Mathematics – 1 (2-2-0-3):
Determinants: Its properties, Cramer’s rule; Matrices, solution of System of linear equations, infinite series, convergence and divergence of infinite series; Vector Algebra :

Basic concepts, dot product, cross product, triple product, Complex numbers, De – Moivres theorem. Three dimensional geometric equations of planes and lines.

Mathematics – 2 (2-2-0-3):
Differential Calculus: Higher derivatives & Leibniz theorem, Expansion of functions, Taylor s and Maclaurin,s series, indeterminate forms. Partial Derivatives, curvature and evolutes. Integral Calculus: Multiple integrals, double & triple integrals.Differential equation: Ordinary differential equations, various methods of Solving first order differential equations and its applications
Physics – 1 (2-0-2-3):
Vectors: (4h) Scalar and vector quantities, Addition of vectors components of vectors, scalar product,, vector product Applications. Dynamics of Bodies : (4h) Displacement , velocity and acceleration , laws of motion , theacceleration of gravity , free fall projectile
, Newton’s first law , mass and weight , force , Newton’s second law , Newton’s third law linear momentum . Impulse , conservation of linear momentum collisions . Energy: (2h) Work, work done against gravity, power, energy, KE, PE. Conservation of energy. Circular and S. H. M.: (4h) Angular displacement, angular velocity, angular acceleration Centripetal force, centripetal accel. Angular momentum, Torque, rotational KE. , gravitation. Elastic PE. S .H. M. Velocity and accel, in S. H. M., simple pendulum. Fluids (4h) Pressure, atmospheric pressure, density surface tension, fluid flow, Bernoulli’s Equation. Mechanical properties of matter: (2h) Elasticity, stress and strain, young’s Modulus Shear and Bulk modulus. Geometrical Optics (4h) Reflection and refraction, mirrors and lenses. Temperatureand Heat: (4h) temp. Thermometers, mechanical equivalent of heat, specific heat capacity change of state, Boyle’s law, Charlie’s law, ideal gas law. K. Theory of gases, heat transfe

Introduction to Computer (2-0-2-3):
Nature of computers, types and evolution. Internal organization and functions, I/O units, storage devices and CPU. Data representation and of computer software functions, operating systems, application softwares. Programming languages, algorithms. Fundamental programming concepts with applications.

Engineering Drawing (2-0-3-3)
Introduction and general instruction regarding lettering instruments and line work. Free hand sketching. Plane geometric constructions. Projection systems-perspective orthographic, axonometric, isometric and oblique Projections. First angle, third angle projections. Orthographic and pictorial view. Projections of various objects and auxiliary planes

Electronic Engineering Material (2-1-0-2)
Structure of matter. Atomic Bonding. Energy Levels and Bonds. Crystal structure; Conductor,
Semiconductors and Insulator. Properties of Conducting, Semiconductors materials and

Insulator materials; Opto electrical properties. Magnetic materials; Para-and Ferro magnetism;
Ferrites and Their applications. Dielectric materials; Dielectric Properties of Solids. Ionic conductivity; Dielectric . Introduction to fiber optical materials.
Physics 2 (2-0-2-3):
waves :Wave motion , pulses in string , principle of super position periodic Waves , equation of wane , Beats , Doppler effect , sound intensity , frequency types of waves , standing waves , resonance sound ,response . Electromagnetic waves. electricity: electric charge , coulombs law , electricity and matter , electrical conduction , electric field , lines of force , gauss’s law , electric pot . Energy. Potential diff. , electron volts electric current , ohm’s law . resistively , conductivity , electric power . Resistors. E. M. F. kirchhoffs rules . capacitances , magnetic forces . Electromagnetic induction , faraday’s law , Ammp. And voltmeter, heat effect of an electric current. Atomic structure:bohr model of hydrogen atom , energy levels , atomic spectra , excitation and ionization energy . Conductors and free electrons solids and liquids, crystalline and non crystalline maternal, crystal bonds, energy bands, conduction, semiconductors and insulators, crystal defects. Physics of semiconductors: Electron emission, cathode ray tube, properties of C. R. electron motion in elec. And mag. Fields, photo-electric effect, semiconductors, intrinsic and extrinsic semiconductors. P-N junction diode, rectification circuits, transistors.
Circuit Theory 1 (3-0-2-4)
Circuit elements; Independent and depended sources; Series Resistive Circuits; Applications of Kirchhoffs Voltage Law (KVL) & Voltage Divider Rule (VDR); Parallel Resistive Circuits;
Applications of Kirchhoffs Current Law (KCL) & Current Divider Rule (CDR); Series- Parallel
Circuits; Applications; Network Analysis by Direct Methods: Current Loop Analysis; Nodal Voltage Analysis;
Superposition theorem; Network Analysis by Equivalent Circuit Methods: Star delta conversions; Thevenin`s and Norton`s theorems; Maximum power transfer theorem; DC Capacitive Circuits; DC Inductive Circuits; Calculations for RC, RL, and RLC Circuits; Transient and steady state response of networks for different excitations. Two port network parameters, h, y, and z. Introduction to AC basic circuits.

Logic Design (3-0-2-4):Digital System and Binary Numbers (Number Base conversion, Octaland Hexadecimal, Complement, Signed Binary Numbers, Binary codes, gray code & ASCII code). Boolean Algebra and Logic Gates: ( Introduction, Definition of Boolean Algebra, Basic Theorems and properties of Boolean Algebra, Basic Gates (NOT, AND, OR),NAND,NOR, X-OR and XNOR, Boolean Functions, Digital Logic gates, Integrated Circuits). Gate-Level Minimization:
(Introduction, The Map Method ( Karnaugh Map), Sum of Product Simplification, Product of Sum Simplification, NAND and NOR Implementation). Combinational Logic: ( Introduction,
Combinational Circuits, Analysis Procedure, Design Procedure, Half Adder, Full Adder, Binary Adder-Substractor, Incrementor-Decrementor, Binary Multiplier, Comparators IncrementorDecrementor, Binary Multiplier, Comparators, Decoder, Encoder, Multiplexer, De Multiplexer). Synchronous Sequential Logic: (Introduction, Sequential

Circuits, Storage Elements, Latches RS Flip-Flops, JK Flip-Flops, D Flip-Flops, T Flip- Flops, Analysis of Clocked Sequential Circuits).
Registers and Counters: (Registers, Shift registers, ASynchronous (Ripple) Counters, Synchronous Counters, Other Counters)
.

Mathematics – 3 (2-2-0-3):Laplace Transforms: Laplace transforms of standard functions, inverse Transforms, convolutes, solution of differential equations, laplace transform of periodic functions. Partial Differential Equations: formation, solution of linear equation of first Order, homogeneous linear equations with constant coefficients, solution of Lablace equation. Probability: Basic concepts of probability theory, random variables, and Discrete and continuous distribution. Bays s theorem, moments and moments generating functions, joint probability distribution and correlation.

Computer programming C- language (2-0-2-3):Introduction to C programming language, Structure of program; include section, define section, main function, print statement, scan statement, cout statement, cin statement, variables declaration, variable types, simple arithmetic
Expressions, simple logic Expressions, if statement. More logical Expression and the operators &&, ||and!, Nested IF statement, Formatting numbers in program outputs. Repetition in programs: for loop, while do loop, do while loop, nested control structure.
Arrays, Declaring
and Referencing Arrays, Using character arrays as string. Sub programs in C: function Declaration, Function Implementation

Electronic Devices (2-1-2-3):
Introduction to physics of semiconductors; Bipolar Devices: pn junction theory, p-n junction Introduction to physics of semiconductors. Bipolar Devices. PN junction theory. PN junction diode. Bipolar junction transistor. Unipolar Devices. Junction field effect transistor.(JFET). Metal insulator semiconductor.(MIS).Diode charge coupled devices(CDD). Metal oxide semiconductor FET(MOSFET). Photonic devices light emitting diode.(LED). Semiconductor lasers and photo-detectors.
Electronic Circuits (2-1-2-3):
This course is designed to provide students with fundamental concepts of Electronic Circuits . It includes Diode circuits, transistor biasing and thermal stabilization , Transistor equivalent circuit and models , small signal bipolar (BJT) and Field Effect (FET) amplifiers,. Single-stage and multi-stage amplifiers. Feedback amplifiers. Frequency response of amplifiers. Power amplifiers. Oscillators. Tuned amplifiers. Application of simulation tools (PSPICE or Multisim) to understand the circuit characteristics.

Circuit Theory – 2 (3-1-2-4):Alternating Voltage and Current Circuits: Waveforms: magnitude, cycle, period, frequency, and wavelength values; the importance of the sine wave; Sine wave values; Phases and Phasors: phasor diagram, polar and rectangular presentation, phasor arithmetic, impedance and admittance; Single Phase R, L, and C AC circuits; Series RC, RL circuits; Parallel RC, RL circuits; RLC Series circuits; RLC Parallel circuits; RLC Series Parallel circuits; RLC circuits conversion; Resonant Circuits: Series RLC resonant circuits, Parallel RLC resonant circuits, Applications of resonance;

Filters (RC Low, High and Pass Band Filters); Fourier Series; Coupled Circuits: Two-port network parameters, with h, y, and z parameters; Applications:The transformer ,transistor as a two-port network; characterization of multi-port networks, Synthesis of one/ two port network.

Mathematics – 4 (2-2-0-3):Complex variables: Functions of complex variables, Differentiation, Analytical functions, Harmonic functions, Complex integration, Cauchy Theorem, Cauchy s integral formula, Taylor s series, Laurent s theorem, theorem, contour integration of real functions. Fourier series Fourier expansions of various functions in given intervals, Euler s formula, odd and even functions, Half range series, typical Waveforms, and harmonic analysis. Vector Calculus: vector differentiation, scalar and vector point functions, Del applied to point functions, gradient, divergence and curl, vector Integration, Green s theorem in a plan, Stokcs s theorem and divergence Theorem, orthogonal curvilinear coordinates, spherical and cylindrical polar coordinates. Special Functions: Gamma and Beta functions, solution of differential Equations in series, solution of Bessel s function, recurrence formula for Jn(x), solution of Legendary s equation. Statistics: Functions of random variables, calculus of probability, regression Analyses. Random sampling, random numbers, estimation of parameters, confidence intervals.

Data Structures and Algorithms (2-1-2-3):Structured programming concept and methodology- modular programs, information hiding. Data abstraction; sets, stacks, queues.
Pointers, linked list, tree Manipulation. Typed / untyped field manipulations. Sorting and searching. Recursivity.
Electrical Machines (2-1-2-3):This course covers three main topics (Transformers, Generators and Motors): The Transformers (Types, construction, operation, equivalent circuit, efficiency, voltage regulation and three phase transformers), DC machines(Construction, performance, equivalent circuit, Generators and motors characteristics, starting, speed control), Induction machines(Construction, 3-phase motors, types, operation, equivalent circuit, starting, speed control), Synchronous machines(Construction, generator performance, motor characteristics,
starting), Small machines (Single phase motors, control motors, tacho-generators).

Signals and Systems (3-1-0-3)
The course presents and integrates the basic concepts for both continuous-time and discrete-time signals and systems. It is an introduction to analog and digital signal processing, control systems and communication systems and digital image processing. Some knowledge in fundamental calculus and use of complex numbers is a pre-requisite for this course. Signal and system representations are developed for both time and frequency domains. It covers linear time-invariant systems: system properties, impulse response, input-output difference and differential equations, convolution sum and the convolution integral representation. These representations are related through the Laplace Transform, Fourier series and Fourier transform with their properties. The course includes an introduction to MATLAB as a tool for signal analysis and system modeling.

course includes
Digital Electronics (2-1-2-3):
This course will introduce how the implementation, analysis, and design build of logic gates including DL, RTL, DTL, CMOS, TTL, ECL with MOSFETs and BJTs.
This course will cover various IC. logic families, including diode logic (DL), resistor- transistor logic (RTL),diode-transistor logic (DTL), diode transistor-transistor logic (TTL), emitter-coupled logic (ECL), NMOS, PMOS, and CMOS logic. In addition, various other circuits used in digital world will be covered. These include analog to digital and digital to analog converters, Schmitttriggers, Semiconductor memories and Sample and Hold circuit. Microprocessors (3-1-2-4):
Introduction to Microprocessor and Computer. History of Intel Microprocessors. Internal architecture of 8088/86 Microprocessors. Addressing modes. Data movement instructions. Arithmetic & Logic instructions. Program control instructions. Programming microprocessor. Machine Encoding. 8088/86 hardware specifications and bus timing. Memory Interface. Basic input/output interface. Interfacing with display and printer. Interrupts. Bus interface.

Control Systems (3-1-2-4):
This course covers theclassification and basic Concepts of Control Systems, Laplacetransformation Mathematical models of systems, Transfer functions, Block diagrams and signal flow graph, Time domain responses analysis, steady state errors and error constants, Stability analysis (Routh-Hurwitz criterion, Root Locus Technique), PID Controller, Frequency domain response analysis,Stability in Frequency Domain,Design of Control Systems,State variable techniques. Solution of control problems of control engineering using MATLAB.

Electromagnetic Field (EMF)Theory (3-1-0-3):
Review of vector analysis, electromagnetic fields: Coulombs law, electric field and flux density, Gauss’s law, electric potential, conductors and semi conductors, dielectric and capacitance, polarization, magnetic field and flux density, BiotSavart law, Amperes law, magnetic potential. Maxwell’s equations, and magnetization vectors Electromagnetic (EM) Waves (3-1-0-3):
Electromagnetic Theory. Plan waves, Maxwell’s equations, boundary conditions, Pointing theorem,Waveequation, Plane waves. Transmission lines: Distributed circuit arameters, HF transmission lines transmission, parallel plates, reflections, standing waves. T.L.
measurements. Wave guides: EM, TMand TE waveguides- TE and TM modes,. Cavity resonators. Impedance Transformation and Matching. Smith Chart

Electronic Instrumentations (2-1-2-3):
Introduction ,review of electrical measurement units., Instrumentation system generalities . Instrumentation set up ,statistical analysis , and probability of errors. Electronic measuring instruments. Electronic voltmeters and multi meters. CRO. Construction and measurement (Time, Frequency, Phase, angle). Transducers
,classification selecting criteria application, construction and use of significant transducers. Digital instrument , Counters and timers .
DVMS and DMMS. Instrumentation amplifiers.

Communication Systems – 1 (2-1-2-3):Introduction on Communication Systems, Signal and linear system review and introduction to new topics including generalized, Hilbert Transform, Autocorrelation, Energy Spectral Density, Filters (LPF, HPF, and BPF) Fourier series and Fourier Transform, Basic modulation techniques: Amplitude Modulation (AM), Spectrum of AM, Envelope Detection, Power Efficiency, Modulation Index, Double sideband-Suppressed Carrier (DSB-SC), Modulation, Demodulation, Transceiver and Receivers, Balanced modulator, Single Sideband Modulation (SSB), Complex Pre-envelope/ Envelope,
Demodulation of SSB, Vestigial Sideband Modulation (VSB), Modulators, demodulators,
Super heterodyne receiver, concepts of mixing. Coherent and non-coherent detection, Analog Modulation, Frequency modulation (FM), Phase modulation (PM), Pulse position modulation (PPM), Spectral analysis, bandwidth, generation, detection, discriminators, phase-locked-loop (PLL), Spectrum of Sampled Signal, Aliasing, Nyquist Criterion, Signal Reconstruction from Sampled Signal, Introduction to Sampling, quantization, analog to digital conversion Pulse Amplitude Modulation (PAM), Pulse code modulation (PCM), Noise representation, analog modulation schemes in the presence of noise.

Computer Architecture (2-0-2-3):
Introduction, Computer types, Computer internal structure and organization, Combinational and Sequential Logic, Programmable Logic Devices: PAL, PLA, CPLD, FPGA. Memory Interfacing: EPROM/Flash interface, DRAM interfaces, PC memory organization, USB Flash memory. I/O Interfacing: input ports design, output ports design, Programmable 510/8255 PIO. Applications: ISA Bus Card design, PCI Bus Card design, USB Keyboard Interface.

Integrated Electronics (2-1-2-3):
Introduction. Linear Op. Amp. Analog Systems: ideal Op Amp, inverting Op Amp, noninverting Op Amp, differential, integrator, summer, subtract or, comparator Amp Applications: Summer, Subtractor, Comparator, Sine Wave Oscillators, Active Fillers, Nonlinear Analog Systems. Timers, PLL, Voltage regulators. Digital System Design (2-1- 2-3):
Review of combinational and sequential logic, Introduction to Digital Systems Design, Combinational Circuit Design, Design of ADDER Circuits, Design of Subtractor Circuits,
Design of Complex Combinational Circuits, Synchronous Sequential Circuit Design, Design of sequential Modules Design of sequential Modules, Design of Counters and Registers, Finite State Machine Design and Optimization, Design of Programmable Logic: Introduction to Programmable Circuits Design of Read-Only Memory (ROM), Programmable Logic Arrays (PLA), Programmable Array Logic (PAL) and GAL, Design of Arithmetic Circuits, Design of Memory Circuits, Algorithmic State Machines Chart, Design of simple CPU
Engineering Economic (2-0-0-2):Production & Operation Management: Decisions in P & O

Management, Quantitative Method in P. O. M.; Linear Programming Models: Graphical &
Algebra Method, Simplex Method / M-Technique, Duality / Post optimality
Analysis. Transportation & Assignment Problems: North-West Corner Method, Least-Cost Method, Stepping-Store Method, Vogel-Approximation, Assignment Model.; CPM & PERT
Networks: CPM Networks Activity Times Table, Minimization Network by Cost-Time Relation, Minimization Network by Linear-Programming Model, The Project Probability (in expected time).
Communication Systems – 2 (2-1-2-3):
Radio spectrum; Radio rules and regulations; Detailed description of at least three out of the following systems: Radio broadcasting Systems. TV and Video Systems. Radar Systems. Microwave Links, Telephony, Telegraphy and Telex systems. SatelliteCommunicationSystems. Optical Communication Systems. Aircraft and Ship navigational systems.
Digital Signal Processing (3-1-0-3):
This course provides an introduction to digital signal processing. The course content includes the concept and the classification of discrete-time signal, representations of signals in time, frequency, z- and discrete frequency domains, representations and analyses of systems, and filter designs.
Opto-Electronics (2-0-2-3):
Basic parameters of optical radiation. Luminescence of semiconductors, light Emitting diodes, parameters and characteristics. Photo detectors parameters and characteristics, photodiodes. Current amplifying photo detectors, photo resistors. Physical process in Lasers, Laser structure, semiconductor Laser types, Laser modulators, Holographic data systems. PN junction silicon solar cells, thin films solar cells. Introduction to optical fiber wave guides. Telecommunication Transmission & Switching (3-1-0-3):
Elements of teletraffic – M/M/I, M/M/S queues, Erlang’s formulas, generic switch and Engest formula; Space-division switching; Time-division network; Analog TDM switching, digital TDM switching, multistage switching networks; Hybrid time and space switching networks; Examples of switch architecture; Telephone call processing; Telephone services-PABX; Common channel signaling; ISDN; Transmission in subscribers loop; Trunk transmission; Satellite switching and multiple access.
Mini project (1) (0-0-3-1):To train students in carrying out electronic circuit and systems design and development exercises under the supervision of a faculty member in the department.

Antennas (2-0-2-3):Radiation and Antenna Fundamentals. Linear Antennas, Current distribution, Short dipoles And Monopoles/2 dipoles, radiation resistance and gain, longer dipoles, folded dipoles. Antenna Arrays. Aperture Antennas. Special types of antennas. Traveling wave antennas, loop antennas. Frequency independent antennas, helical Antennas, corner reflector, lenses. Space Wave Propagation. Ground Wave Propagation. Tropospheric
waves. Ionosphericwaves

Digital Communication (2-0-2-3): This course provides a comprehensive coverage of a wide variety of digital modulation scheme and spread spectrum technique..It covers a review of probability and random processes; Sampling theorems; Quantization; compounding, line coding , digital modulation methods (ASK, FSK, PSK, BPSK, MPSK, GMSK, QPSK, M-array modulation schemes), noise analysis and errorprobability, digital matched filters, interference and jamming, effects of sampling errors, modern digital modulation methods, chirp
modulation, and spread spectrum Microwave Communication (2-0-2-3):
Line-of sight microwave system; path loss calculations; Microwave transmitters and receivers; Repeater stations; Diversity reception; Microwave tubes: Klystron, Magnetron and traveling wave tubes. Introduction to microwave solid state devices. Wave guide circuits and techniques. Introduction to radar systems; Radar equation; CW; Monopulse radar.

Optical Communications (2-1-2-3):
Introduction to optical communication; Review of optical source, fibers and detectors; Optical signaling schemes – IM, PL, PCCM/PL digital PPM, PFM, PRM; Various receiver configurations; Noise source; Integrated and transimpedance amplifier; optical line coding; performance evaluation of optical receivers for various modulation and demodulation schemes.
Electronic Communication Circuits (2-1-2-3):
Behavior of Transistorsat high frequencies. Analysis and design of electronic circuits employed in electronic and communication systems: Practical tuned circuits; Tuned Band Passamplifiers; large signal (power) amplifiers; Sinusoidal & Relaxation Oscillators; Up & Down Mixers; AM & FM Modulator and Demodulator circuits; Phase locked loop (PLL); FM Detector using PLL; Digital Frequency Synthesizer (DDS); Pulse Modulation Circuits;ASK, FSK, PSK Circuits: Superhetrodyne Receivers; Carrier recovery circuits; Matched filters; Cross-correlators, Audio power amplifiers.
Mini project – 2 (0-0-3-1):
To train students in carrying out design and development projects in the area of communications under the supervision of a faculty member in the department.
Computer Networks (3-1-0-3):
This course gives an introduction to computer networks and protocols. The course provides fundamentals about network topologies, network hardware, network operating system, physical networks classification and the beginning of the internet. It explains packet switching concept and issues in computer networking. The course includes layered approach and protocol standards, OSI and TCP/IP reference models. It provides examples of physical layer and then the data link layer protocols such as flow and error control. It also covers network layer internet addressing and routing protocols. This course discusses the process-to-process transport layer protocols such as UDP and TCP. The course introduces the email, http and the WWW of the application layer in addition to network security.
Information Theory and Coding (3-1-0-3):
This course is an elective course and it explores the fundamental limits of the representation and transmission of information. The course will include discrete information systems,

entropy, optimum coding, channel coding theorem, channel capacity, error control coding techniques: linear block code, cyclic code and convolutional block code

Project part – I (0-0-3-1):
Project work starts in the 9th semester and may include theoretical investigation or systems design and development activity of hardware and/or software nature. Approximately a fourth of the total work involved is to be done. The work done will be examined and grade awarded at the end of the semester.
Satellite Communication systems (3-1-0-3):
This course provides an in-depth understanding of different concepts used in a satellite communication system. It will explain the tools necessary for the calculation of basic parameters in a satellite communication system.
This course covers the most relevant aspects of satellite communications, with emphasis on the most recent applications and developments. The course begins with a review on the background and basic concepts of satellite communications. Next it covers the orbital aspects, with emphasis on the geostationary orbit. Satellite subsystems and launching methods, space and earth segments, different access system towards a satellite and satellite link design. Different
applications of satellite communication will be discussed at the end.
Seminar (2-0-0-1):A student is required to carry out investigations specialized topics and deliver a talk at the end of the semester.
Project part II (0-0-9-3);The project started in the 9th semester is to be completed and at the end of the 10th semester the student is required to submit a project report and the present the work to a committee constituted by the department.
Elective Courses CONTENTS:
1. VLSI Circuits,
2. Industrial Electronics,
3. Microwave Electronic Devices,
4. CAD of Digital Systems,
5. Neural Networks,
6. Biomedical Instrumentations,
7. PLC Applications,
8. Selected Topics in Electronics.
9. Mobile Communication,
10. Digital Image Processing,
11. Radar System,
12. TV Communication Systems,
13. Selected Topics In Communications.

VLSI Circuits (3-1-0-3): Evolution of VLSI, Designed system concepts, Evolution of integrated circuits design approaches, physical design tools, Review of solid state device

concepts, device structure, Device modeling and circuit simulation, MOS circuit design, test methodologies for VLSI, VLSI process development.
Industrial Electronics (3-1-0-3):Power electronic components- Thyristors, Triacs, GTOs, MOSSFET and bipolar devices and their switching properties, Introduction to thyristorised phase controlled rectifiers and dual converter, A.C. controllers and timers, dimmers, heating, switched mode power supply and UPS systems, Introduction to A.C. controllers, inverters, choppers and cycloconverters.

CAD of Digital Systems (3-1-0-3);
Review of combinational and sequential logic. Structured digital circuits and systems: PALs, Logic Gate Arrays, MOS clocking schemes, Dynamic MOS storage circuits, Memory organization, ROMs, SRAM, DRAM, PLA based finite- state machines, Data and control path synthesis, systolic arrays. VLSI Design automation and verification: HDL, Register-Transfer-Level simulation (RTL), logic and switch simulation, Placement and routing, CAD tools.
Neural Networks(3-1-0-3):
Biological consideration, perception and cognitive system. Artificial neurons and neural network fundamentals. Neural network models. Learning process. Implementation to signal
processing, classification and optimization Cellular Communications (3-1-0-3):
The aim of the course is to provide the students with the basic concepts of cellular mobile communication technologies. It provides a brief history and evolution different generations of wireless cellular networks 1G, 2G, 3G and 4G mobile systems. It covers also cellular- systems concepts, GSM system architecture, concepts of frequency reuse and channel allocation algorithms and covers handover, interference and system capacity. The course considers multiple access techniques used in cellular communications and improving coverage. Finally the course provides a detailed understanding of wireless channel modeling emphasis on mobile radio wave propagation. Programmable Logic Controllers – PLCs (2-1-2-3):
Introduction to Microprocessors & Microcontrollers, Microcontroller building blocks ( CPU,
RAM, ROM, Timer/Counters, Ports,…..), Architecture of 8051 Microcontrollers, Memory organization of the 8051, the 8051 instruction set and addressing modes, the 8051 Assembly programming, MCS51 applications, LED Flashes, Clock, LCD drive, Light sensor,
Temperature sensor, Step motor driver, 7-Segment display driver & Keypad driver PLC architecture, Seimens S7, PLC operation and scan cycle,
PLC memory organization, PLC programming, LAD & STL languages, Connecting PLC with PC,
Step 7 Compiler, Program editing, Compiling and downloading,

Applications: PLC-Lab.
Temperature control with PLCs

Tank liquid level control with PLCs Motor speed control with PLCs
Others.
Selected Topics in electronics (3-1-0-3):
Under this course topics of current interest will be covered. TV Communication Systems (2-1-2-3):
Introduction, Television fundamentals, Elements of colour, Composite colour signal, Colour TV systems, Colour picture tube, Colour TV receivers, Digitizing the TV picture, Video encoding, Audio encoding, Channel encoding, Satellite DTV.
Radar Communication Systems (3-1-0-3):
Introduction to Radar System, Radar performance factors, Basic Pulsed Radar System, Antennas and scanning, Display Methods, Pulsed Radar systems, Moving Target Indication, Radar Beacons, CW Doppler Radar, Frequency Modulated CW Radar, Phase Array Radars, Other Radar Systems.
Selected Topics in Communications (3-1-0-3):
Under this course topics of current interest will be covered.