Lesson Plan. WEEK Theory Practical Lecture Day Topic(including assignment/test) Practical Day Topic

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1 Lesson Plan Name of the Faculty : Mr. Sandeep Kumar (Theory) Discipline : B.TECH (ECE ) Semester : 6 th semester Subject : VLSI Design Lesson plan Duration : 15 Weeks (from January, 2018 to April, 2018) Work Load( lecture/practical) Per Week(in hours): Lectures-04, Practical-00 WEEK Theory Practical Lecture Day Topic(including assignment/test) Practical Day Topic 1 st 1 st Introduction to VLSI 2 nd Basic Mos Transistor 3 rd Enhancement mode 4 th Depletion mode 2 nd 5 th Fabrication 6 th NMOS Fabrication 7 th PMOS Fabrication 8 th CMOS Fabrication 3 rd 9 th BiCMOS Fabrication 10 th NMOS transistor current equation 11 th Second order effects 12 th MOS Transistor Model 4 th 13 th Class test th Introduction to NMOS Inverter 15 th Introduction to CMOS Inverter 16 th Introduction to Gates 5 th 17 th Determination of pull up ratio 18 th Determination of pull down ratio 19 th Stick diagram 20 th Lamda based rules 6 th 21 st Super buffers 22 nd BiCMOS logic

2 23 rd Steering logic 24 th Introduction to Sub System Design 7 th 25 th Layout of Sub System Design 26 th Structured design of combinational circuits 27 th Dynamic CMOS 28 th Examples of Sub System Design 8 th 29 th Class Test th Clocking 31 st Introduction to Tally circuits 32 nd NAND-NAND Tally circuits 9 th 33 rd NOR-NOR Tally circuits 34 th AOI logic 35 th EXOR structure 36 th Multiplexer structures 10 th 37 th Barrel shifter 38 th Introduction to Design of Combinational Elements 39 th Introduction to Regular Array Logic 40 th NMOS PLA 11 th 41 st Programmable Logic Devices 42 nd Finite State Machine 43 rd PLA 44 th Introduction to FPGA 12 th 45 th Examples of Tally Circuits 46 th Introduction to VHDL Programming 47 th RTL Design 48 th Class test-3

3 13 th 49 th Combinational logic 50 th Data types 51 st Operators 52 nd Packages 14 th 53 rd Sequential circuit 54 th Sub-programs 55 th Test benches 56 th Examples: address 15 th 57 th VHDL programming counters 58 th VHDL programming flipflops 59 th FSM 60 th VHDL programming of Multiplexers / De-multiplexers

4 Lesson Plan Name of the Faculty : Mr. Sandeep (Theory and Practical) Discipline : B.TECH (ECE) Semester : 6 th semester Subject : Control System Engineering Lesson plan Duration : 15 Weeks (from January, 2018 to April, 2018) Work Load (Lecture/Practical) per week (in hours) : Lecture 04, Practical-01 WEEK Theory Practical Lecture Day Topic(including Practical Day Topic assignment/test) 1 st 1 st 2 nd System/Plant model Types of models 1 st To study speed Torque characteristics of 3 rd Illustrative examples of plants A.C. servo motor 4 th And their inputs and outputs 2 nd 5 th Controller servo mechanism 6 th Regulating system, 2 nd To study speed Torque characteristics of DC servo motor 7 th Linear timeinvariant (LTI) System 8 th Time-varying system 3 rd 9 th Causal system 3 rd To demonstrate simple motor driven closed loop DC position control system 10 th Closed loop control system 11 th Open loop control system 12 th Illustrative examples of open-loop control system 4 th 13 th Class Test-1 4 th To study and 14 th Feedback control systems Continuous time demonstrate simple closed loop speed

5 data control control system systems 15 th Sampled data control systems 16 th Effects of feedback on sensitivity (to parameter variations) 5 th 17 th Stability 5 th To study the 18 th External disturbance (noise) 19 th Overall gain 20 th Introductory remarks about non-linear control systems 6 th 21 st Concept of transfer function 22 nd Relationship between transfer function and impulse response 23 rd Order of a system 24 th Block diagram algebra 7 th 25 th Signal flow graphs : Mason s gain formula & its application 26 th Characteristic equation 27 th Derivation of transfer functions of electrical system 28 th Derivation of transfer functions of electromechanical lead, lag, leadlag compensators and to draw their magnitude and phase plots 6 th To study a stepper motor & to execute microprocessor or computerbased control of the same by changing number of steps, direction of rotation & speed 7 th To implement a PID controller for temperature control of a pilot plant

6 systems 8 th 29 th Class test -2 8 th To study 30 th Transfer functions of cascaded and non-loading cascaded elements behavior of 1 order,2 order type 0,type 1 system 31 st Introduction to state variable analysis 32 nd Introduction to state variable design 9 th 33 rd Typical test signals 34 th Time response of first order systems to various standard inputs 35 th Time response of 2nd order system to step input 36 th Relationship between location of roots of characteristics equation 10 th 37 th Time domain specifications of a general an underdamped 2nd order system 38 th Steady state error and error constants 39 th Dominant closed loop poles 40 th Concept of 9 th To study control action of light control device 10 th To study water level control using a industrial PLC

7 stability 11 th 41 st Pole zero configuration and stability 42 nd Necessary and sufficient conditions for stability 11 th To study motion control of a conveyor belt using a industrial PLC 43 rd Class Test-3 44 th Root locus concept 12 th 45 th Development of root locus for various systems 46 th Stability considerations 47 th Hurwitz stability criterion 48 th Routh stability criterion 13 th 49 th Relationship between frequency response and time-response for 2nd order system 50 th Polar, Nyquist and Bode plots 51 st Stability 52 nd Gain-margin and Phase Margin 14 th 53 rd Relative stability 54 th Frequency response specifications 55 th Necessity of compensation and compensation networks 56 th Application of lag and lead compensation 15 th 57 th Basic modes of feedback control,

8 proportional, integral and derivative controllers 58 th Synchros, AC and DC techogenerators 59 th Servomotors, stepper motors & their applications 60 th Magnetic amplifier

9 Lesson Plan Name of the Faculty : Mr. Pawan Kumar (Theory and Practical) Discipline : B.TECH (ECE) Semester : 6 th semester Subject : Digital System Design Lesson plan Duration : 15 Weeks (from January, 2018 to April, 2018) Work Load (Lecture/Practical) per week (in hours): Lectures -04, Practical 01 WEEK Theory Practical Lecture Day Topic(including assignment/test) Practical Day Topic 1 st 1 st Introduction to Computer-aided design tools for digital systems 1 st Design all gates using VHDL 2 nd Hardware description Languages; introduction to VHDL data objects 3 rd Data Classes 4 th data types 2 nd 5 th Operators 2 nd Write VHDL 6 th Overloading 7 th Types of delays 8 th Syntax of VHDL model programs for the following circuits, check the wave forms and the hardware generated a. half adder b. full adder 3 rd 9 th Entity 3 rd Write VHDL 10 th Architecture programs for the declaration following 11 th Introduction to circuits, check behavioral the wave forms 12 th Dataflow models and the hardware generated a. multiplexer

10 4 th 13 th Structural models 14 th Class test th Assignment statements 16 th Sequential statements 5 th 17 th Process statement 18 th Conditional Statements 19 th Case statement 20 th Array b. demultiplexer 4 th Write VHDL programs for the following circuits, check the wave forms and the hardware generated a. decoder b. encoder 5 th Write a VHDL program for a comparator and check the wave forms and the hardware generated 6 th 21 st loops 6 th Write a VHDL 22 nd Packages program for a 23 rd Libraries code converter and check the 24 th Concurrent wave forms and instantaneous the hardware generated 7 th 25 th 26 th Concurrent Statements Functions 7 th Write a VHDL program for a FLIP-FLOP and 27 th Resolution check the wave functions forms and the 28 th Example of hardware subprogram generated 8 th 29 th Procedures 8 th Write VHDL 30 th Generics 31 st Component Declaration 32 nd Structural layout programs for the following circuits, check the wave forms and the hardware generated a. register b. shift register

11 9 th 33 rd Class test-2 9 th Write VHDL 34 th VHDL code for programs for the Multiplexers following 35 th VHDL code for circuits, check Demultiplexers the wave forms 36 th VHDL code for and the Half adder and hardware Full adder generated for Asynchronous counter 10 th 37 th VHDL code for encoders 38 th VHDL code for decoders 39 th VHDL code for code converters 40 th VHDL code for BCD seven segment 11 th 41 st VHDL code for magnitude Comparators 42 nd Implementation of Boolean functions 43 rd VHDL Models and Simulation of Sequential Circuits 44 th VHDL code of sequential circuit using Block statement 12 th 45 th VHDL code for FLIP FLOP 46 th VHDL code for Shift Registers 47 th VHDL code for Asynchonous& synchronous Counters 48 th Class test-3 13 th 49 th Basic 10 th Write VHDL programs for the following circuits, check the wave forms and the hardware generated for Synchronous counter

12 components of a computer, specifications 50 th Architecture of a simple microcomputer system 51 st Implementation of a simple microcomputer system using VHDL 52 nd ROM 14 th 53 rd PLAS 54 th PALS 55 th Gal 56 th PEEL 15 th 57 th CPLD 58 th FPGA 59 th Design implementation using CPLDS 60 th Design implementation using FPGAS

13 Lesson Plan Name of the Faculty : Mr. Dinesh KumarYadav (Theory and Practical) Discipline : B.TECH (ECE) Semester : 6 th semester Subject : MICROWAVE AND RADAR ENGINEERING Lesson plan Duration : 15 Weeks (from January, 2018 to April, 2018) Work Load (Lecture/Practical) per week (in hours): Lectures -04, Practical 01 WEEK Theory Practical Lecture Day Topic(including assignment/test) Practical Day Topic 1 st 1 st Introduction to Radar. 2 nd Comparison with transmission lines 3 rd Propagation in TE 4 th Propagation in TM mode 2 nd 5 th rectangular wave guide 6 th TEM mode in rectangular wave guide 7 th Characteristic impedance 8 th Introduction to circular waveguides 3 rd 9 th Planar transmission lines 10 th Introduction to microwave components & tubes 11 th Directional couplers 12 th Tees 1 st Study of wave guide components 2 nd To measure frequency of microwave source and demonstrate relationship among guide dimensions, free space wave length and guide wavelength. 3 rd To measure VSWR of unknown load and determine its impedance using a smith chart

14 14 th Class test -1 Study of 15 th S -parameters characteristics of Gunn oscillator 4 th 13 th Hybrid ring 4 th 16 th Attenuators & Gunn diode as modulated source (PIN modulation) and determination of modulation depth 5 th 17 th Cavity resonators 5 th Study of 18 th Mixers 19 th Detector 20 th Matched Load insulation & coupling coefficient of a magic T & coupling coefficient and directivity of a directional coupler 6 th 21 st Phase shifter 6 th Measurement of 22 nd Wave meter attenuation of a 23 rd Ferrite devices: attenuator and Isolators isolation, 24 th Circulators insertion loss, cross coupling of an circulator 7 th 25 th Limitation of conventional tubes 7 th Study of waveguide horn and its radiation pattern and determination of the beam width 26 th Construction & operation of Klystron amplifier 27 th properties of Klystron amplifier 28 th Reflex Klystron 8 th 29 th Magnetron 8 th To study 30 th TWT 31 st BWO working of MIC Components like Power Divider, Ring resonator, Filters & Microwave

15 32 nd Crossed field amplifiers Amplifier 9 th 33 rd Class test-2 9 th To study 34 th Introduction to Measurement of microwave solid Guide state devices & wavelength, Free measurements Space 35 th Varactor diode wavelength. & 36 th Tunnel Concept diode of reduction of wavelength due to substrate material 10 th 37 th Schottky diode 10 th Measurement of SWR in a Microwave transmission line 38 th GUNN diode, 39 th IMPATT 40 th TRAPATT Diodes 11 th 41 st PIN diodes 42 nd MASER 43 rd Parametric amplifiers 44 th Power measurement using calorimeter 12 th 45 th bolometers measurement of SWR, frequency 46 th Wavelength and impedance 47 th Microwave bridges 48 th Class test-3 13 th 49 th RADAR (history of radar) 50 th Block Diagram and operation of radar 51 st Radar

16 Frequencies 52 nd Simple form of Radar Equation 14 th 53 rd Prediction of Range 54 th Factor affecting of radar 55 th Types of radar. 56 th Performance of radar 15 th 57 th Pulse Repetition frequency 58 th Range Ambiguities 59 th Numericals based on radar. 60 th Applications of Radar

17 Lesson Plan Name of Faculty : Mr. Pankaj Soni (Theory and Practical) Discipline : B.Tech(ECE) Semester : 6 th Semester Subject : Microcontroller & Embedded Systems Lesson Plan Duration : 15 Weeks (from January, 2018 to April, 2018) Work Load (Lecture/Practical) per week (in hours): Lectures -04, Practical 01 Week Theory Practical Lecture Day Topic ( including Assignment/ Topic) Practical Day Topic 1 st 1 st Introduction to microcontrollers 2 nd Microcontroller architecture 3 rd Microcontroller memory types 4 th Microcontrollers Features 1 st To study development tools/environment for ATMEL/PIC microcontroller program and Architecture. 2 nd 5 th 6 th Microcontrollers Features continued.. PIC microcontrollers 2 nd Write an ALP to generate square of 10Khz using Timer 7 th Addressing modes 0. 8 th Addressing modescontinued.. 3 rd 9 th CPU registers 3 rd Write an ALP to display a string on LCD. 10 th Instruction set 11 th Instruction setcontinued 12 th Assignment 1 on CPU Registers 4 th 13 th Microcontroller 8051 Architecture/ Introduction 14 th Microcontroller 8051 Pin diagram 15 th Class Test 1 16 th Microcontroller 8051 Internal 4 th Write an ALP to interface seven segment with 8051 and display 0-9 on it.

18 RAM and registers 5 th 17 th Interrupts 5 th Write an ALP to 18 th Microcontroller 8051 I/o ports interface DC Motor with th Addressing modes 20 th Addressing modes continued 6 th 21 st Memory Organization and External Addressing 22 nd Register Mode 23 rd Direct Mode 24 th Indirect Mode 6 th Write an ALP to transmit the data using P1 of th 25 th Immediate Mode 7 th Write an ALP to 26 th Indexed addressing modes interface 4x4 27 th Assignment 2 on Addressing Modes of 8051 keyboard with th Real Time Applications of Microcontroller 8 th 29 th Interfacing with LCD 8 th Write an ALP to 30 th Interfacing with DAC interface 31 st Class Test 2 temperature sensor 32 nd Interfacing with STEPPER MOTOR using th 33 rd Interfacing with KEYBOARD 9 th Write an ALP to 34 th Interfacing with SENSORS interface the lcd 35 th Interfacing with ACTUATORS 16x2 to P16f877A 36 th Interfacing with Memory 10 th 37 th Interfacing with ADC 10 th Write an ALP to 38 th Classification of Embedded Systems 39 th Software Embedded into System 40 th Tools used for ALP 11 th 41 st KIEL Software Generate square wave P16f877A

19 42 nd Proteus Software 43 rd Assignment 3 on Classification of Embedded Systems 44 th Applications and Products of Embedded Systems 12 th 45 th Application in Telecom / Smart Cards 46 th Missiles and Satellites 47 th Application in Computer Networking 48 th Class Test 3 13 th 49 th Application in Digital Consumer Electronics, and Automotive 50 th Structure of Processor 51 st Memory data register 52 nd Memory address register 14 th 53 rd Bus Interface Unit Program Counter or Instruction Pointer 54 th Stack Pointer Registers 55 th Assignment 4 on Memory Registers 56 th Case Study of an Embedded System for a Smart Card 15 th 57 th Smart Card System Requirements 58 th Classes and class diagram Hardware Architecture 59 th Software Architecture 60 th Smart OS RTOS used as alternative to MUCOS

20 Lesson Plan Name of Faculty : Mr. Sarjender Yadav (Theory) Discipline : B.Tech(ECE) Semester : 6 th Semester Subject : Computer Networks Lesson Plan Duration : 15 Weeks (from January, 2018 to April, 2018) Work Load (Lecture/Practical) per week (in hours): Lectures -04, Practical 00 Week Theory Practical Lecture Day Topic ( including Assignment/ Topic) Practical Day Topic 1 st 1 st Introduction to Computer Networks 2 nd Example networks ARPANET 3 rd Internet, Private Networks 4 th Network Topologies: Bus-, Star-, Ring 2 nd 5 th Ring-, Hybrid -, Tree 6 th Complete -, Irregular Topology 7 th Types of Networks : Local Area Network 8 th Metropolitan Area Networks 3 rd 9 th Wide Area Networks 10 th Layering architecture of networks, OSI model 11 th Functions of each layer 12 th Services and Protocols of each layer 4 th 13 th Introduction, History of TCP/IP 14 th Layers of TCP/IP, Protocols 15 th Internet Protocol, Transmission Control Protocol 16 th User Datagram Protocol, IP Addressing 5 th 17 th IP address classes 18 th Subnet Addressing

21 19 th Internet Control Protocols, 20 th ARP, RARP 6 th 21 st ICMP, Application 22 nd Domain Name System, SMTP 23 rd POP,IMAP; FTP 24 th NNTP, HTTP 7 th 25 th Overview of IP version 6 26 th Introduction to LANs 27 th Features of LANs 28 th Components of LANs 8 th 29 th LAN Standards 30 th Usage of LANs 31 st IEEE 802 standards 32 nd Channel Access Methods 9 th 33 rd Aloha 34 th CSMA, CSMA/CD 35 th Token Passing, Ethernet 36 th Layer 2 & 3 switching 10 th 37 th Fast Ethernet 38 th Gigabit Ethernet 39 th Token Ring 40 th Hubs, Switches, Bridges 11 th 41 st Routers, Gateways 42 nd Introduction of WANs 43 rd Routing, Congestion Control 44 th WAN Technologies 12 th 45 th Distributed Queue Dual Bus (DQDB) 46 th Synchronous Digital Hierarchy (SDH) 47 th Synchronous Optical Network (SONET) 48 th Asynchronous Transfer Mode (ATM) 13 th 49 th Frame Relay., 50 th Wireless Links. 51 st Remote Monitoring Techniques: Polling 52 nd Traps 14 th 53 rd Performance Management

22 54 th Class of Service 55 th Quality of Service 56 th Security management, Firewalls 15 th 57 th VLANs, Proxy Servers 58 th Introduction to Network Operating System 59 th Client-Server infrastructure 60 th Windows NT/2000

YEAR (ELECTRONICS & COMMUNICATION ENGINEERING) SEMESTER - VI

M.D UNIVERSITY,ROHTAK SCHEME OF STUDIES AND EXAMINATION B.Tech. III YEAR (ELECTRONICS & COMMUNICATION ENGINEERING) SEMESTER - VI Modified F Scheme effective from 2011-12 Course No. Course Title Teaching