@ YldJa BHAVAN'S VIVEKANANDA COLLEGE OF SCIENCE, HUMANITIES AND COMMERCE, SAINIKPURI, SECUNDERABAD. Autonomous College Affiliated to oSMANIA UNIVERSITY, Hyderabad. Faculty of Science-B.Sc. Electronics Course Structure (To be implemented with effect from 2018-19) Classes: B Sc I Year, II Year and III Year to select any one elective paper each in semester V and semester VI CH a !R,t\,tAN oard of Stuctius rir ElscttUnlc| Osmania UniversitY, HYd' Year Semester Paper Code Paper Hours/ week Internal Marks Semester end exam Marks Total Marks Credits I I EL 124 Circuit Analysis - Theory 4 30 70 100 4 EL I24P Circuit Analysis - Practicals 2 25 25 I II EL224 Semiconductor Devices- Theory 4 30 70 100 4 EL224P Semiconductor Devices- Practicals 2 25 25 1 II m E,L324 Electronic Circuits- Theory 4 30 70 100 4 EL324P Electronic Circuits - Practicals 2 25 25 I 58324 Basic Instrumentation Skills 2 l5 35 50 2 rV EL 424 Operational Amplifiers and Communications- Theory 4 30 70 100 4 EL 424P Operational Amplifiers and Communications- Practicals 2 25 25 I 58,424 Renewable Energy & Energy Harvesting 2 l5 35 50 2 m v* EL 524 Digital Electronics-Theory ^ J 30 70 100 J EL 524P Digital Electronics- Practicals 2 25 25 I EL 524A 8085 Microprocessor-Theory a J 30 70 100 J EL 5244P 8085 Microprocessor- Practicals 2 25 25 I EL 524B Digital Communication Elective-Theory 3 30 70 100 J EL 5248P Digital Communication Elective-Practicals 2 25 25 I SE 524 Consumer Electronics 2 15 35 50 2 VI* EL 624 8051 Microcontroller Elective-Theory a J 30 70 100 J EL 624P 8051 Microcontroller Elective-Practicals 2 25 25 I EL 624A Digital System Design with VHDL Elective-Theory J 30 70 100 J EL 624AP Digital System Design with VHDL Elective-Practicals 2 25 25 I EL624B Computer Organization Elective-Theory J 30 70 100 J EL 6248P Computer Organization Elective-Practicals 2 25 25 I SE 624 Schematic capture with MultiSim 2 l5 35 50 2 *Note: Students have llr ! r W
Transcript
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BHAVAN'S VIVEKANANDA COLLEGE OF SCIENCE, HUMANITIES AND COMMERCE,SAINIKPURI, SECUNDERABAD.
Autonomous CollegeAffiliated to oSMANIA UNIVERSITY, Hyderabad.
Faculty of Science-B.Sc. ElectronicsCourse Structure
(To be implemented with effect from 2018-19)
Classes: B Sc I Year, II Year and III Year
to select any one elective paper each in semester V and semester VICH a !R,t\,tAN
oard of Stuctius rir ElscttUnlc|Osmania UniversitY, HYd'
Year Semester Paper Code PaperHours/week
InternalMarks
Semesterend exam
Marks
TotalMarks Credits
I
I EL 124 Circuit Analysis - Theory 4 30 70 100 4EL I24P Circuit Analysis - Practicals 2 25 25 I
IIEL224 Semiconductor Devices-
Theory4 30 70 100 4
EL224PSemiconductor Devices-Practicals
2 25 25 1
II
m
E,L324 Electronic Circuits- Theory 4 30 70 100 4
EL324PElectronic Circuits -Practicals
2 25 25 I
58324 Basic Instrumentation Skills 2 l5 35 50 2
rV
EL 424Operational Amplifiers andCommunications- Theory
4 30 70 100 4
EL 424POperational Amplifiers andCommunications- Practicals
2 25 25 I
58,424Renewable Energy &Energy Harvesting
2 l5 35 50 2
m
v*
EL 524 Digital Electronics-Theory J 30 70 100 J
EL 524P Digital Electronics- Practicals 2 25 25 IEL 524A 8085 Microprocessor-Theory aJ 30 70 100 J
EL 5244P8085 Microprocessor-Practicals
2 25 25 I
EL 524BDigital CommunicationElective-Theory
3 30 70 100 J
EL 5248PDigital CommunicationElective-Practicals
2 25 25 I
SE 524 Consumer Electronics 2 15 35 50 2
VI*
EL 6248051 MicrocontrollerElective-Theory
aJ 30 70 100 J
EL 624P8051 MicrocontrollerElective-Practicals
2 25 25 I
EL 624ADigital System Design withVHDL Elective-Theory J 30 70 100 J
EL 624APDigital System Design withVHDL Elective-Practicals 2 25 25 I
EL 6248P Computer OrganizationElective-Practicals 2 25 25 I
SE 624Schematic capture withMultiSim 2 l5 35 50 2
*Note: Students have
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qffisliffiffBhavan's Vivekananda CoIIege
of Science, Humanities and Commerce, Sainikpuri, Secunderabad.Autonomous College
Affiliated to Osmania University, Hyderabad.
Accredited with 'A' grade by NAAC
SyllabusB Sc I Year Electronics
Wef the academic year: 2019-20
Semester ICircuit Analysis (60 Hours) - Paper Code: EL 124
HoursAVeek: 4 Credits: 4
Course Objectives: This course aims,
COB 1 : To develop an understanding of the basic circuit laws and elements of electric circuits
COB2: To introduce the basic concepts of DC and AC circuit behavior
COB3: To make the students proficient in analyzing any given electricol network by applyingbasic circuit laws and network theorems.
COB4: To become familiar with the working principle of CRO and its operation
UNIT _ I (1s)
AC Fundamentals: Periodic waveforms, sine wave - average and RMS values; the j-operator,polar and rectangular forms of complex numbers, phasor diagram; complex impedance andadmittance.
Kirchhoffs Current and Voltage Laws: Concept of voltage and current sources - KVL andKCL- application to simple circuits consisting of resistors and sources - Node voltage analysisand Mesh analysis.
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Network Theorems: Statement and explanation of theorems - superposition theorem, Thevenin'stheorem, Norton's theorem, maximum power transfer theorem - application to simple networks(DC and AC).
Reciprocity Theorem, Millman's Theorem, application to simple networks. T and r networks,conversions between them.
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RC and RL Circuits:
Transient response of RC and RL circuits with step input, time constant.
Frequency response of RC and RL circuits, types of filters - low pass filter and high pass filter,differentiating and integrating circuits.
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UNIT.IV (1s)
Resonance: RLC circuit - series and parallel resonance - resonant frequency - Q Factor-Bandwidth - Selectivity.
Cathode Ray Oscilloscope: Cathode Ray Tube (CRT), CRO operation, voltage sweepsynchronizing & triggering, measurement of amplitude, time period, frequency and phase.
Course Outcomes:
By the end of the course, students will be able to
COI: Apply the l*towledge of basic circuit la,vs and simplify the network using reduction
techniques.
CO2: Analyze the circuits using Kirchhoff's laws and Network theorems.
CO3: Infer and evaluate transient response and steady state response of RC and RL circuits.
CO4: Analyze thefrequency response of circuits containing RC, RL and RLC.
CO5: Understand the working of the most commonly used equipment CRO and use it formeosurement of electrical quantities.
CO6: Simulote to study the transient and frequency response of RC, RL and RLC circuits using
appropriate software.
Recommended Books:
l. B Sc I Year Electronics - Telugu Akademi.
2. Grob's Basic Electronics - Mitchel E Schultz, Tata McGraw Hill.3. Electric Circuits - Mahmood Nahvi and Joseph Edminister, Schaum's outlines 5th Ed. Mc
Graw Hill Education (lndia) Pvt. Limited.
4. Engineering Circuit Analysis - William H. Hayt, Jack E. Kemmerly, Steven M. Durbin.
5. Applied Electronics - R S Sedha, S. Chand Publications.
1. Familiarization of CRO - measurement of amplitude, time period, frequency and phase
angle.2. Verification of KVL and KCL.3. Verification of Thevenin's and Norton's theorems4. Verification of Maximum power transfer theorem5. RC circuits - Frequency response (Low pass and High pass filters).6. RC circuits - differentiation and integration - tracing of waveforms.7. LCR - Series resonance circuit - frequency response - Determinatron of fo, Q andband
width.8. Simulation: i) Verification of KVL and KCL.
ii) Transient response of RC and RL circuitsiii) Frequency response of RC and RL circuitsiv) Frequency response of RLC circuits (series and parallel).
Note: Student has to perform minimum of SIX experiments. Experiment no. 8 is
compulsory.
Reference Books:
1. Basic Electronics - A Text Lab Manual - Zbar, Malvino, Miller.2.Labmanual for Electronic Devices and Circuits,4th Edition - David A Bell - PHI
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ffiBIiffivffBhavan's Vivekananda College
of Science, Humanities and Commerce, Sainikpuri, Secunderabad.Autonomous College
Affiliated to Osmania University, Hyderabad.
Accredited with 'A' grade by NAAC
SyllabusB Sc I Year Electronics
Wef the academic year: 2019-20
Semester IISemiconductor Devices (60 Hours) - Paper Code: 8L224
HoursAVeek: 4 Credits: 4
Course Objectives:
This course aims to,
COB 1 : To familiarize students with the fundamentals of Semiconductor Physics
COB2: To make them understand the operation of various semiconductor devices
COB3: To train them to apply the devices for common applications.
COB4: To provide an understonding of the capabilities and limitations of various semiconductordevices
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PN Junction: Basics of semiconductor physics, formation of PN junction, depletion region,junction capacitance, VI characteristics of a PN junction diode, diode equation (no derivation),effect of temperature on reverse saturation current.
Working and characteristics of i) Zener diode - zener and avalanche breakdown ii) Tunnel diodeand iii) Varactor diode; Application of zener as voltage regulator.
UNIT.II (1s)
Bipolar Junction Transistor (BJT): PNP and NPN transistors, current components in BJT, BJTstatic characteristics (input and output), Early effect, CB, CE, CC configurations of transistor,transistor as an amplifier.
BJT in CE configuration as two port network, h-parameter model and hybrid equivalent circuit.Determination of h-parameters from the characteristics; load line analysis, transistor biasing-Fixed, voltage divider bias and self bias, stability factor.
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Field Effect Transistor (FET): Construction and working of JFET, drain and transfer
characteristics of FET, determination of FET parameters. Application of FET as Voltage VariableResistor (VVR), advantages of FET over BJT; MOSFET - Construction and working of
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enhancement and depletion mode MOSFET, output and transfer characteristics; Application ofMOSFET as a switch.
Uni Junction Transistor (UJT): Construction and working of UJT and its characteristics.Application of UJT as relaxation oscillator.
UNIT- IV (1s)
Silicon Controlled Rectifier (SCR): Construction and working of SCR. Two transistorrepresentation, characteristics of SCR. Application of SCR in half wave and full wave rectifiersfor power control.
Photo electronic Devices: Construction and Characteristics of Light Dependent Resistor (LDR),Photo voltaic Cell, Photo diode, Photo transistor and Light Emitting Diode (LED).
Course Outcomes:
By the end of the course, the students will be able to
COI : Study and analyze the behavior of semiconductor devices
CO2: Dffirentiate the behavior of BJT in CB, CE and CC configurations
CO3: Bias BJTfor application in amplifier circuits
CO4: Use zener diode, BJT, FET, UJT and SCR in simple applications
CO5: Simulate PN junction diode, zener diode, BJT and JFET to study their characteristics usingappropriate software
Books Recommended:
B Sc First Year ELECTRONICS - Telugu AkademiElectronic Devices and Circuits - Jacob Millman and Christos C Halkias(TMH)Basic Electronics and Linear Circuits- Bhargava, Kulsreshta, Gupta (TMH)Principles of Electronics - V.K.Mehta & Rohit MehtaElectronic Devices and Circuits - Allen Mottershed (PHI)Electrical Technology Vol. I and II, B L Theraja, A K Theraja, S. Chand
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B Sc I Year ElectronicsSemester-II
Semiconductor Devices Practical-Paper Code: EL 224P(30 Hours - 15 sessions)
HoursAVeek: 2
List of experiments:
Credits: 1
1. V-I characteristics of a Junction diode and determination of cut-in voltage, forward andreverse resistances.
2. Y-I Characteristics of Zener diode- Determination of Zener breakdown voltage.3. Load and line regulation characteristics of Zener voltage regulator.4. IIP characteristics of the given transistor in CE mode-determination of h-parameters.5. OiP characteristics of the given transistor in CE mode-determination of h-parameters.6. Drain and transfer characteristics of FET- determination of FET parameters.
7. UJT characteristics-determination of intrinsic stand - off ratio '11'.
10. Simulation: i. Diode (PN junction diode and zener diode) characteristicsii. FET-Characteristicsiii. BJT-characteristics
Note: Student has to perform minimum of SIX experiments.
Reference Books:
l. Lab manual for Electronic Devices and Circuits - 4th Edition by David A Bell - PHI2. Experiments in Electronics S V Subramanyam - Mac Millan India Limited3. Basic Electronics - A Text lab manual by Zbar, Malvino, Miller.
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BHAVAN'S VIVEKANANDA COLLEGEof Science, Humanities And Commerce, Sainikpuri
Autonomous College I Affiliated to Osmania UniversityAccredited with 'A' Grade by NAAC
Syllabus - B Sc II Year Electronics(To be implemented for the students joined in 2019-20)
wef the academic year:2020-21
Semester IIICourse Name: Analog Circuits Course Code: 8L324
(60 Hours)
HPW: 4 CREDITS: 4
Course Objectives:This course aims to -
COBI: learn the working principle of DC power supply.COB 2: design the regulated DC power.suppliesCOB 3: understand the methods of biasing transi,stors and analyse a single stage transistoramplifier circuits.COB 4: apply positive feedback in amplifiers for the design of o.scillators and multivibrators.
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Rectifiers: Rectifiers - half wave, full wave and bridge rectifier, ripple factor, efficiency,regulation, harmonic components in rectified output.
Regulated Power Supplies: Zener regulation, block diagram of regulated power supply, series
and shunt regulated power supplies.
IC regulators - Three terminal regulators(78XX and 79XX), variable voltage regulators.
Principle and working of switch mode power supply (SMPS). UPS - Principle and working.
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Transistor amplifier: Classification of amplifiers, hybrid n model of a transistor, RC coupled CE
amplifier - frequency response, analysis.
Feedback in amplifiers: Positive and negative feedback- Effect of negative feedback on gain,
bandwidth, noise, input and output impedances. Emitter follower and Darlinglon pair.
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Oscillators: Barkhausen criterion for sustained oscillations, RC oscillators - RC phase shift and
Wein's bridge oscillators, LC oscillators - Hartley and Collpits, crystaloscillator.
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Multivibrators: Astable, Monostable and Bistable multivibrators (qualitative only)
Course Outcomes:Upon,succes.sfiil completion oJ' this course, studentswill be able to-
COI: Design a dc regulated power.supply.CO2: Properly bia,s a BJTfor an amplifier.CO3 : Design amplifieri' using BJT and .study frequency responses.
CO4: Observe the effect of positive feedback and design dffirent oscillators and multivibrators
COS: Develop the skill to build and troubleshoot analog circuits.
Reference Books:
l. Electronic Devices and Circuits - Millman and Halkias (TMH)2. Basic Electronics and linear circuits - Bhargava, Kulshreshta& Gupta TMH3. A first course in Electronics - AA Khan and KK Dey-PHI4. Electronic Devices and Circuit Theory - Robert L Boylestad & Louis Nashelsky
Analog Circuits Practicals - Paper Code: EL324P(30 Hours - 15 sessions)
Hours/Week: 2
List of experiments:
Credits: I
l. Study of HWR, FWR and bridge rectifier, detennination of ripple factor.
2. Series inductor, shunt capacitor, L-section and r-section filters; determination of ripplefactor.
3. Study of voltage regulator using 7805 &7905.4. RC coupled amplifier5. Emitter follower.6. RC Phase shift oscillator.
7. Astable multivibrator.8. Simulationexperiments
a) Rectifiers
b) RC coupled amplifierc) Wein's bridge oscillatord) Colpitt's oscillator
e) RC phase shift oscillator
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Note: Student has to perform minimum of SIX experiments. Experiment no.8 iscompulsory.
Reference Books:
l. Basic Electronics - A Text Lab Manual - Zbar, Malvino, Miller.
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of Science, Humanities and Commerce, SainikpuriAutonomous College I Affiliated to Osmania University
Accredited with 'A' Grade by NAAC
Syllabus - B Sc II Year Electronics(To be implemented for the students joined in 2019-20)
wef the academic year:2020-21
Semester IVCourse Name: Operational amplifiers and Communications Course Code: EL 424
(60 Hours)
HoursAileek: 4 Credits: 4
Course 0bjectives:
The course aims to -
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Provide the basic education in the working of linear integrated circuits.Under.stand the OpAmp ICs - construction, characteristics, parameter limitations andapplicotion.
To give basic knowledge of analog communication.
Become proficient with simulation software skills for the analysis and design ofcircuits.
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Operational Amplifiers: Differential amplifier, block diagram of OpAmp, ideal characteristicsof Op Amp; OpAmp parameters - input resistance, output resistance, common mode rejectionratio (CMMR), slew rate, offset voltages, input bias current, frequency response of OpAmp.
Basic OpAmp circuits - inverting and non-inverting amplifiers, virtual ground.
Applications of OpAmps: summing amplifier, subtractor, comparator, voltage follower,integrator, d i fferentiator.
UNIT- rr (ls)Applications of OpAmps: Logarithmic amplifier, sine wave [Wien Bridge] and square wave
[Astable] generators, triangular wave generator, monostable multivibrator, solving simple second
order differential equation. series and shunt regulators.
UNIT - III (ls)Modulation: Need for modulation, types of modulation - Amplitude, Frequency and Phase
modulation.
Amplitude modulation: Analysis of Amplitude modulation, side bands, modulation index, AMmodulator, Demodulation - diode detector.
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IC 555 Timer [Block diagram and its working], IC 555 as astable and monostable multivibrators.
8
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diode and reactance modulator; detection of FM waves - balanced slope, ratio detector.
Advantages of frequency modulation.
AM and FM radio transmitters and receivers [block diagram approach].
Pulse modulation: PAM, PWM, PPM; PCM and Delta modulations.
Course Outcomes:Upon succr,s:sfiil completion of this cour.se, students will be able to-
COI: Understand basic dffirential amplifier and applications in linear integrated circuits.CO2: Learn basic function of OpAmp, ideal and practical characteristics and their
mat he mat ic al app I icat ions.CO3: C'on.struct active filters, comparators for various applications.CO4: Design dffirent multivibrators using IC' 555.COS: Be familiar with the fundamental concepts of analog communications, working of
transmitter and rece iver.
Reference Books:l. OpAmp and linear Integrated Circuits - Ramakant Gayakwad, PHI
2. Linear Integrated Circuits - D Roy Choudhury & Shail B Jain
3. Electronic Communication Systerns - George Kennedy & Bernard Davis
4. Principles of Electronic Communication Systems - Louis E Frenzel, TMH
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Operational amplifiers and Communications
(30 Hours * 15 sessions)
HoursAVeek: 2
P racticals-C o de z EL424P
Credits: 1
List of experiments:
Using IC 741
l. Inverting and Non inverting amplifiers2. Comparator(Zero crossing detector)
3. Wien's bridge oscillator4. Astable multivibrator5. Astable multivibrator using IC 555
6. Monostable multivibrator using IC 555.
7. AM modulator and detector
8. Simulation of all the above experiments:a) Inverting and Non inverting amplifiersb) Summing amplifier and comparator using op amp
c) Integrator/ Differentiator using op amp
d) Wein's bridge oscillator using op amp
e) Astable multivibrator using op amp
0 Astable multivibrator using IC 555
Note: Student has to perform minimum of SIX experiments. Experiment no. 8 is
compulsory.
Reference Books:
l. Basic Electronics - A Text Lab Manual - Zbar, Malvino, Miller.
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r"*ttsri!ffiHiiBHAVAN'S VIVEKANANDA COLLEGE
of Science, Humanities And Commerce, SainikpuriAutonomous College I Affiliated to Osmania University
Accredited with 'A' Grade by NAAC
Syllabus- B Sc III Year Electronics(To be implemented for the students joined in 2019-20)
wef the academic year: 2021-2L/Semester V -Core Course
Course Name: Digital Electronics Course Code: EL 524(45 Hours)
HPW:3 CREDITS: 3
Course Objectives:The course aims to -
COBI: learn- logic gates, boolean algebra and Karnaugh maps for designing digital circuits.
COB2: study combinational Logic circuits - adders, subtractors, multiplexers, encoders, etc.
COB3: Study sequential Logic circuits - flip-Jlops, registers and counters.
COB4: understand the TTL and CMOS logic family of ICs and various memories.
COB5: acquire the basic principles of ADC and DACs.
UNIT I (l l)
Logic gates: AND, OR, NOT, NAND, NOR, Exclusive-OR and Exclusive-NOR, Implementationof logic functions using gates, NAND-NOR implementations - Multi level gate implementations.
Minimization techniques: Boolean postulates and laws, De-Morgan's Theorem, Principle ofDuality, Boolean expression, Minirnization of Boolean expressions - Minterm, Maxterm, Sum ofProducts (SOP) , Product of Sums (POS). Karnaugh map Minimization - Don't care conditions.
Sequential circuits: Latches, Flip-f1ops - SR, D, JK, T and Master-Slave; Registers - shiftregisters - Universal shift registers - Ring counter; Asynchronous Ripple counter &Up/Downcounter - Synchronous counters - Modulo N counter
UNIT IV (12)
Logic families: TTL and CMOS Logic and their characteristics
Memory: Classiflcation of memories: RAM - static and dynamic; RoM - diode RoM, pRoM,EPROM, EEPROM and flash memorv.
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D/A and A/D Converters: Binary weighted DAC, R-2R ladder type DAC; Dual slope ADC,Successive approximation ADC.
Course Outcome:Upon successful completion of this course, students will fu able to -
COl: use various number systems for application in digital circuits.
CO2: analyse various combinational circuits.
CO3: study the working of various sequential circuits.
CO4: Identify classifu various memory devices and data converters develop skill to build andtrouble s hoot digital c ircuits
Recommended Books:l. Digital Electronics - William H. Gothmann, Prentice Hall.2. Principles of Digital Electronics - Malvino &Leach,TMH.3. Digital logic Digital Design - Morris Mano, PHL4. Digital Integrated Electronics - Taub and Schilling, McGraw-Hill.5. Digital Systems, Principles and Applications - R. J. Tocci, P.F//.
6. Digital Design: Principles & Practices - John F. Wakerly, Pearson Education.
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Course Name: Digital Electronics Practicals(30 Hours - l5 sessions)
Course Code: EL 524 P
HPW: 2 CREDIT: 1
l. Verification of truth tables for OR, AND, NOT, NAND, NOR, EX-OR gates (using74XX-series ICs)
2. Construction of gates using Universal gates (NAND, NOR).3. Construction of adders - Half, Full and Parallel adder; verification of truth tables.4. Construction and verification of truth tables - RS flip-flop using gates, D, JK using ICs.5. Verification of counters using IC 7493 and lC 7490.6. Modulo-N counter using IC 7493.7. 4 bit DAC using R-2R ladder network.8. Simulation experiments using appropriate electronic circuit simulation.
a. 4-bit parallel adder using combinational circuits.b. Up/Down counter using JK flip flop.c. Decade counter using 7490.d. Up/Down counter using 7493.e. Multiplexer/Demultiplexer.f. Encoder/Decoder.
Recommended Books:
Digital Electronics Theory and Experiments - Virendra Kumar - New age Internationalpublishers.
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of Science, Humanities And Commerce, SainikpuriAutonomous College I Affiliated to Osmania University
Accredited with 'A' Grade by NAACSyllabus - B Sc III Year Electronics
(To be implemented for the students joined in 2019-20)wef the academic yearz 2021-22
Semester V - Elective CourseCourse Name: 8085 Microprocessor Course Code: EL 524A
(45 Hours)
HPW: 3 CRBDITS: 3
Course Objectives:This course aims to-
COB l: Familiarize students with the composition of a Central Processing Unit.COB2: Become familiar with the term.s - Arithmetic Logic Unit, Control Unit, Registers, Bus, Von
Neumann & Harvard architecture.
COB3: Illustrate the architecture of 8085 pP.
COB4: Develop skills in writing simple programs and interfacing of microprocessors withvarious modules.
COB5. Provide ^strongfoundation.for de.signing real world application.s using microprocessors.
Unit 1 (10)
8085 architecture: Introduction to microcomputer and microprocessor, Memory organization;Intel 8085 Microprocessor, central processing unit (CPU), arithmetic and logic unit (ALU),timing and control unit. register organization, address, data and control buses, pin configuration of8085 and its description.
Unit 2 (13)
Programming 8085: Instruction set of 8085, instruction and data formats- classification ofinstructions -addressing modes. Assembly language programming examples of 8 and l6 bitaddition, subtraction, multiplication and division. Finding the largest and smallest in a data array,arranging the data in ascending / descending order.
Unit 3 (10)
Counter and Time Delays: Counters, Time Delays, Stack and Subroutines .
Interrupts: Software and hardware interrupts.Timing diagrams- Instruction cycle, machine cycle, fetch and execute cycles.
Unit 4 (r2)
Interfacing peripherals: Data transfer schemes, PPI (8255) - Modes - keyboard and display
Course Outcomes:Upon stx:ces.sfiil completion of' lhis course, .studen*will be altle to -
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Learn how the computer hardware ha.s evolved lo meet the needs of processing system.Define terms applicable to microprocessors, write programs using Assembly language.Understand the architecture and operation of Programmable Intedace Devices andinterface them with 8085 microprocessor.Work with microprocessor based equipment and be capable of participating in productdevelopment elforts, including.tupport and development of assembly language code.
Recommended books:
l. Microprocessor Architecture, Programming and Applications with the 8085 - Ramesh S.
Gaonkar. P e nr am Inte rnat io nal P ub I ic at io ns.
2. Fundamentals of Microprocessors & Microcomputers - B. Ram, Dhanpat RaiPublications.
3. Introduction to Microprocessors - Aditya P. Mathur. TMH.4. Theory and Problems of Microprocessor fundamentals - 2nd Edition Roger L, Tokheim,
Schaum's outline series, McGraw Hill.i. Microprocessors, Interfacing and Applications - R.Singh and B.P.Singh, New Age
1. Binary addition & subtraction.2. Multiplication & division.3. Decimal addition (DAA) & Subtraction.4. Using subroutines - zr value up to 5 decimal places5. Picking up largest/smallest number.6. Arranging -ascending/descending order.7. Time delay generation
MICROPROCESSOR (Ha rdware)
1. Interfacing of LED.2. Interfacing a seven segment display.
3. Interfacing a stepper motor and rotating it clockwise/anticlockwise through aknown angle.
Recommended books:
Microprocessor 8085 Architecture, Programming and Interfacing - Ajay Wadhwa
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BHAVAN'S VIVEKANANDA COLLEGEof Science, Humanities And Commerce, Sainikpuri
Autonomous College I Affiliated to Osmania UniversityAccredited with 'A' Grade by NAAC
Syllabus - B Sc III Year Electronics(To be implemented for the students joined in 2019-20)
Wef the academic year: 2021-22
Semester VI - Core Course
Course Name: 8051 Microcontroller Course Code: EL 624
(45 Hours)
HPW:3 CREDITS: 3
Course Objectives:
This course aims to-COBl: Learn what an embedded system is and to understand the need of microcontrollers in
embedded systems
COB2: Understand architecture andfeatures of 805I Microcontroller.COB3: Familiarize with Assembly Language Programming, Serial communication and
int e rfac ing t e c hni q ue s of I 0 5 I M ic ro c o nt ro I le r.
COB4: Master Programming and debugging skills.
Unit I (12)
Introduction to embedded systems and microcontroller, 8051 microcontroller, overview of 8051
family
Architecture of 8051: Block diagram of microcontroller, functions of each block, pin details of8051, ALU, ROM, RAM, memory organization of 8051, oscillator and clock, special functionregisters, program counter, PSW register, stack, I/O Ports , serial port, timers, interrupts.
Unit 2 (11)
Instruction set of 8051: Addressing modes of 8051, Instruction set of 8051, classification of8051 Instructions, data transfer instructions, arithmetic instructions, logical instructions,branching instructions. bit manipulation instructions, sirnple programs using these instructions.
Unit 3 (10)
Programs: Addition, Subtraction. Multiplication and Division. Largest Number/SmallestNumber, Ascending order/Descending order, BCD to HEX conversion, HEX to BCD Conversion,BCD to ASCII Conversion, subroutines, time delay routines
Unit 4 (12)
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Interfacing of peripherals to 8051 and applications: Serial communication, Interfacing ADC(ADC0804) - Temperature measurement, Interfacing DAC (DAC0808) - waveform generation,Interfacing LCD and displaying information, stepper motor interfacing.
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Course Outcomes:At the end of this course, students will be able to-
COl. Define terms applicable to microcontrollers.CO2: llrite programs using As.sembly language.CO3: Apply knowledge and demon,\tate programming proficiency using the various.
addres.sing modes and data lransfer instruction,s of the target microcontroller.
COI: Evaluate assembly language programs and download the machine code thot willprovide solutions to real-world control problems
Recommended Books:
l. 8051 Microcontroller and Embedded Systems using Assembly & C - Mazidi, Mazidi and D.McKinlay - Pearson Education.
2. 8051 Microcontroller by Kenneth J. Ayala - Cengage Learning India 3'd Edition.3. Microcontrollers, Principles and Applications - Ajit pal - PHI Ltd., - 201 1.
4. Microcontrollers, Theory and Applications - Ajay V. Deshmukh-TMH.5. Architecture, Programming, Interfacing and System Design - Raj Kamal - Pearson
Education.
[\^J.Dr. tVt- PRASAD
a.-ssoci ate P''ofe.ssor' -bePt' of PhYstcsoIil"i" UniversitY
l. Addition and subtraction on 2-byte numbers2. Multiplication using repeated addition and using MUL instruction3. Division using repeated subtraction and using DIV instruction4. Picking the smallesVlargest of a given set of numbers5. Sorting a given series of numbers in ascending/descending order6. Conversion from HEX to BCD7. Programming timer in model/28. Interfacing LEDs and flashing
9. Interfacing LCD
10. Interfacing DAC for waveform generationI l. Interfacing ADCI2. Interfacing stepper motor
Recommended Books:8051 Microcontroller -V Udayashankara, M S Mallikarjuna Swamy
of Science, Humanities And Commerce, SainikpuriAutonomous College I Affiliated to Osmania University
Accredited with 'A' Grade by NAACSyllabus- B Sc III Year Electronics
(To be implemented for the students joined in 2019-20)wef the academic year 2021-22
Semester VI - Elective CourseCourse Name: Digital System Design with VHDL Course Code: EL 624A
(45 Hours)
HPW:3 CREDITS: 3
Course Objective:This course aims to-
COBI: A hardware description language (HDL) for the specification, simulation, synthesis andimplementation of digital logic systems.
COB2: To identify the dffirences between behavioral and structural coding stylesCOB3: To write code targeting Xilinx devices specifically and FPGA devices in general.COB4: To opply the information gained to any digital design by using a top-down synthesisdesign approach.
Unit I (ll)
Introduction: Introduction to computer aided design tools for digital systems. Hardwaredescription languages; introduction to VHDL, data objects, classes and data types, Operators,
Overloading, logical operators. Types of delays, Entity and Architecture declaration. Introduction
to behavioral, dataflow and structural models.
Unit 2 (12)
VHDL Statements: Assignment statements, sequential statements and process, conditional
statements, case statement, Array and loops, resolution functions, Packages and Libraries,
concurrent statements. Subprograms: Application of Functions and Procedures, Structural
Modeling, component declaration, structural layout and generics.
Unit 3 (1 l)
Combinational Circuit Design: VHDL Models and Simulation of combinational circuits such as
Sequential Circuit Design: VHDL Models and Simulation of Sequential Circuits, Flip-flops -SR, D, JK and T; Shift Registers, Counters - 4 bit ripple and decade counter.
O>"-r-il-,*r- f\rtDr.'M. PRASAD
Associate ProfessorDept. of PhYsics
Osmania UniversitYHYderabacl - T.S
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Course Outcome:Upon succe.ssfil completion of this corm;e, .students will be able to-
COl: To learn the syntax and behavior of VHDL languageCO2: To use development tools to design digital circuits.CO3: To simulate and debug digital systems described in VHDLCO4: To synthesize .simple digital circuits in CPLD/FPGA
Recommended books:
l. VHDL- Primer by J Bhasker; PHI2. VHDL by Douglas L. Perry, Mc Graw Hill Publications.
3. Digital System Design using VHDL by Charles. H.Roth, PWS (1998).
4. VHDL-Analysis & Modeling of Digital Systems by Navabi Z; McGraw Hill.5. Logic and Computer Design Fundamentals,2/8, M. Morris Mano
6. Digital Electronics Laboratory Experiments Using the Xilinx XC95l08 CPLD with Xilinx
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Digital System Design with VHDL Practicals Course Code:EL 624AP(30 Hours-15 sessions)
(Using Behavioral, Structural and Data flow models)HPW: 2 CREDIT: I
