lesson plan_1

MITS-D/ECE-SDE-07

LESSON PLAN

SUBJECT: OPTICAL COMMUNICATION ECE IV Year I SemesterNAME OF THE FACULTY: S.NANDA KISHOR

S.No Week No

TOPICS TO BE COVERED Plannedhours

Actualhours

1. 1. Overview of optical fiber communication - Historical development, The general system, advantages of optical fiber communications. Optical fiber wave guides- Introduction, Ray theory transmission

5

2. 2. Total Internal Reflection, Acceptance angle, Numerical Aperture, Skew rays. Cylindrical fibers- Modes, Vnumber, Mode coupling, Step Index fibers, Graded Index fibers.

5

3. 3. Single mode fibers- Cut off wavelength, Mode Field Diameter, Effective Refractive Index. [2]. Fiber materials — Glass, Halide, Active glass, Chalgenide glass, Plastic optical fibers

5

4. 4. Signal distortion in optical fibers- Attenuation, Absorption, Scattering and Bending losses, Core and Cladding losses

5

5. 5. Information capacity determination, Group delay, Types of Dispersion - Material dispersion, Wave-guide dispersion, Polarization mode dispersion

5

6. 6. Intermodal dispersion. Pulse broadening. Optical fiber Connectors- Connector types, Single mode fiber connectors, Connector return loss.

5

7. 7. Fiber Splicing- Splicing techniques, Splicing single mode fibers. Fiber alignment and joint loss- Multimode fiber joints, single mode fiber joints,. Optical sources- LEDs, Structures, Materials, Quantum efficiency, Power

5

8. 8. Modulation, Power bandwidth product. Injection Laser Diodes- Modes, Threshold conditions, External quantum efficiency,Laser diode rate equations,Resonant frequencies. Reliability of LED&ILD.

5

9. 9. Source to fiber power launching - Output patterns, Power coupling, Power launching, Equilibrium Numerical Aperture, Laser diode to fiber coupling.

5

10. 10. Optical detectors- Physical principles of PIN and APD, Detector response time, Temperature effect on Avalanche gain 5

11. 11. Comparision of Photodetectors. Optical receiver operation- Fundamental receiver operation, Digital signal transmission, error sources

4

12. 12. Receiver configuration, Digital receiver performance, Probability of error, Quantum limit, Analog receivers.

4

13. 13.

Optical system design — Considerations, Component choice, Multiplexing. Point-to- point links, System considerations, Link power budget with examples

4

14. 14. . Overall fiber dispersion in Multi mode and Single mode fibers, Rise time budget with examples.

4

MITS-D/ECE-SDE-07

15. 15. Transmission distance, Line coding in Optical links, WDM, Necessity

4

16. 16. Principles, Types of WDM, Measurement of Attenuation and Dispersion, Eye pattern. 4

17. 17. REVISION 2 TOTAL HOURS 76

SIGNATURE OF THE FACULTY SIGNATURE OF THE HOD

MITS-D/ECE-SDE-07

LESSON PLAN

SUBJECT: ANTENNAS AND WAVE PROPAGATION ECE III Year I SemesterNAME OF THE FACULTY: R.M.SULTHANI

S.No Week No


Actualhours

1. 1. ANTENNA FUNDAMENTALS : Introduction, Radiation Mechanism – single wire, 2 wire, dipoles, Current Distribution on a thin wire antenna . Antenna Parameters] - Radiation Patterns, Patterns in Principal Planes

2. 2. Main Lobe and Side Lobes, Beamwidths, Beam Area, Radiation Intensity, Beam Efficiency, Directivty, Gain and Resolution, Antenna Apertures, Aperture Efficiency, Effective Hight. Related Problems

3. 3. Thin Linear Wire Antennas: Retarded Potentials, Radiation from Small Electric Dipole, Quarterwave Monopole and Halfwave Dipole – Current Distributions, Evaluation of Field Components, Power Radiated, Radiation Resistance, Beamwidths, Directivity

4. 4. Effective Area and Effective Hight. Natural current distributions, fields and patterns of Thin Linear Center-fed Antennas of different lengths, Radiation Resistance at a point which is not current maximum. Antenna Theorems – Applicability and Proofs for equivalence of directional characteristics

5. 5. Loop Antennas : Small Loops - Field Components, Comparison of far fields of small loop and short dipole, Concept of short magnetic dipole, D and Rr relations for small loops.

6. 6. ANTENNA ARRAYS : 2 element arrays – different cases, Principle of Pattern Multiplication, N element Uniform Linear Arrays – Broadside, Endfire Arrays, EFA with Increased Directivity, Derivation of their characteristics and comparison; Concept of Scanning Arrays

7. 7. Directivity Relations (no derivations). Related Problems. Binomial Arrays, Effects of Uniform and Non-uniform Amplitude Distributions, Design Relations

8. 8. NON-RESONANT RADIATORS : Introduction, Travelling wave radiators – basic concepts, Longwire antennas – field strength calculations and patterns, V-antennas, Rhombic Antennas and Design Relations

9. 9. Broadband Antennas: Helical Antennas – Significance, Geometry, basic properties; Design considerations for monofilar helical antennas in Axial Mode and Normal Modes (Qualitative Treatment).

10. 10. VHF, UHF AND MICROWAVE ANTENNAS - I : Arrays with Parasitic Elements, Yagi - Uda Arrays, Folded Dipoles & their characteristics. Reflector Antennas : Flat Sheet and Corner Reflectors

11. 11. Paraboloidal Reflectors – Geometry, characteristics,types of feeds,

MITS-D/ECE-SDE-07

F/D Ratio, Spill Over, Back Lobes, Aperture Blocking, Off-set Feeds, Cassegrainian Feeds].

12. 12. Horn Antennas – Types, Optimum Horns, Design Characteristics of Pyramidal Horns; Lens Antennas – Geometry, Features, Dielectric Lenses and Zoning

13. 13. Applications. Antenna Measurements – Patterns Required, Set Up, Distance Criterion, Directivity and Gain Measurements (Comparison, Absolute and 3-Antenna Methods).

14. 14. WAVE PROPAGATION - I: Concepts of Propagation – frequency ranges and types of propagations. Ground Wave Propagation–Characteristics, Parameters, Wave Tilt, Flat and Spherical Earth Considerations. Sky Wave Propagation – Formation of Ionospheric Layers and their Characteristics

15. 15. Mechanism of Reflection and Refraction, Critical Frequency, MUF & Skip Distance – Calculations for flat and spherical earth cases, Optimum Frequency, LUHF, Virtual Height, Ionospheric Abnormalities, Ionospheric Absorption

16. 16. WAVE PROPAGATION – II: Fundamental Equation for Free-Space Propagation, Basic Transmission Loss Calculations. Space Wave Propagation – Mechanism, LOS and Radio Horizon. Tropospheric Wave Propagation

17. 17. Radius of Curvature of path, Effective Earth’s Radius, Effect of Earth’s Curvature, Field Strength Calculations, M-curves and Duct Propagation, Tropospheric Scattering.

TOTAL HOURS


LESSON PLAN

MITS-D/ECE-SDE-07

SUBJECT: COMPUTER NETWORKS ECE IV Year I SemesterNAME OF THE FACULTY: M.B. MANJUNATHA

S.No Week No


Actualhours

1. 1. Introduction : OSI, TCP/IP and other networks models, Examples of Networks: Novell Networks

5

2. 2. Arpanet, Internet, Network Topologies WAN, LAN, MAN 4

3. 3. Physical Layer : Transmission media copper, twisted pair wireless

4

4. 4. switching and encoding asynchronous communications; Narrow band, broad band ISDN and ATM.

5

5. 5. Data link layer : Design issues, framing, error detection and correction, CRC

4

6. 6. Elementary Protocol-stop and wait, Sliding Window, Slip, Data link layer in HDLC, Internet, ATM.

4

7. 7. ALOHA, MAC addresses, Carrier sense multiple access 48. 8. IEEE 802.X Standard Ethernet, wireless LANS. Bridges, 59. 9. Network Layer : Virtual circuit and Datagram subnets-

Routing algorithm shortest path routing, Flooding4

10. 10. Hierarchical routing, Broad cast, Multi cast, distance vector routing 5

11. 11. Dynamic routing – Broadcast routing. Rotary for mobility. Congestion, Control Algorithms

4

12. 12. General Principles – of Congestion prevension policies. Internet working: The Network layer in the internet and in the

4

13. 13. Transport Layer: Transport Services, Connection management,

4

14. 14. , TCP and UDP protocols; ATM AAL Layer Protocol. 415. 15. , TCP and UDP protocols; ATM AAL Layer Protocol. 416. 16. Electronic Mail; the World WEB, Multi Media. 417. 17. REVISION 2

TOTAL HOURS 70


LESSON PLAN

MITS-D/ECE-SDE-07

SUBJECT: TELEVISION EGINEERING ECE IV Year I SemesterNAME OF THE FACULTY: Ms.HEMANTHA LAKSHMI

S.No Week No


Actualhours

1. 1. TV transmitter and receivers, synchronization. Television Pictures: Geometric form and aspect ratio, image continuity, interlaced scanning, picture resolution,

4

2. 2. Composite video signal: Horizontal and vertical sync, scanning sequence. Colour signal generation and Encoding: Perception of brightness and colours, additive colour mixing,

4

3. 3. video signals for colours, luminance signal, colour difference signals, encoding of colour difference signals, formation of chrominance signals, PAL encoder.

5

4. 4. Picture signal transmission, positive and negative modulation, VSB transmission, sound signal transmission

4

5. 5. standard channel BW, TV transmitter, TV signal propagation, interference, TV broadcast channels, TV transmission Antennas.

4

6. 6. Camera tube types, Vidicon, Silicon Diode Array Vidicon 47. 7. Monochrome TV camera, color camera. CCD Image Sensors. 38. 8. Monochromatic Picture tube, Electrostatic focussing, Beam

deflection, picture tube characteristics and specifications, colour picture tubes.

4

9. 9. TV Standards: American 525 line B&W TV system, NTSC colour system, 625-line monochrome system,b PAL colour system, TV standards.

4

10. 10. RF tuner, IF subsystem, video amplifier, sound section, sync separation and processing, deflection circuits, scanning circuits.

4

11. 11. PAL-D Colour Receiver: Electron tuners, IF subsystem, Y-signal channel, Chroma decoder, Separation of U & V Colour Phasors, synchronous demodulators, Subcarrier generation, raster circuits.

5

12. 12. AGC, noise cancellation, video and intercarrier sound signal detection, vision IF subsystem of Black and White receivers, Colour receiver IF subsystem

5

13. 13. .Receiver sound system: FM detection, FM Sound detectors, typical applications. TV Receiver Tuners: Tuner operation, VHF and UHF tuners, digital tuning techniques, remote control of receiver functions.

3

14. 14. : PAL – D decoder, chroma signal amplifiers, separation of U and V signals, Color burst separation, Burst phase discriminator

4

15. 15. ACC amplifier, Reference oscillator, Indent and colour killer circuits, RO phase shift and 180o PAL–SWITCH circuitry, U & V demodulators, Colour signal mixing.

4

16. 16. Synchronous separation, k noise in sync pulses, separation of frame and line sync pulses.

4

17. 17. AFC, single ended AFC circuit. Deflection Oscillators, deflection drive Ics. Receiver Antennas. DIGITAL TV Digital Satellite

3

MITS-D/ECE-SDE-07

TV, Direct to Home Satellite TV, Digital TV Receiver, Digital Terrestrial TV.

TOTAL HOURS 68


LESSON PLAN

MITS-D/ECE-SDE-07

SUBJECT: DIGITAL IMAGE PROCESSING ECE IV YEAR I SEMESTER NAME OF THE FACULTY: B.D. VENKATARAMANA REDDY

S.No Week No


Actualhours

1. 1. Digital image fundamentals - Digital Image through scanner, digital camera. Concept of gray levels. Gray level to binary image conversion

6

2. 2. Sampling and quantization. Relation ship between pixels. Imaging Geometry.

6

3. 3. Image Transforms 2-D FFT , Properties. Walsh transform, Hadamard Transform

5

4. 4. Discrete cosine Transform, Haar transform, Slant transform, Hotelling transform.

5

5. 5. Image enhancement Point processing 26. 6. Histogram processing. Spatial filtering 57. 7. Enhancement in frequency domain 28. 8. Image smoothing, Image sharpening 49. 9. Colour image processing : Psedo colour image processing 410. 10. full colour image processing 4

11. 11. Image Restoration Degradation model, Algebraic approach to restoration

4

12. 12. Inverse filtering, Least mean square filters, Constrained Least Squares Restoration, Interactive Restoration.

4

13. 13. Image segmentation Detection of discontinuities. Edge linking and boundary detection

5

14. 14. Thresholding, Region oriented segmentation. 415. 15. Image compression Redundancies and their removal methods,

Error free compression6

16. 16. Lossy compression Fidelity criteria, Image compression models, Source encoder and decoder.

6

17. 17. RIVISION 3TOTAL HOURS 75


LESSON PLAN

MITS-D/ECE-SDE-07

SUBJECT: LINEAR IC APPLICATIONS ECE III Year I Semester NAME OF THE FACULTY: k.kanthamma

S.No Week No


Actualhours

1. 1. INTEGRATED CIRCUITS : Differential Amplifier- DC and AC analysis of Dual input Balanced output Configuration

5

2. 2. Properties of other differential amplifier configuration (Dual Input Unbalanced Output, Single Ended Input – Balanced/ Unbalanced Output), DC Coupling and Cascade Differential Amplifier Stages, Level translator.

5

3. 3. CharacteristicsofOP-Amps,Integratedcircuits-Types,Classification, Package Types and temperature ranges, Power supplies, Op-amp Block Diagram ideal and practical Op-amp specifications, DC and AC characteristics, 741 op-amp & its features

5

4. 4. , FET input. Op-Amps,Op-Amp parameters & Measurement, Input & Out put Off set voltages & currents, slew rates, CMRR, PSRR, drift, Frequency Compensation technique.

5

5. 5. LINEAR APPLICATIONS OF OP- AMPS : Inverting and Non-inverting amplifier, Integrator and differentiator

5

6. 6. Difference amplifier, Instrumentation amplifier, AC amplifier, V to I, I to V converters, Buffers

5

7. 7. NON-LINEAR APPLICATIONS OF OP- AMPS : Non- Linear function generation, Comparators, Multivibrators

5

8. 8. Triangular and Square wave generators, Log and Anti log amplifiers, Precision rectifiers.

5

9. 9. OSCILLATORS AND WAVEFORM GENERAGTORS : Introduction, Butter worth filters – 1st order, 2nd order LPF

5

10. 10. HPF filters. Band pass, Band reject and all pass filters. Applications of VCO (566).

5

11. 11. TIMERS & PHASE LOCKED LOOPS : Introduction to 555 timer, functional diagram, Monostable and Astable operations and applications, Schmitt Trigger

5

12. 12. PLL - introduction, block schematic, principles and description of individual blocks, 565 PLL, Applications of PLL – frequency multiplication, frequency translation, AM, FM & FSK demodulators.

5

13. 13. D to A & A to D CONVERTERS : Introduction, basic DAC techniques, weighted resistor DAC, R-2R ladder DAC, inverted R-2R DAC, and IC 1408 DAC, Different types of ADCs

5

14. 14. parallel comparator type ADC, counter type ADC, successive approximation ADC and dual slope ADC. DAC and ADC Specifications, Specifications AD 574 (12 bit ADC).

5

15. 15. ANALOG MULTIPLIERS AND MODULATORS : Four Quadrant multiplier, balanced modulator

5

16. 16. IC 1496, Applications of analog switches and Multiplexers, Sample & Hold amplifiers.

5

17. 17. RIVISION 5TOTAL HOURS 85


LESSON PLAN

MITS-D/ECE-SDE-07

SUBJECT: RADAR SYSTEMS ECE IV Year I SemesterNAME OF THE FACULTY: V.ANAND

S.No Week No


Actualhours

1. 1. Introduction Nature of Radar, Maximum Unambiguous Range, Radar Waveforms, Simple form of Radar Equation, Radar Block Diagram and Operation.

4

2. 2. Radar Frequencies and Applications. Related Problems.Radar Equation: Prediction of Range Performance, Minimum Detectable Signal, Receiver Noise and SNR.

4

3. 3. Integration of Radar Pulses, Transmitter Power, Radar Cross Section of Targets (simple targets - sphere, cone-sphere), PRF and Range Ambiguities,

5

4. 4. System Losses (qualitative treatment). Related Problems.CW and Frequency Modulated Radar: Doppler Effect, CW Radar – Block Diagram,

4

5. 5. Isolation between Transmitter and Receiver, Non-zero IF Receiver. Receiver Bandwidth Requirements.

4

6. 6. Applications of CW radar, FM-CW Radar, Range and Doppler Measurement. Block Diagram and Characteristics (Approaching/ Receding Targets),

4

7. 7. FM-CW altimeter, Measurement Errors, Multiple Frequency CW Radar.

3

8. 8. MTI and Pulse Doppler Radar: Introduction, Principle, MTI Radar with - Power Amplifier Transmitter and Power Oscillator Transmitter, Delay Line Cancellers – Filter Characteristics,

5

9. 9. Blind Speeds, Double Cancellation, Staggered PRFs. Range Gated Doppler Filters. MTI Radar Parameters, Limitations to MTI Performance.

4

10. 10. Non-coherent MTI, MTI versus Pulse Doppler Radar.Tracking Radar: Tracking with Radar, Sequential Lobing, Conical Scan, and Monopulse.

4

11. 11. Tracking Radar – Amplitude Comparison Monopulse (one- and two- coordinates).Phase Comparison Monopulse.

5

12. 12. Target Reflection Characteristics and Angular Accuracy. Tracking in Range, Acquisition and Scanning Patterns. Comparison of Trackers.

5

13. 13. Detection of Radar Signals in Noise: Introduction, Matched Filter Receiver – Response Characteristics and Derivation, Correlation Function.

3

14. 14. Cross-correlation Receiver, Efficiency of Non-matched Filters, Matched Filter with Non-white Noise.

4

15. 15. Radar Receivers – Noise Figure and Noise Temperature. Displays – types. Duplexers – Branch type and Balanced type, Circulators as Duplexers.

4

16. 16. Introduction to Phased Array Antennas – Basic Concepts, Radiation Pattern, Beam Steering and Beam Width changes

5

MITS-D/ECE-SDE-07

17. 17. Series versus Parallel Feeds, Applications, Advantages and Limitations,& previous papers discussion

3

TOTAL HOURS70


LESSON PLAN

SUBJECT: COMPUTER ORGANIZATION ECE III YEAR I SEMESTER

MITS-D/ECE-SDE-07

NAME OF THE FACULTY: S.USHA

S.No Week No


Actualhours

1. 1. Computer Types, Functional units, Basic operational concepts, Bus structures, Software

4

2. 2. Performance, multiprocessors and multi computers.Data types, Complements, Data Representation. Fixed Point Representation

4

3. 3. Floating – Point Representation. Error Detection codes.Register Transfer language.

5

4. 4. Register Transfer, Bus and memory transfer, Arithmetic Mircro operatiaons, logic micro operations,

4

5. 5. shift micro operations, Arithmetic logic shift unit Instruction codes. Computer Registers Computer instructions – Instruction cycle. Memory – Reference Instructions.

5

6. 6. input – Output and Interrupt Stack organization. Instruction formats. Addressing modes. DATA Transfer and manipulation.

4

7. 7. Program control. Reduced Instruction set computerControl memory, Address sequencing, micro program example, Design of control unit

3

8. 8. Hard wired control. Micro programmed controlAddition and subtraction, multiplication Algorithms,

5

9. 9. Division Algorithms, Floating – point Arithmetic operations. Decimal Arithmetic unit, Decimal Arithmetic operations.

4

10. 10. Memory Hierarchy, Main memory, Auxiliary memory, Associative memory

4

11. 11. Cache memory, Virtual memory Memory management hardwarePeripheral Devices

5

12. 12. Input-Output Interface, Asynchronous data transfer Modes of Transfer Priority Interrupt

5

13. 13. Direct memory AccessInput –Output Processor (IOP), Serial communication;

3

14. 14. Parallel Processing, Pipelining Arithmetic Pipeline 415. 15. Instruction Pipeline RISC Pipeline Vector Processing,

Array Processors.4

16. 16. Characteristics of Multiprocessors Interconnection Structures, Interprocessor Arbitration.

4

17. 17. Interprocessor Communication and Synchronization, Cache Coherance.

3

TOTAL HOURS70


LESSON PLAN

SUBJECT: DIGITAL COMMUNICATIONS ECE III Year II SemesterNAME OF THE FACULTY: S.SAYARA BANU

MITS-D/ECE-SDE-07

S.No Week No


Actualhours

1. 1. UNIT IPULSE DIGITAL MODULATION : Elements of digital communication systems, advantages of digital communication systems

3

2. 2. Elements of PCM: Sampling, Quantization & Coding, Quantization error, Compading in PCM systems. Differential PCM systems (DPCM).

5

3. 3. UNIT IIDELTA MODULATION : Delta modulation, its draw backs, adaptive delta modulation,

4

4. 4. comparison of PCM and DM systems, noise in PCM and DM systems

3

5. 5. UNIT IIIDIGITAL MODULATION TECHNIQUES : Introduction, ASK, FSK, PSK, DPSK

3

6. 6. DEPSK, QPSK, M-ary PSK, ASK, FSK, similarity of BFSK and BPSK

3

7. 7. UNIT IVDATA TRANSMISSION : Base band signal receiver, probability of error, the optimum filter, matched filter, probability of error using matched filter

5

8. 8. coherent reception, non-coherent detection of FSK, calculation of error probability of ASK, BPSK, BFSK,QPSK

5

9. 9. UNIT VINFORMATION THEORY : Discrete messages, concept of amount of information and its properties,

4

10. 10. Average information, Entropy and its properties. Information rate, Mutual information and its properties

4

11. 11. UNIT VISOURCE CODING : Introductions, Advantages, Shannon’s theorem, Shanon-Fano coding, Huffman coding, efficiency calculations

4

12. 12. channel capacity of discrete and analog Channels, capacity of a Gaussian channel, bandwidth –S/N trade off

4

13. 13. UNIT VIILINEAR BLOCK CODES : Introduction, Matrix description of Linear Block codes, Error detection and error correction capabilities of Linear block codes

5

14. 14. Hamming codes, Binary cyclic codes, Algebraic structure, encoding, syndrome calculation, BCH Codes

5

15. 15. UNIT VIIICONVOLUTION CODES : Introduction, encoding of convolution codes, time domain approach, transform domain approach.

4

MITS-D/ECE-SDE-07

16. 16. Graphical approach state, tree and trellis diagram decoding using Viterbi algorithm

4

17. 17. RIVISION 3

TOTAL HOURS66


LESSON PLAN

SUBJECT: ELECTRONIC CIRCUIT ANALYSIS ECE II Year II SemesterNAME OF THE FACULTY: P.R.RATNA RAJU.K

MITS-D/ECE-SDE-07

S.No Week No


Actualhours

1. 1. SINGLE STAGE AMPLIFIERS: classification of amplifiers, Distortion in amplifiers, Analysis of CE CC, and CB amplifiers with Hybrid model.

5

2. 2. Analysis of CE amplifier with emitter resistance and emitter follower, Design of single stage RC coupled amplifier using BJT.

5

3. 3. MULTI STAGE AMPLIFIERS :Analysis of cascaded RC coupled BJT amplifiers, cascaded amplifiers

5

4. 4. Darlington pair, different coupled schemes, RC coupled amplifier, direct and transformer coupled amplifier.

5

5. 5. BJT FREQUENCY RESPONSE: Logarithms, Decibels’, general frequency response of BJT amplifier, Analysis at low and high frequencies, Effect of coupling and bypass capacitors.

4

6. 6. The Hybrid-pi CE transistor model, CE short circuit current gain, current gain with resistive load, single stage CE transistor amplifier response Gain –Bandwidth product, emitter follower at higher frequencies.

6

7. 7. MOSFET AMPLIFIERS: Basic concepts, MOSFET small signal model, CS amplifier with resistive load

5

8. 8. Diode connected load and current source load, source follower, common gate stage, cascaded and folded cascaded amplifier and their frequency Response.

6

9. 9. FEEDBACK AMPLIFIERS: Classification of amplifiers, concepts of feedback, classification of feedback amplifiers, general characteristics of negative feedback amplifiers.

5

10. 10. Effect of feedback on amplifier characteristics, voltage-series, voltage –shunt, current series and current shunt feedback configurations, illustrative problems.

5

11. 11. OSCILLATORS: conditions for oscillations, RC and LC type oscillators, Frequency and amplitude stability of oscillators.

4

12. 12. Generalized analysis of LC oscillators, quartz, Hartley and colpitts oscillators, RC-phase shift and Wien-bridge oscillators.

5

13. 13. LARGE SIGNAL AMPLIFIERS: Class A power amplifier, maximum efficiency of class-A amplifier, transformer coupled amplifier, transformer coupled audio amplifier

5

14. 14. Push pull amplifier complementary symmetry class-B power amplifier phase inverters, transistor power dissipation.

4

15. 15. TUNED AMPLIFIERS: Introduction, Q-factor , small signal tuned amplifiers, effect of cascading single tuned amplifiers on B.W

5

16. 16. Effect of cascading, double tuned amplifiers, stager tuned amplifiers, stability of stager tuned amplifiers

4

17. 17. Revision 3TOTAL HOURS 81

MITS-D/ECE-SDE-07


LESSON PLAN

SUBJECT: SIGNALS AND SYSTEMS ECE II Year I SemesterNAME OF THE FACULTY: B.SUKUMAR

S.No Week No


Actualhours

1. 1. Analogy between vectors and signals, Orthogonal signal space, Signal approximation using orthogonal functions, Mean square error.

4

MITS-D/ECE-SDE-07

2. 2. Closed or complete set of orthogonal functions, Orthogonality in complex functions, Exponential and sinusoidal signals, Concepts of Impulse function, Unit step function, Signum function.

4

3. 3. FOURIER SERIES REPRESENTATION OF PERIODIC SIGNALS : Representation of Fourier series, Continuous time periodic signals

5

4. 4. properties of Fourier series, Dirichlet’s conditions, Trigonometric Fourier series and Exponential Fourier series, Complex Fourier spectrum

4

5. 5. FOURIER TRANSFORMS : Deriving Fourier transform from Fourier series, Fourier transform of arbitrary signal, Fourier transform of standard signals, Fourier transform of periodic signals

4

6. 6. properties of Fourier transforms, Fourier transforms involving impulse function and Signum function. Introduction to Hilbert Transform.

4

7. 7. SIGNAL TRANSMISSION THROUGH LINEAR SYSTEMS : Linear system, impulse response, Response of a linear system, Linear time invariant (LTI) system, Linear time variant (LTV) system, Transfer function of a LTI system

3

8. 8. Filter characteristics of linear systems. Distortion less transmission through a system, Signal bandwidth, system bandwidth, Ideal LPF, HPF and BPF characteristics, Causality and Poly-Wiener criterion for physical realization, relationship between bandwidth and rise time

5

9. 9. CONVOLUTION AND CORRELATION OF SIGNALS : Concept of convolution in time domain and frequency domain, Graphical representation of convolution, Convolution property of Fourier transforms

4

10. 10. Cross correlation and auto correlation of functions, properties of correlation function, Energy density spectrum, Parseval’s theorem, Power density spectrum, Relation between auto correlation function and energy/power spectral density function

4

11. 11. Relation between convolution and correlation, Detection of periodic signals in the presence of noise by correlation, Extraction of signal from noise by filtering

5

12. 12. SAMPLING : Sampling theorem – Graphical and analytical proof for Band Limited Signals, impulse sampling, Natural and Flat top Sampling, Reconstruction of signal from its samples, effect of under sampling – Aliasing, Introduction to Band Pass sampling.

5

13. 13. LAPLACE TRANSFORMS :Review of Laplace transforms, Partial fraction expansion, Inverse Laplace transform, Concept of region of convergence (ROC) for Laplace transforms, constraints on ROC for various classes of signals

3

14. 14. Properties of L.T’s relation between L.T’s, and F.T. of a signal. Laplace transform of certain signals using waveform synthesis

4

15. 15. Z–TRANSFORMS : Fundamental difference between continuous and discrete time signals, discrete time signal representation using complex exponential and sinusoidal components

4

16. 16. Periodicity of discrete time usingcomplex exponential signal, Concept of Z- Transform of a discrete sequence. Distinction between Laplace, Fourier and Z transforms. Region of convergence in Z-Transform

5

17. 17. constraints on ROC for various classes of signals, Inverse Z-transform, 3

MITS-D/ECE-SDE-07

properties of Z-transforms.TOTAL HOURS 70


LESSON PLAN

SUBJECT: PROBABILITY THEORY AND STOCHASTIC PROCESSES ECE II Year I SemesterNAME OF THE FACULTY: T. VENKATA RAMANA

S.No Week No


Actualhours

1. 1. Probability introduced through Sets and Relative Frequency: Experiments and Sample Spaces, Discrete and Continuous Sample Spaces, Events, Probability Definitions and Axioms

5

2. 2. , Mathematical Model of Experiments, Probability as a Relative 5

MITS-D/ECE-SDE-07

Frequency, Joint Probability, Conditional Probability, Total Probability, Bayes’ Theorem, Independent Events:

3. 3. Definition of a Random Variable, Conditions for a Function to be a Random Variable, Discrete and Continuous, Mixed Random Variable, Distribution and Density functions

4

4. 4. Properties, Binomial, Poisson, Uniform, Gaussian, Exponential, Rayleigh, Conditional Distribution, Methods of defining Conditioning Event, Conditional Density, Properties.

4

5. 5. Introduction, Expected Value of a Random Variable, Function of a Random Variable, Moments about the Origin, Central Moments, Variance and Skew, Chebychev’s Inequality, Characteristic Function, Moment Generating Function

5

6. 6. Transformations of a Random Variable: Monotonic Transformations for a Continuous Random Variable, Nonmonotonic Transformations of Continuous Random Variable, Transformation of a Discrete Random Variable.

4

7. 7. Vector Random Variables, Joint Distribution Function, Properties of Joint Distribution, Marginal Distribution Functions, Conditional Distribution and Density – Point Conditioning, Conditional Distribution and Density – Interval conditioning

4

8. 8. Statistical Independence, Sum of Two Random Variables, Sum of Several Random Variables, Central Limit Theorem, (Proof not expected). Unequal Distribution, Equal Distributions.

4

9. 9. Expected Value of a Function of Random Variables: Joint Moments about the Origin, Joint Central Moments, Joint Characteristic Functions, Jointly Gaussian Random Variables: Two Random Variables case,

4

10. 10. N Random Variable case, Properties, Transformations of Multiple Random Variables, Linear Transformations of Gaussian Random Variables

4

11. 11. The Random Process Concept, Classification of Processes, Deterministic and Nondeterministic Processes, Distribution and Density Functions, concept of Stationarity and Statistical Independence. First-Order Stationary Processes, Second- Order and Wide-Sense Stationarity, (N-Order)

5

12. 12. Strict-Sense Stationarity, Time Averages and Ergodicity, Mean-Ergodic Processes, Correlation-Ergodic Processes, Autocorrelation Function and Its Properties, Cross-Correlation Function and Its Properties, Covariance Functions, Gaussian Random Processes Poisson Random Process

5

13. 13. The Power Spectrum: Properties, Relationship between Power Spectrum and Autocorrelation Function,

3

14. 14. The Cross-Power Density Spectrum, Properties, Relationship between Cross-Power Spectrum and Cross-Correlation Function

3

15. 15. LINEAR SYSTEMS WITH RANDOM INPUTS : Random Signal Response of Linear Systems: System Response – Convolution, Mean and Mean-squared Value of System Response, autocorrelation Function of Response,

4

MITS-D/ECE-SDE-07

16. 16. Cross-Correlation Functions of Input and Output, Spectral Characteristics of System Response: Power Density Spectrum of Response, Cross-Power Density Spectrums of Input and Output, Band pass, Band-Limited and Narrowband Processes

4

17. 17. Properties, Modeling of Noise Sources: Resistive (Thermal) Noise Source, Arbitrary Noise Sources, Effective Noise Temperature, Average Noise Figures, Average Noise Figure of cascaded networks.

3

TOTAL HOURS70


LESSON PLAN

SUBJECT: PROBABILITY THEORY AND STOCHASTIC PROCESSES ECE II Year I SemesterNAME OF THE FACULTY: ARUN S

S.No Week No


Actualhours

1. 1. Probability introduced through Sets and Relative Frequency: Experiments and Sample Spaces, Discrete and Continuous Sample Spaces, Events, Probability Definitions and Axioms.

5

2. 2. Mathematical Model of Experiments, Probability as a Relative 5

MITS-D/ECE-SDE-07

Frequency, Joint Probability, Conditional Probability, Total Probability, Bayes’ Theorem, Independent Events.

3. 3. Definition of a Random Variable, Conditions for a Function to be a Random Variable, Discrete and Continuous, Mixed Random Variable, Distribution and Density functions.

4

4. 4. Properties, Binomial, Poisson, Uniform, Gaussian, Exponential, Rayleigh, Conditional Distribution, Methods of defining Conditioning Event, Conditional Density, Properties.

4

5. 5. Introduction, Expected Value of a Random Variable, Function of a Random Variable, Moments about the Origin, Central Moments, Variance and Skew, Chebychev’s Inequality, Characteristic Function, Moment Generating Function.

5

6. 6. Transformations of a Random Variable: Monotonic Transformations for a Continuous Random Variable, Nonmonotonic Transformations of Continuous Random Variable, Transformation of a Discrete Random Variable.

4

7. 7. Vector Random Variables, Joint Distribution Function, Properties of Joint Distribution, Marginal Distribution Functions, Conditional Distribution and Density – Point Conditioning, Conditional Distribution and Density – Interval conditioning.

4

8. 8. Statistical Independence, Sum of Two Random Variables, Sum of Several Random Variables, Central Limit Theorem, (Proof not expected). Unequal Distribution, Equal Distributions.

4

9. 9. Expected Value of a Function of Random Variables: Joint Moments about the Origin, Joint Central Moments, Joint Characteristic Functions, Jointly Gaussian Random Variables: Two Random Variables case.

4

10. 10. N Random Variable case, Properties, Transformations of Multiple Random Variables, Linear Transformations of Gaussian Random Variables.

4

11. 11. The Random Process Concept, Classification of Processes, Deterministic and Nondeterministic Processes, Distribution and Density Functions, concept of Stationarity and Statistical Independence. First-Order Stationary Processes, Second- Order and Wide-Sense Stationarity, (N-Order).

5

12. 12. Strict-Sense Stationarity, Time Averages and Ergodicity, Mean-Ergodic Processes, Correlation-Ergodic Processes, Autocorrelation Function and Its Properties, Cross-Correlation Function and Its Properties, Covariance Functions, Gaussian Random Processes Poisson Random Process.

5

13. 13. The Power Spectrum: Properties, Relationship between Power Spectrum and Autocorrelation Function.

3

14. 14. The Cross-Power Density Spectrum, Properties, Relationship between Cross-Power Spectrum and Cross-Correlation Function

3

15. 15. LINEAR SYSTEMS WITH RANDOM INPUTS : Random Signal 4

MITS-D/ECE-SDE-07

Response of Linear Systems: System Response – Convolution, Mean and Mean-squared Value of System Response, autocorrelation Function of Response.

16. 16. Cross-Correlation Functions of Input and Output, Spectral Characteristics of System Response: Power Density Spectrum of Response, Cross-Power Density Spectrums of Input and Output, Band pass, Band-Limited and Narrowband Processes.

4

17. 17. Properties, Modeling of Noise Sources: Resistive (Thermal) Noise Source, Arbitrary Noise Sources, Effective Noise Temperature, Average Noise Figures, Average Noise Figure of cascaded networks.

3

TOTAL HOURS70


LESSON PLAN

SUBJECT: DIGITAL IC APPLICATIONS ECE III Year I SemesterNAME OF THE FACULTY: ARUN S

S.No Week No


Actualhours

1. 1. CMOS LOGIC : Introduction to logic families, CMOS logic, CMOS steady state electrical behavior

4

2. 2. CMOS dynamic electrical behavior, CMOS logic families. 4

MITS-D/ECE-SDE-07

3. 3. BIPOLAR LOGIC AND INTERFACING : Bipolar logic, Transistor logic, TTL families, CMOS/TTL interfacing, low voltage CMOS logic and interfacing

5

4. 4. Emitter coupled logic, Comparison of logic families, Familiarity with standard 74XX and CMOS 40XX series-ICs – Specifications

4

5. 5. VHDL HARDWARE DESCRIPTION LANGUAGE : Design flow, program structure, types and constants

4

6. 6. functions and procedures, libraries and packages.THE VHDL DESIGN ELEMENTS : Structural design elements

4

7. 7. data flow design elements, behavioral design elements, time dimension and simulation synthesis.

3

8. 8. COMBINATIONAL LOGIC DESIGN : Decoders, encoders, three state devices, multiplexers and demultiplexers, Code Converters

5

9. 9. EX-OR gates and parity circuits, comparators, adders & subtractors, ALUs, Combinational multipliers. VHDL modes for the above ICs.

4

10. 10. DESIGN EXAMPLES (USING VHDL) : Design examples (using VHDL) - Barrel shifter

4

11. 11. comparators, floating-point encoder, dual parity encoder. 512. 12. SEQUENTIAL LOGIC DESIGN : Latches and flip-flops, PLDs,

counters, shift register5

13. 13. and their VHDL models, synchronous design methodology, impediments to synchronous design.

3

14. 14. MEMORIES : ROMs : Internal structure, 2D-decoding commercial types, timing and applications

4

15. 15. Static RAM: Internal structure, SRAM timing, standard SRAMS, synchronous SRAMS.

4

16. 16. Dynamic RAM : Internal structure, timing, synchronous DRAMs. Familiarity with Component Data Sheets – Cypress CY6116,CY7C1006, Specifications.

5

17. 17. REVISION 3

TOTAL HOURS70


LESSON PLAN

SUBJECT: DIGITAL IC APPLICATIONS ECE III Year I SemesterNAME OF THE FACULTY: MR. MAHESH

S.No Week No


Actualhours

1. 1. CMOS LOGIC : Introduction to logic families, CMOS logic, CMOS steady state electrical behavior

4

2. 2. CMOS dynamic electrical behavior, CMOS logic families. 4

MITS-D/ECE-SDE-07

3. 3. BIPOLAR LOGIC AND INTERFACING : Bipolar logic, Transistor logic, TTL families, CMOS/TTL interfacing, low voltage CMOS logic and interfacing

5

4. 4. Emitter coupled logic, Comparison of logic families, Familiarity with standard 74XX and CMOS 40XX series-ICs – Specifications

4

5. 5. VHDL HARDWARE DESCRIPTION LANGUAGE : Design flow, program structure, types and constants

4

6. 6. functions and procedures, libraries and packages.THE VHDL DESIGN ELEMENTS : Structural design elements

4

7. 7. data flow design elements, behavioral design elements, time dimension and simulation synthesis.

3

8. 8. COMBINATIONAL LOGIC DESIGN : Decoders, encoders, three state devices, multiplexers and demultiplexers, Code Converters

5

9. 9. EX-OR gates and parity circuits, comparators, adders & subtractors, ALUs, Combinational multipliers. VHDL modes for the above ICs.

4

10. 10. DESIGN EXAMPLES (USING VHDL) : Design examples (using VHDL) - Barrel shifter

4

11. 11. comparators, floating-point encoder, dual parity encoder. 512. 12. SEQUENTIAL LOGIC DESIGN : Latches and flip-flops, PLDs,

counters, shift register5

13. 13. and their VHDL models, synchronous design methodology, impediments to synchronous design.

3

14. 14. MEMORIES : ROMs : Internal structure, 2D-decoding commercial types, timing and applications

4

15. 15. Static RAM: Internal structure, SRAM timing, standard SRAMS, synchronous SRAMS.

4

16. 16. Dynamic RAM : Internal structure, timing, synchronous DRAMs. Familiarity with Component Data Sheets – Cypress CY6116,CY7C1006, Specifications.

5

17. 17. REVISION 3

TOTAL HOURS70


LESSON PLAN

SUBJECT: MANAGERIAL ECONOMICS AND FINANCIAL ANALYSIS ECE III Year I SemesterNAME OF THE FACULTY: N.SHESHADRI

S.No Week No


Actualhours

1. 1. INTRODUCTION TO MANAGERIAL ECONOMICS : Definition, Nature and Scope Managerial Economics–Demand Analysis

4

MITS-D/ECE-SDE-07

2. 2. Demand Determinants, Law of Demand and its exceptions 3

3. 3. ELASTICITY OF DEMAND : Definition, Types, Measurement and Significance of Elasticity of Demand. Demand Forecasting, Factors governing demand forecasting

4

4. 4. methods of demand forecasting (survey methods, statistical methods, expert opinion method, test marketing, controlled experiments, judgmental approach to demand forecasting).

5

5. 5. THEORY OF PRODUCTION AND COST ANALYSIS : Production Function – Isoquants and Isocosts, MRTS, Least Cost Combination of Inputs, Production function, Laws of Returns, Internal and External Economies of Scale

5

6. 6. Cost Analysis : Cost concepts, Opportunity cost, Fixed Vs.Variable costs, Explicit costs Vs.Implicit costs, Out of pocket costs vs. Imputed costs. Break-even Analysis (BEA)-

5

7. 7. termination of Break-Even Point (simple problems)-Managerial Significance and limitations of BEA.

5

8. 8. INTRODUCTION TO MARKETS & PRICING STRATEGIES : Market structures: Types of competition, Features of Perfect competition, Monopoly and Monopolistic Competition

5

9. 9. Price-Output Determination in case of Perfect Competition and Monopoly. Pricing Strategies

5

10. 10. BUSINESS & NEW ECONOMIC ENVIRONMENT : Characteristic features of Business, Features and evaluation of Sole Proprietorship, Partnership, Joint Stock Company

4

11. 11. Public Enterprises and their types, Changing Business Environment in Post-liberalization scenario.

4

12. 12. CAPITAL AND CAPITAL BUDGETING : Capital and its significance, Types of Capital, Estimation of Fixed and Working capital requirements, Methods and sources of raising finance. Nature and scope of capital budgeting

5

13. 13. features of capital budgeting proposals, Methods of Capital Budgeting: Payback Method, Accounting Rate of Return (ARR) and Net Present Value Method (simple problems).

5

14. 14. INTRODUCTION TO FINANCIAL ACCOUNTING : Double-Entry Book Keeping, Journal, Ledger, Trial Balance- Final Accounts (Trading Account,

5

15. 15. Profit and Loss Account and Balance Sheet with simple adjustments).FINANCIAL ANALYSIS THROUGH RATIOS : Computation, Analysis and Interpretation of Liquidity Ratios (Current Ratio and quick ratio), Activity Ratios (Inventory turnover ratio and Debtor Turnover ratio)

5

16. 16. Capital structure Ratios (Debt-Equity ratio, Interest Coverage ratio), and Profitability ratios (Gross Profit Ratio, Net Profit ratio, Operating Ratio, P/E Ratio and EPS).

5

MITS-D/ECE-SDE-07

17. 17. REVISION 5

TOTAL HOURS79


LESSON PLANSUBJECT: MATHEMATICS – III ECE III Year I SemesterNAME OF THE FACULTY: MR.GOUSE BASHA

S.No Week No


Actualhours

1. 1. Special functions: Gamma and Beta Functions – Their properties – evaluation of improper integrals. Bessel functions – properties – Recurrence relations

MITS-D/ECE-SDE-07

2. 2. Orthogonality. Legendre polynomials – Properties – Rodrigue’s formula – Recurrence relations – Orthogonality

3. 3. Functions of a complex variable – Continuity – Differentiability – Analyticity – Properties – Cauchy-Riemann equations in Cartesian and polar coordinates

4. 4. Harmonic and conjugate harmonic functions – Milne – Thompson method.

5. 5. Elementary functions: Exponential, trigonometric6. 6. hyperbolic functions and their properties – General power Z (c is

complex), principal value.

7. 7. Complex integration: Line integral – evaluation along a path and by indefinite integration

8. 8. Cauchy’s integral theorem – Cauchy’s integral formula – Generalized integral formula.

9. 9. Complex power series: Radius of convergence – Expansion in Taylor’s series, Maclaurin’s series and Laurent series

10. 10. Singular point –Isolated singular point – pole of order m – essential singularity

11. 11. Residue – Evaluation of residue by formula and by Laurent series - Residue theorem

12. 12. Evaluation of integrals of the type (a) Improper real integrals

(b)

(c) (d) Integrals by identation

13. 13. Argument principle – Rouche’s theorem – determination of number of zeros of complex polynomials

14. 14. Maximum Modulus principle - Fundamental theorem of Algebra, Liouville’s Theorem

15. 15. Conformal mapping: Transformation by , lnz, z2, z (n positive integer), Sin z, cos z,z + a/z. Translation, rotation, inversion and bilinear transformation

16. 16. fixed point – cross ratio – properties – invariance of circles and cross ratio – determination of bilinear transformation mapping 3 given points

17. 17. REVISION

TOTAL HOURS

MITS-D/ECE-SDE-07


LESSON PLAN

SUBJECT: ENVIRONMENTAL STUDIES ECE III Year I SemesterNAME OF THE FACULTY: K.JAGADEESWAR

S.No Week No


Actualhours

1. 1. Multidisciplinary nature of Environmental Studies: Definition, Scope and Importance – Need for Public Awareness.

MITS-D/ECE-SDE-07

Natural Resources : Renewable and non-renewable resources – Natural resources and associated problems – Forest resources – Use and over – exploitation, deforestation

2. 2. case studies – Timber extraction – Mining, dams and other effects on forest and tribal people – Water resources – Use and over utilization of surface and ground water – Floods, drought, conflicts over water, dams – benefits and problems - Mineral resources: Use and exploitation, environmental effects of extracting and using mineral resources

3. 3. case studies. - Food res ources: World food problems, changes caused by agriculture and overgrazing, effects of modern agriculture, fertilizer-pesticide problems, water logging, salinity, case studies. – Energy resources: Growing energy needs, renewable and non-renewable energy sources use of alternate energy sources

4. 4. Case studies. Land resources: Land as a resource, land degradation, man induced landslides, soil erosion and desertification. Role of an individual in conservation of natural resources. Equitable use of resources for sustainable lifestyles.

5. 5. Ecosystems : Concept of an ecosystem. - Structure and function of an ecosystem. - Producers, consumers and decomposers. - Energy flow in the ecosystem - Ecological succession. - Food chains, food webs and ecological pyramids

6. 6. Introduction, types, characteristic features, structure and function of the following ecosystem:

a. Forest ecosystemb. Grassland ecosystemc. Desert ecosystemd. Aquatic ecosystems (ponds, streams, lakes, rivers, oceans, estuaries)

7. 7. Biodiversity and its conservation : Introduction - Definition: genetic, species and ecosystem diversity. Bio-geographical classification of India - Value of biodiversity: consumptive use, productive use, social, ethical, aesthetic and option values

8. 8. Biodiversity at global, National and local levels. - . India as a megadiversity nation - Hot-sports of biodiversity - Threats to biodiversity: habitat loss, poaching of wildlife, manwildlife conflicts. - Endangered and endemic species of India - Conservation of biodiversity: In-situ and Exsitu conservation of biodiversity.

9. 9. Environmental Pollution : Definition, Cause, effects and control measures of :

a. Air pollutionb. Water pollutionc. Soil pollutiond. Marine pollutione. Noise pollutionf. Thermal pollution

MITS-D/ECE-SDE-07

g. Nuclear hazards10. 10. Solid waste Management : Causes, effects and control measures

of urban and industrial wastes. – Role of an individual in prevention of pollution. - Pollution case studies. - Disaster management: floods, earthquake, cyclone and landslides.

11. 11. Social Issues and the Environment : From Unsustainable to Sustainable development -Urban problems related to energy -Water conservation, rain water harvesting, watershed management -Resettlement and rehabilitation of people; its problems and concerns. Case Studies

12. 12. Environmental ethics: Issues and possible solutions. -Climate change, global warming, acid rain, ozone layer depletion, nuclear accidents and holocaust. Case Studies. -Wasteland reclamation. -Consumerism and waste products. –Environment Protection Act. -Air (Prevention and Control of Pollution) Act

13. 13. Water (Prevention and control of Pollution) Act -Wildlife Protection Act -Forest Conservation Act -Issues involved in enforcement of environmental legislation. -Public awareness.

14. 14. Human Population and the Environment : Population growth, variation among nations. Population explosion - Family Welfare Programme. -Environment and human health

15. 15. Human Rights. -Value Education. -HIV/AIDS. -Women and Child Welfare. -Role of information Technology in Environment and human health. -Case Studies.

16. 16. Field work : Visit to a local area to document environmental assets River /forest grassland/hill/mountain -Visit to a local polluted site-Urban/Rural/industrial/ Agricultural Study of common plants, insects, birds. - Study of simple ecosystems-pond, river, hill slopes, etc.

17. 17. REVISION

TOTAL HOURS


LESSON PLAN

SUBJECT: ELECTRONIC MEASUREMENTS AND INSTRUMENTATION ECE IV YEAR 1SEMESTERNAME OF THE FACULTY: K.KANTHAMMA

S.NO

WEEKNO

TOPICS TO BE COVEREDPlannedhours

Actualhours

1 1 Performance characteristics of instruments, Static characteristics, Accuracy, Resolution, Precision, Expected value, Error, Sensitivity.

3

MITS-D/ECE-SDE-07

Errors in Measurement,

2 2Dynamic Characteristics-speed of response, Fidelity, Lag and Dynamic error. DC Voltimeters- Multirange, Range extension/Solid state works

5

3 3

differential voltmeters, AC voltmeters- multi range, range extension, shunt. Thermocouple type RF ammeter, Ohmmeters series type, shunt type, Multimeter for Voltage, Current and resistance measurements.

5

4 4Signal Generator- fixed and variable, AF oscillators, Standard and AF sine and square wave signal generators,

3

5 5Function Generators, Square pulse, Random noise, sweep, Arbitrary waveform

3

6 6Wave Analyzers, Haromonic Distortion Analyzers, Spectrum Analyzers, Digital Fourier Analyzers

3

7 7Oscilloscopes CRT features, vertical amplifiers, horizontal deflection system, sweep, trigger pulse, delay line,

4

8 8selector circuits, simple CRO, triggered sweep CRO, Dual beam CRO, Measurement of amplitude and frequency.

4

9 9Dual trace oscilloscope, sampling oscilloscope, storage oscilloscope, digital readout oscilloscope, digital storage oscilloscope,

3

10 10Lissajous method of frequency measurement, standard specifications of CRO, probes for CRO- Active & Passive, attenuator type, Frequency counter, Time and Period measurement.

5

11 11AC Bridges Measurement of inductance- Maxwell’s bridge, Anderson bridge.

4

12 12 Measurement of capacitance - Schearing Bridgewheat stone bridge.

4

13 13 Wien Bridge, Errors and precautions in using bridges. Q-meter. 4

14 14Capacitance, inductance; Strain gauges, LVDT, Piezo Electric transducers

4

15 15 Resistance Thermometers, Thermocouples, Thermistors, Sensistors. 5

16 16Measurement of physical parameters force, pressure, velocity, humidity,

3

17 17moisture, speed, proximity and displacement. Data acquisition systems.

3

TOTAL HOURS 65


lesson plan_1

Documents

advantages of optical

single mode fibers

fiber coupling

single mode fiber connectors

optical fibers attenuation

loop antennas

antenna arrays

optical links