government system & Agencies and Analyze the factors governing to project selection

Course Name : Antenna & Wave Propagation
Code : BEETE501T
At the end of course Students will be able to –
CO1	Describe transmission line characteristics.
CO2	calculate antenna parameters (radiation pattern, beam width, lobes, directivity, gain, impedance, efficiency, polarization)
CO3	Analyze wire antennas (monopoles, dipoles, and loops).
CO4	Analyze and design antenna arrays.
CO5	Describe the operation of broadband and traveling wave antennas.
CO6	Describe the operation of aperture and reflector antennas.
CO7	Analyze and design Microstrip antennas.

Course Name : MICROPROCESSOR AND MICROCONTROLLERS
Code : BEETE502T
At the end of course Students will be able to –
CO1	Describe internal organization of 8086/8088 microprocessors & 8051microcontrollers.
CO2	Describe the concept of addressing modes and timing diagram of Microprocessor.
CO3	Interface 8086 & 8051 with Keyboard/ Display, ADC/DAC, Stepper motor etc.
CO4	Demonstrate the concept of interrupts and its use.
CO5	Demonstrate the concept of Serial & parallel data communication
CO6	Describe Handshaking concept and interfacing with peripheral devices.
CO7	Describe the concept of DMA & Pentium.
CO8	Describe 8087 Numeric coprocessor & its use in practical application.
CO8	Interface various hardware with microprocessor

Course Name : ANALOG CIRCUIT AND DESIGN
Code : BEETE503T
At the end of course Students will be able to –
CO1	Describe the basic differential Amplifier using transistor and its operation & characteristic.
CO2	Design linear Op-Amp circuits such as Voltage follower, Summing amplifier, scaling and averaging amplifier, Instrumentation amplifier circuits for various practical applications.
CO3	Design non-linear Op-Amp such as Comparators, Comparator IC such as LM 339, Schmitt trigger, multivibrator circuits for various practical applications using IC555.
CO4	Analyze and design amplifier circuits, oscillators, Filter, regulated power supply

Course Name : COMMUNICATION ELECTRONIC
Code : BEETE504T
At the end of course Students will be able to –
CO1	Demonstrate a basic understanding of the term bandwidth and its application in communications.
CO2	Describe quantizing and PCM signals, bandwidth and bit rate calculations, study amplitude and angle modulation and demodulation of analog signals etc.
CO3	Solve the problems involving bandwidth calculation, representation & Generation of an AM sine wave
CO4	Compare different modulation techniques of Generation of FM (Direct & Indirect Method)
CO5	Identify, formulate & solve communication engineering problems.

B.E. Sixth Semester

Course Name : TELECOMMUNICATION SWITCHING SYSTEMS
Code : BEETE601T
At the end of course Students will be able to –
CO1	Describe the need for switching systems and their evolution from analogue to digital.
CO2	Describe the Public Switched Telephone Network.
CO3	Describe private networks.
CO4	Describe integrated networks.

Course Name : DIGITAL SIGNAL PROCESSING
Code : BEETE602T
At the end of course Students will be able to –
CO1	Represent discrete-time signals analytically and visualize them in the time domain.
CO2	Meet the requirement of theoretical and practical aspects of DSP with regard to sampling and reconstruction.
CO3	Design and implement digital filter for various applications.
CO4	Describe the various transforms for analysis of signals and systems.
CO5	Describe the concept of multi rate signal processing and how to apply it for the wavelet transform.

Course Name : CONTROL SYSTEM ENGINEERING
Code : BEETE603T
At the end of course Students will be able to –
CO1	Analyze various control systems.
CO2	Analyze various control systems.
CO3	Determine the response of different order systems for various step inputs.
CO4	Analyze the stability of the system using Root locus. Bode plot, Nyquist plot.
CO5	Obtain transfer function of systems using signal flow graph.
CO6	Apply the state variable approach in design.

Course Name : DIGITAL COMMUNICATION
Code : BEETE604T
At the end of course Students will be able to –
CO1	Explain the working principles of basic building blocks of a digital communication system.
CO2	Describe a random process in terms of its mean and correlation functions and characterize special Gaussian and Rayleigh distributions.
CO3	Explain receiver techniques for detection of a signal in AWGN channel
CO4	Describe digital modulation techniques.
CO5	Demonstrate the concept of coding and decoding techniques.
CO6	Model digital communication systems using appropriate mathematical techniques.
CO7	Describe spread spectrum analysis.

B.E. Seventh Semester

Course Name : DSP PROCESSOR & ARCHITECTURE
Code : BEETE701T
At the end of course Students will be able to –
CO1	To describe the detailed architecture, addressing mode, instruction sets of TMS320C5X
CO2	To write program of DSP processor
CO3	To design & implement DSP algorithm using code composer studio
CO4	To design decimation filter and interpolation filter.

Course Name : TELEVISION AND VIDEO ENGINEERING
Code : BEETE702T
At the end of course Students will be able to –
CO1	Analyze and understand colour T.V. System
CO2	Understand fundamental techniques of Different T.V. standards.
CO3	Understand Advanced T.V. Technology.
CO4	Understand different video recording, display and its consumer application.

Course Name : OPTICAL COMMUNICATION
Code : BEETE703T
At the end of course Students will be able to –
CO1	Learn the basic elements of optical fiber.
CO2	Understand the different kinds of losses, signal distortion in optical wave guides & other signal degradation factors
CO3	Classify various optical source materials, LED structures, LASER diodes.
CO4	Learn the fiber optic receivers such as PIN, APD diodes, receiver operation & performance.
CO5	Understand the operational principal of WDM, SONET, measurement of attenuation, dispersion, refractive index profile in optical fibers.

Course Name : Advanced Digital System Design
Code : BEETE704T
At the end of course Students will be able to –
CO1	Design of combinational & sequential circuit
CO2	Develop skilled VLSI front end designers
CO3	Implementation of digital system
CO4	Experimentation on Hardware /Software co-design.

Course Name : VLSI SIGNAL PROCESSING (ELECTIVE 1 )
Code : BEETE705T
At the end of course Students will be able to –
CO1	Learn various methodologies to optimize power delay and area of VLSI design.
CO2	Build Real Time processing system.
CO3	Design of algorithm structure for DSP algorithms based on algorithm transformation.

B.E. Eighth Semester

Course Name : MICROWAVE & RADAR ENGINEERING
Code : BEETE801T
At the end of course Students will be able to –
CO1	Understand the use of active and passive microwave devices
CO2	Analyze Different UHF components with the help of scattering parameter
CO3	Understand micro strip lines MIC design
CO4	Understand the use of different Klystrons.
CO5	Analyze the different power distribution Tees.
CO6	Analyze Scattering Matrix of different UHF components
CO7	Do research with capabilities in the design, development and manufacture of radar systems used in a wide spectrum of applications.

Course Name : COMPUTER COMMUNICATION NETWORK
Code : BEETE802T
At the end of course Students will be able to –
CO1	Understand the requirement of theoretical & practical aspect of computer network.
CO2	Understand the network traffic in computer network.
CO3	Describe various protocols used in network.
CO4	Describe the concept of computer network security.
CO5	Understand the different wired &wireless LAN stds.& Routers.

Course Name : WIRELESS & MOBILE COMMUNICATION
Code : BEETE803T
At the end of course Students will be able to –
CO1	Design a model of cellular system communication and analyze their operation and performance
CO2	Explain Abrasive Jet Machining, Mechanics of AJM-process parameters & Compute Machining parameters.
CO3	Quantify the causes and effects of path loss and signal fading on received signal characteristics.
CO4	to construct and analyze the GSM system

Course Name : Elective 2- EMBEDDED SYSTEMS
Code :BEETE804T
At the end of course Students will be able to –
CO1	Design embedded based system .
CO2	Design embedded system based on RTOS and communication protocols.

Course Name : – Elective 3- SATELLITE COMMUNICATION
Code :BEETE805T
At the end of course Students will be able to –
CO1	Do research with capabilities in the design, development and manufacture of satellite communication systems used in a wide spectrum of applications.
CO2	Experience real world experience from household appliances to sophisticated satellite communication, from electronic ignition to neural networks and signal processing chips & to integrate academic discipline with project-based engineering applications, classroom learning theory
CO3	Able for Acquisition of technical competence in specialized areas of Satellite Communication engineering.
CO4	Able to identify, formulate and model problems and find Satellite Communication engineering solutions based on a system approach.