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IES Syllabus
« on: July 31, 2014, 04:16:39 pm »
Syllabus for Civil Engineering

Paper I

1. BUILDING MATERIALS
Timber: Different types and species of structural
timber, density-moisture relationship, strength
in different directions, defects, influence of
defects on permissible stress, preservation, dry
and wet rots, codal provisions for design,
Plywood.
Bricks: Types, Indian Standard classification,
absorption, saturation factor, strength in
masonry, influence of morter strength on
masonry strength.
Cement: Compounds of, different types, setting
times, strength.
Cement Mortar: Ingredients, proportions, water
demand, mortars for plastering and masonry.
Concrete: Importance of W/C Ratio, Strength,
ingredients including admixtures, workability,
testing for strength, elasticity, non-destructive
testing, mix design methods.

2. SOLID MECHANICS
Elastic constants, stress, plane stress, Mohrís
circle of stress, strains, plane strain, Mohrís
circle of strain, combined stress; Elastic theories
of failure; Simple bending, shear; Torsion of
circular and rectangular sections and simple
members.

3. STRUCTURAL ANALYSIS
Analysis of determinate structures - different
methods including graphical methods.
Analysis of indeterminate skeletal frames -
moment distribution, slope-deflection, stiffness
and force methods, energy methods, Muller-
Breslau principle and application.
Plastic analysis of indeterminate beams and
simple frames - shape factors.

4. DESIGN OF STEEL STRUCTURES
Principles of working stress method. Design of
connections, simple members, Built-up sections
and frames, Design of Industrial roofs.
Principles of ultimate load design. Design of
simple members and frames.

5.   DESIGN OF CONCRETE AND MASONRY STRUCTURES
Limit state design for bending, shear, axial
compression and combined forces. Codal
provisions for slabs, beams, walls and footings.
Working stress method of design of R.C.
members.
Principles of prestressed concrete design,
materials, methods of prestressing, losses.
Design of simple members and determinate
structures. Introductions to prestressing of
indeterminate structures.
Design of brick masonry as per I.S. Codes.

6. CONSTRUCTION PRACTICE, PLANNING AND
MANAGEMENT

Concreting Equipment:
Weight Batcher, Mixer, vibrator, batching plant,
concrete pump.
Cranes, hoists, lifting equipment.
Earthwork Equipment:
Power shovel, hoe, dozer, dumper, trailers and
tractor, rollers, sheep foot rollers, pumps.
Construction, Planning and Management:
Bar chart, linked bar chart, work-break down
structures, Activity - on - arrow diagrams.
Critical path, probabilistic Activity durations;
Event-based networks.
PERT network: Time-cost study, crashing;
Resource allocation.


Paper II

1 A. FLUID MECHANICS, OPEN CHANNEL FLOW,
PIPE FLOW

Fluid Properties, Pressure, Thrust, Buoyancy;
Flow Kinematics; Integration of flow equations;
Flow measurement; Relative motion; Moment of
momentum; Viscosity, Boundary layer and
Control, Drag, Lift; dimensional Analysis,
Modelling; Cavitation; Flow oscillations;
Momentum and Energy principles in Open
channel flow, Flow controls, Hydraulic jump,
Flow sections and properties; Normal flow,
Gradually varied flow; Surges; Flow development
and losses in pipe flows, Measurements; Siphons;
Surges and Water hammer; Delivery of Power
Pipe networks.

1 B. HYDRAULIC MACHINES AND HYDROPOWER
Centrifugal pumps, types, performance
parameters, scaling, pumps in parallel;
Reciprocating pumps, air vessels, performance
parameters; Hydraulic ram; Hydraulic turbines,
types, performance parameters, controls,
choice; Power house, classification and layout,
storage, pondage, control of supply.

2 A. HYDROLOGY
Hydrological cycle, precipitation and related
data analyses, PMP, unit and synthetic
hydrographs; Evaporation and transpiration;
Floods and their management, PMF; Streams
and their gauging; River morphology; Routing of
floods; Capacity of Reservoirs.

2 B. WATER RESOURCES ENGINEERING
Water resources of the globe: Multipurpose uses
of Water: Soil-Plant-Water relationships,
irrigation systems, water demand assessment;
Storages and their yields, ground water yield
and well hydraulics; Waterlogging, drainage
design; Irrigation revenue; Design of rigid
boundary canals, Laceyís and Tractive force
concepts in canal design, lining of canals;
Sediment transport in canals; Non-Overflow and
overflow sections of gravity dams and their
design, Energy dissipators and tailwater rating;
Design of headworks, distribution works, falls,
cross-drainage works, outlets; River training.

ENVIRONMENTAL ENGINEERING

3 A. WATER SUPPLY ENGINEERING
Sources of supply, yields, design of intakes and
conductors; Estimation of demand; Water
quality standards; Control of Water-borne
diseases; Primary and secondary treatment,
detailing and maintenance of treatment units;
Conveyance and distribution systems of treated
water, leakages and control; Rural water supply;
Institutional and industrial water supply.

3 B. WASTE WATER ENGINEERING
Urban rain water disposal; Systems of sewage
collection and disposal; Design of sewers and
sewerage systems; pumping; Characteristics of
sewage and its treatment, Disposal of products
of sewage treatment, streamflow rejuvenation
Institutional and industrial sewage
management; Plumbing Systems; Rural and
semi-urban sanitation.

3 C. SOLID WASTE MANAGEMENT
Sources, classification, collection and disposal;
Design and Management of landfills.

3 D. AIR AND NOISE POLLUTION AND ECOLOGY
Sources and effects of air pollution, monitoring
of air pollution; Noise pollution and standards;
Ecological chain and balance, Environmental
assessment.

4 A. SOIL MECHANICS
Properties of soils, classification and
interrelationship; Compaction behaviour,
methods of compaction and their choice;
Permeability and seepage, flow nets, Inverted
filters; Compressibility and consolidation;
Shearing resistance, stresses and failure; soil
testing in laboratory and in-situ; Stress path
and applications; Earth pressure theories, stress
distribution in soil; soil exploration, samplers,
load tests, penetration tests.

4 B. FOUNDATION ENGINEERING
Types of foundations, Selection criteria, bearing
capacity, settlement, laboratory and field tests;
Types of piles and their design and layout,
Foundations on expansive soils, swelling and its
prevention, foundation on swelling soils.

5 A. SURVEYING
Classification of surveys, scales, accuracy;
Measurement of distances - direct and indirect
methods; optical and electronic devices;
Measurement of directions, prismatic compass,
local attraction; Theodolites - types;
Measurement of elevations - Spirit and
trigonometric levelling; Relief representation;
Contours; Digital elevation modelling concept;
Establishment of control by triangulations and
traversing - measurements and adjustment of
observations, computation of coordinates; Field
astronomy, Concept of global positioning system;
Map preparation by plane tabling and by
photogrammetry; Remote sensing concepts, map
substitutes.

5 B. TRANSPORTATION ENGINEERING
Planning of highway systems, alignment and
geometric design, horizontal and vertical curves,
grade separation; Materials and construction
methods for different surfaces and
maintenance: Principles of pavement design;
Drainage.

Traffic surveys, Intersections, signalling: Mass
transit systems, accessibility, networking.
Tunnelling, alignment, methods of construction,
disposal of muck, drainage, lighting and
ventilation, traffic control, emergency
management.

Planning of railway systems, terminology and
designs, relating to gauge, track, controls,
transits, rolling stock, tractive power and track
modernisation; Maintenance; Appurtenant
works; Containerisation.

Harbours - layouts, shipping lanes, anchoring,
location identification; Littoral transport with
erosion and deposition; sounding methods; Dry
and Wet docks, components and operational
Tidal data and analyses.

Airports - layout and orientation; Runway and
taxiway design and drainage management;
Zoning laws; Visual aids and air traffic control;
Helipads, hangers, service equipment.
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Re: IES Syllabus
« Reply #1 on: July 31, 2014, 04:25:28 pm »
Syllabus for Mechanical Engineering

Paper I

1. THERMODYNAMICS
Cycles and IC Engines, Basic concepts, Open and
Closed systems. Heat and work. Zeroth, First
and Second Law, Application to non-Flow and
Flow processes. Entropy, Availability,
Irreversibility and Tds relations. Claperyron and
real gas equations, Properties of ideal gases
and vapours. Standard vapour, Gas power and
Refrigeration cycles. Two stage compressor. C-I
and S.I. Engines. Pre-ignition, Detonation and
Diesel-knock, Fuel injection and Carburation,
Supercharging. Turbo-prop and Rocket engines,
Engine Cooling, Emission & Control, Flue gas
analysis, Measurement of Calorific values.
Conventional and Nuclear fuels, Elements of
Nuclear power production.

2. REFRIGERATION AND AIR CONDITIOINING
Modes of heat transfer. One dimensional steady
and unsteady conduction. Composite slab and
Equivalent Resistance. Heat dissipation from
extended surfaces, Heat exchangers, Overall
heat transfer coefficient, Empirical correlations
for heat transfer in laminar and turbulent
flows and for free and forced Convection,
Thermal boundary layer over a flat plate.
Fundamentals of diffusive and connective mass
transfer, Black body and basic concepts in
Radiation, Enclosure theory, Shape factor, Net
work analysis. Heat pump and Refrigeration
cycles and systems, Refrigerants. Condensers,
Evaporates and Expansion devices,
Psychrometry, Charts and application to air
conditioning, Sensible heating and cooling,
Effective temperature, comfort indices, Load
calculations, Solar refrigeration, controls, Duct
design.

3. FLUID MECHANICS
Properties and classification of fluids,
Manometry, forces on immersed surfaces, Center
of pressure, Buoyancy, Elements of stability of
floating bodies. Kinematics and Dynamics.
Irrotational and incompressible. Inviscid flow.
Velocity potential, Pressure field and Forces on
immersed bodies. Bernoulliís equation, Fully
developed flow through pipes, Pressure drop
calculations, Measurement of flow rate and
Pressure drop. Elements of boundary layer
theory, Integral approach, Laminar and
tubulent flows, Separations. Flow over weirs and
notches. Open channel flow, Hydraulic jump.
Dimensionless numbers, Dimensional analysis,
Similitude and modelling. One-dimensional
isentropic flow, Normal shock wave, Flow through
convergent - divergent ducts, Oblique shock-
wave, Rayleigh and Fanno lines.

4. FLUID MACHINERY AND STEAM GENERATORS
Performance, Operation and control of
hydraulic Pump and impulse and reaction
Turbines, Specific speed, Classification. Energy
transfer, Coupling, Power transmission, Steam
generators Fire-tube and water-tube boilers.
Flow of steam through Nozzles and Diffusers,
Wetness and condensation. Various types of
steam and gas Turbines, Velocity diagrams.
Partial admission. Reciprocating, Centrifugal
and axial flow Compressors, Multistage
compression, role of Mach Number, Reheat,
Regeneration, Efficiency, Governance.


Paper II

1. THEORY OF MACHINES
Kinematic and dynamic analysis of planer
mechanisms. Cams. Gears and gear trains.
Flywheels. Governors. Balancing of rigid rotors
and field balancing. Balancing of single and
multicylinder engines, Linear vibration analysis
of mechanical systems. Critical speeds and
whirling of shafts Automatic controls.

2. MACHINE DESIGN
Design of Joints : cotters, keys, splines, welded
joints, threaded fasteners, joints formed by
interference fits. Design of friction drives :
couplings and clutches, belt and chain drives,
power screws.

Design of Power transmission systems : gears and
gear drives shaft and axle, wire ropes.
Design of bearings : hydrodynamics bearings
and rolling element bearings.

3. STRENGTH OF MATERIALS
Stress and strain in two dimensions, Principal
stresses and strains, Mohrís construction, linear
elastic materials, isotropy and anisotropy,
stress-strain relations, uniaxial loading,
thermal stresses. Beams : Bending moment and
shear force diagram, bending stresses and
deflection of beams. Shear stress distribution.
Torsion of shafts, helical springs. Combined
stresses, thick-and thin-walled pressure vessels.
Struts and columns. Strain energy concepts and
theories of failure.

4. ENGINEERING MATERIALS
Basic concepts on structure of solids. Crystalline
maferials. Detects in crystalline materials. Alloys
and binary phase diagrams. Structure and
properties of common engineering materials.
Heat treatment of steels. Plastics, Ceramics and
composite materials. Common applications of
various materials.

5. PRODUCTION ENGINEERING
Metal Forming : Basic Principles of forging,
drawing and extrusion; High energy rate
forming; Powder metallurgy.
Metal Casting : Die casting, investment casting,
Shall Moulding, Centrifugal Casting, Gating &
Riser design; melting furnaces.

Fabrication Processes : Principles of Gas, Arc,
Shielded arc Welding; Advanced Welding
Processes, Weldability: Metallurgy of Welding.
Metal Cutting : Turning, Methods of Screw
Production, Drilling, Boring, Milling, Gear
Manufacturing, Production of flat surfaces,
Grinding & Finishing Processes. Computer
Controlled Manufacturing Systems-CNC, DNC,
FMS, Automation and Robotics.
Cutting Tools Materials, Tool Geometry,
Mechanism of Tool Wear, Tool Life &
Machinability; Measurement of cutting forces.
Economics of Machining. Unconventional
Machining Processes. Jigs and Fixtures. Fits and
tolerances, Measurement of surface texture,
Comparators Alignment tests and reconditioning
of Machine Tools.

6. INDUSTRIAL ENGINEERING
Production Planning and Control : Forecasting -
Moving average, exponential smoothing,
Operations, scheduling; assembly line balancing,
Product development, Break-even analysis,
Capacity planning, PERT and CPM.
Control Operations : Inventory control ABC
analysis, EOQ model, Materials requirement
planning. Job design, Job standards, Work
measurement, Quality Management - Quality
analysis and control. Operations Research :
Linear Programming - Graphical and Simplex
methods, Transportation and assignment
models. Single server queueing model.
Value Engineering : Value analysis for cost/
value.

7. ELEMENTS OF COMPUTATION
Computer Organisation, Flow charting, Features
of Common computer Languages - FORTRAN, d
Base III, Lotus 1-2-3, C and elementary
Programming.

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Re: IES Syllabus
« Reply #2 on: July 31, 2014, 10:00:45 pm »
Syllabus for Electrical Engineering

Paper I

1. EM Theory
Electric and magnetic fields. Gaussís Law and
Amperes Law. Fields in dielectrics, conductors
and magnetic materials. Maxwellís equations.
Time varying fields. Plane-Wave propagating in
dielectric and conducting media. Transmission
lines.

2. ELECTRICAL MATERIALS
Band Theory, Conductors, Semi-conductors and
Insulators. Super-conductivity. Insulators for
electrical and electronic applications. Magnetic
materials. Ferro and ferri magnetism. Ceramics,
Properties and applications. Hall effect and its
applications. Special semi conductors.

3. ELECTRICAL CIRCUITS
Circuits elements. Kirchoffís Laws. Mesh and
nodal analysis. Network Theorems and
applications. Natural response and forced
response. Transient response and steady state
response for arbitrary inputs. Properties of
networks in terms of poles and zeros. Transfer
function. Resonant circuits. Threephase circuits.
Two-port networks. Elements of two-element
network synthesis.

4. MEASUREMENTS AND INSTRUMENTATION
Units and Standards. Error analysis,
measurement of current, Voltage, power, Power-
factor and energy. Indicating instruments.
Measurement of resistance, inductance,
Capacitance and frequency. Bridge
measurements. Electronic measuring
instruments. Digital Voltmeter and frequency
counter. Transducers and their applications to
the measurement of non-electrical quantities
like temperature, pressure, flow-rate
displacement, acceleration, noise level etc. Data
acquisition systems. A/D and D/A converters.

5. CONTROL SYSTEMS
Mathematical modeling of physical systems.
Block diagrams and signal flow graphs and their
reduction. Time domain and frequency domain
analysis of linear dynamical system. Errors for
different type of inputs and stability criteria
for feedback systems. Stability analysis using
Routh-Hurwitz array, Nyquist plot and Bode
plot. Root locus and Nicols chart and the
estimation of gain and phase margin. Basic
concepts of compensator design. State variable
matrix and its use in system modelling and
design. Sampled data system and performance
of such a system with the samples in the error
channel. Stability of Sampled data system.
Elements of non-linear control analysis. Control
system components, electromechanical,
hydraulic, pneumatic components.


Paper II

1. ELECTRCIAL MACHINES AND POWER
TRANSFORMERS

Magnetic Circuits - Analysis and Design of Power
transformers. Construction and testing.
Equivalent circuits. Losses and efficiency.
Regulation. Auto-transformer, 3-phase
transformer. Parallel operation.
Basic concepts in rotating machines. EMF,
torque, Basic machine types. Construction and
operation, leakage losses and efficiency.

B.C. Machines. Construction, Excitation methods.
Circuit models. Armature reaction and
commutation. Characteristics and performance
analysis. Generators and motors. Starting and
speed control. Testing, Losses and efficiency.
Synchronous Machines. Construction. Circuit
model. Operating characteristics and
performance analysis. Synchronous reactance.
Efficiency. Voltage regulation. Salient-pole
machine, Parallel operation. Hunting. Short
circuit transients.

Induction Machines. Construction. Principle of
operation. Rotating fields. Characteristics and
performance analysis. Determination of circuit
model. Circle diagram. Starting and speed
control.

Fractional KW motors. Single-phase synchronous
and induction motors.

2. POWER SYSTEMS
Types of Power Stations, Hydro, Thermal and
Nuclear Stations. Pumped storage plants.
Economics and operating factors.
Power transmission lines. Modeling and
performance characteristics. Voltage control.
Load flow studies. Optimal power system
operation. Load frequency control. Symmetrical
short circuit analysis. ZBus formulation.
Symmetrical Components. Per Unit
representation. Fault analysis. Transient and
steady-state stability of power systems. Equal
area criterion.

Power system Transients. Power system Protection
Circuit breakers. Relays. HVDC transmission.

3. ANALOG AND DIGITAL ELECTRONICS AND
CIRCUITS

Semiconductor device physics, PN junctions and
transistors, circuit models and parameters, FET,
Zener, tunnel, Schottky, photo diodes and their
applications, rectifier circuits, voltage
regulators and multipliers, switching behavior of
diodes and transistors.

Small signal amplifiers, biasing circuits,
frequency response and improvement, multistage
amplifiers and feed-back amplifiers, D.C.
amplifiers, Oscillators. Large signal amplifiers,
coupling methods, push pull amplifiers,
operational amplifiers, wave shaping circuits.
Multivibrators and flip-flops and their
applications. Digital logic gate families,
universal gates-combination circuits for
arithmetic and logic operational, sequential
logic circuits. Counters, registers, RAM and
ROMs.

4. MICROPROCESSORS
Microprocessor architecture-Instruction set and
simple assembly language programming.
Interfacing for memory and I/O. Applications
of Micro-processors in power system.

5. COMMUNICATION SYSTEMS
Types of modulation; AM, FM and PM.
Demodulators. Noise and bandwidth
considerations. Digital communication systems.
Pulse code modulation and demodulation.
Elements of sound and vision broadcasting.
Carrier communication. Frequency division and
time division multiplexing, Telemetry system in
power engineering.

6. POWER ELECTRONICS
Power Semiconductor devices. Thyristor. Power
transistor, GTOs and MOSFETS. Characteristics
and operation. AC to DC Converters; 1-phase
and 3-phase DC to DC Converters; AC regulators.
Thyristor controlled reactors; switched capacitor
networks.

Inverters; single-phase and 3-phase. Pulse
width modulation. Sinusoidal modulation with
uniform sampling. Switched mode power supplies.

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Re: IES Syllabus
« Reply #3 on: July 31, 2014, 10:24:10 pm »
Syllabus for Electronics and Telecommunication Engineering

Paper I
1. MATERIALS AND COMPONENTS
Structure and properties of Electrical
Engineering materials; Conductors,
Semiconductors and Insulators, magnetic,
Ferroelectric, Piezoelectric, Ceramic, Optical and
Super-conducting materials. Passive components
and characteristics Resistors, Capacitors and
Inductors; Ferrites, Quartz crystal Ceramic
resonators, Electromagnetic and
Electromechanical components.

2. PHYSICAL ELECTRONICS, ELECTRON DEVICES AND
ICs

Electrons and holes in semiconductors, Carrier
Statistics, Mechanism of current flow in a
semiconductor, Hall effect; Junction theory;
Different types of diodes and their
characteristics; Bipolar Junction transistor;
Field effect transistors; Power switching devices
like SCRs, GTOs, power MOSFETS; Basics of ICs -
bipolar, MOS and CMOS types; basic of Opto
Electronics.

3. SIGNALS AND SYSTEMS
Classification of signals and systems: System
modelling in terms of differential and
difference equations; State variable
representation; Fourier series; Fourier
transforms and their application to system
analysis; Laplace transforms and their
application to system analysis; Convolution and
superposition integrals and their applications;
Z-transforms and their applications to the
analysis and characterisation of discrete time
systems; Random signals and probability,
Correlation functions; Spectral density; Response
of linear system to random inputs.

4. NETWORK THEORY
Network analysis techniques; Network theorems,
transient response, steady state sinusoidal
response; Network graphs and their applications
in network analysis; Tellegenís theorem. Two port
networks; Z, Y, h and transmission parameters.
Combination of two ports, analysis of common
two ports. Network functions : parts of network
functions, obtaining a network function from a
given part. Transmission criteria : delay and
rise time, Elmoreís and other definitions effect
of cascading. Elements of network synthesis.

5. ELECTROMAGNETIC THEORY
Analysis of electrostatic and magnetostatic
fields; Laplaceís and Poissonís equations;
Boundary value problems and their solutions;
Maxwellís equations; application to wave
propagation in bounded and unbounded media;
Transmission lines : basic theory, standing
waves, matching applications, microstrip lines;
Basics of wave guides and resonators; Elements
of antenna theory.

6. ELECTRONIC MEASUREMENTS AND
INSTRUMENTATION

Basic concepts, standards and error analysis;
Measurements of basic electrical quantities and
parameters; Electronic measuring instruments
and their principles of working : analog and
digital, comparison, characteristics, application.
Transducers; Electronic measurements of non
electrical quantities like temperature, pressure,
humidity etc; basics of telemetry for industrial
use.


Paper II

1. ANALOG ELECTRONIC CIRCUITS
Transistor biasing and stabilization. Small signal
analysis. Power amplifiers. Frequency response.
Wide banding techniques. Feedback amplifiers.
Tuned amplifiers. Oscillators. Rectifiers and
power supplies. Op Amp, PLL, other linear
integrated circuits and applications. Pulse
shaping circuits and waveform generators.

2. DIGITAL ELECTRONIC CIRCUITS
Transistor as a switching element; Boolean
algebra, simplification of Boolean functions,
Karnaguh map and applications; IC Logic gates
and their characteristics; IC logic families : DTL,
TTL, ECL, NMOS, PMOS and CMOS gates and their
comparison; Combinational logic Circuits; Half
adder, Full adder; Digital comparator;
Multiplexer Demulti-plexer; ROM an their
applications. Flip flops. R-S, J-K, D and T flip-
flops; Different types of counters and registers
Waveform generators. A/D and D/A converters.
Semiconductor memories.

3. CONTROL SYSTEMS
Transient and steady state response of control
systems; Effect of feedback on stability and
sensitivity; Root locus techniques; Frequency
response analysis. Concepts of gain and phase
margins: Constant-M and Constant-N Nicholís
Chart; Approximation of transient response
from Constant-N Nicholís Chart; Approximation
of transient response from closed loop frequency
response; Design of Control Systems,
Compensators; Industrial controllers.

4. COMMUNICATIONS SYSTEMS
Basic information theory; Modulation and
detection in analogue and digital systems;
Sampling and data reconstructions;
Quantization & coding; Time division and
frequency division multiplexing; Equalization;
Optical Communication : in free space & fiber
optic; Propagation of signals at HF, VHF, UHF
and microwave frequency; Satellite
Communication.

5. MICROWAVE ENGINEERING
Microwave Tubes and solid state devices,
Microwave generation and amplifiers,
Waveguides and other Microwave Components
and Circuits, Microstrip circuits, Microwave
Antennas, Microwave Measurements, Masers,
lasers; Microwave propagation.
Microwave Communication Systems terrestrial
and Satellite based.

6. COMPUTER ENGINEERING
Number Systems. Data representation;
Programming; Elements of a high level
programming language PASCAL/C; Use of basic
data structures; Fundamentals of computer
architecture; Processor design; Control unit
design; Memory organisation, I/o System
Organisation. Microprocessors : Architecture and
instruction set of Microprocessors 8085 and 8086,
Assembly language Programming. Microprocessor
Based system design : typical examples. Personal
computers and their typical uses.

 

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