Course Curriculum for the Degree of Bachelor of...

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Course Curriculum for the Degree of Bachelor of Science (B.Sc.) in Electronic and Electrical Engineering, Faculty of Technology, Obafemi Awolowo University, Nigeria

To be eligible for the Degree of B.Sc. in Electronic and Electrical Engineering, a

candidate must satisfactorily complete a minimum of 194 units including:

12 units of Special Electives.

30 units of Part-One Physics, Chemistry and Mathematics courses.

88 units of Electronic and Electrical Engineering courses excluding Industrial

Attachment.

5 units of Agricultural Engineering courses comprising AGE 202 and AGE

302.

9 units of Chemical Engineering courses comprising CHE 201, CHE 305 and

CHE 306.

5 units of Civil Engineering courses comprising CVE 202 and CVE 401.

5 units of Computer Science and Engineering courses comprising CSC 201 and

CSC 208.

8 units of Part-Two Mathematics courses comprising MTH 201 and MTH 202.

10 units of Mechanical Engineering courses comprising MEE 203, MEE 204,

MEE 205 and MEE 206.

3 units of Metallurgical and Material Engineering courses comprising MME

201.

7 units of Technology Policy and Planning courses comprising TPD 101, TPD

501, TPD 502 and TPD 503.

15 units of Industrial Training courses comprising EEE 200, EEE 300 and EEE

400.

1. PART-ONE COURSES

A. Harmattan-Semester Courses (Part-One)

CHM 101: Introductory Chemistry I:

[4-1–0] (5 Credit Units) Harmattan Semester

Course Content:

Introduction

Method of Science: Measurement and precision. Significant figures, errors in

quantitative measurements, nature of matter, elements and compounds. Types

of chemical reactions.

http://fet.oauife.edu.ng/eee/undergrad.html#1

http://fet.oauife.edu.ng/eee/che.htm

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Atomic Theory and Nature of Atoms

Dalton’s atomic theory: Atomic weight, Avogadro’s number: structure of the

atom. Cathode rays: mass spectrometer: contributions to atomic structure by

Bohr, Thompson, Morseley and Rutherford; Discovery of nucleus: electronic

energy levels and Periodic Table: Atomic size; Ionization potentials, Electron

affinity: ionic radii and electronic configuration.

Stoichiometry I Chemical formulae and equations; simplest formulae; molecular formulae;

mole concept; calculation of formulae and equations from gravimetric data and

vice versa; ionic equations for neutralization and precipitation reactions.

Concentrations; Molarity and Volumetric calculations based on stoichiometric

coefficients; Oxidation and reduction as electron transfer; oxidation number;

balancing of equations including balancing of redox equations by electron

transfer equality.

Stoichiometry II

Volumetric analysis including relevant calculations. Preparation of standard

solutions, Molarity and volumetric coefficients in neutralization, redox

precipitation and complexation reactions.

Chemical Equilibria

The equilibrium state; Mass action; equilibrium constant calculations;

Equilibrium changes; dissociation of water; pH of acids and bases; buffer

solutions; Indicator theory; Solubility of ionic solids; solubility products;

precipitation reactions (using solubility products); calculations as applied to

qualitative and quantitative analysis. Common-ion effect.

Thermochemistry Balancing of intermolecular forces. Hydrogen bonding; order-disorder

phenomenon; entropy; free energy; energy effect; exothermic and endothermic

changes; enthalpy of reaction, Hess’s Law of enthalpy summation (with

relevant calculations); heats of neutralization, combination and formation; bond

dissociation energies; relevant calculations; free energy and spontaneous

energy.

Electrochemistry

Electrical units; Ohm’s law; Faraday’s law of electrolysis; Galvanic cells;

Standard Half-Cell potentials and reactions.

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Concentration effects (Nernst equation). Redox reactions; oxidation potential

treated in terms of free energy changes; cells and batteries.

Kinetics Introduction to chemical kinetics, basic definition of order of reaction,

molecularity, reaction rates and simple reaction mechanism, Activation energy

and kinetic theory.

Radioactivity Types of radioactive disintegration; Nuclear fission and fusion; Detection of

radioactivity; Uses of radio-isotopes.

MTH 101: Elementary Mathematics I:


Course Content:

Set Theory:

Sets, Union, Intersection, empty set and universal set, complement of a set,

subset, finite and infinite sets, Venn diagrams, Mappings and Functions

Operations with Real Numbers:

Real numbers (R) and its extension to the set of complex numbers (C).

Equations involving one variable, the Remainder Theorem, and the Factor

Theorem. Equations in two variables, inequalities, partial fractions, surds,

indices and logarithms

Theory of Quadratic Functions and Equations: The quadratic function and the relation between the roots of a quadratic

equation and the coefficients.

Sequences and Series:

Finite sequences and series, the arithmetic sequences and series, the finite and

infinite geometric sequences and series.

The Binomial Theorem: Elementary examples in the use of induction, permutations and combinations

and their applications. The Binomial Theorem for a positive integral index. The

use of the expansion (1 + 𝑥)𝑛, where 𝑛 is fractional or negative; simple

approximations.

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Matrices

Definition of 𝑚 x 𝑛 matrices (1 ≤ 𝑚, 𝑛 ≤ 3); addition of matrices, matrix

multiplication and inversion. Determinant of a matrix. Applications to simple

linear equations, consistence and linear dependence.

PHY 101: General Physics I

[3-0-0] (3 Credit Units) Harmattan Semester

Course Content Fundamental principles of mechanics. Mechanical properties of matter

including elasticity, surface tension and viscosity. Mechanical Waves.

Thermal Physics: Thermal properties including elementary thermodynamics

and kinetic theory.

PHY 107- Experimental Physical IA [0-0-1] (1 Credit Unit) Harmattan Semester

Course Content:

Laboratory experiments to demonstrate the application of the theory covered in

PHY 101.

TPD 101 – Engineers in Society

[1-0-0] (1 Credit Unit) Harmattan Semester

Course Content:

Historical roots of modern technology, science and industrialization. Origin and

development of engineering education and training. Engineering profession and

national economy. Engineering professional institutes. Social impact of

engineering on development. Organization of engineers in the private and

public sectors. Opportunities for engineers in the private and public sectors.

Engineering and environment.

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B. Rain-Semester Courses (Part-One)

CHM 102: Introductory Chemistry II:

[3-1–0] (4 Credit Units) Rain Semester

Course Content:

Qualitative Analysis (Inorganic) – Tests for simple cations and anions

Identification of Organic Compounds to include

i. Isolation and Purification;

ii. Qualitative Analysis: Tests for common elements e.g. carbon, hydrogen,

nitrogen, Sulphur, halogens, etc.;

iii. Qualitative Analysis using Durnas, Kjeidahl and Carius Methods

Chemical Bonding

Why and how do atoms combine? The molecule and chemical bonding;

electrons in molecules; ionic, covalent, dative and complex bonding; polarity of

bonds; coordinate bonds; metallic bonds; basic crystalline structure e.g. NaCl

and metallic lattices; Hybridization and resonance in chemical bonding.

Chemistry of hydrogen, noble gases, Alkali metals (Group I) and the alkali

earth metals (Group II)

Introduction to Organic Chemistry Introduction to the term “Organic Chemistry”;

Hybridization in Carbon – sp3, sp2 and sp hybridizations;

Physical properties as related to structures – bond length, strength, rotation,

etc.;

Electrophiles and Nucleophiles – Examples to include acids and bases;

Homolytic and Heterolytic fission of bonds;

Factors influencing organic reactions – inductive and mesomeric effects, steric

factors, etc.

Homologous Series, Functional Group Chemistry, Isomerism and

Chemistry of Hydrocarbons Homologous series and Functional Groups chemistry

Types of organic reactions

Isomerism – Structural, Geometric and Optimal Isomers

Chemistry of Hydrocarbons (alkanes, alkenes, alkynes, alkylhalides and

Grignard reagents) to include

i. Nomenclature (IUPAC rules to be treated under alkenes);

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ii. Preparation;

iii. Physical properties;

iv. Chemical reactions with simple mechanisms where applicable;

v. Applications

Main Group Chemistry (Groups III and V) Trends in properties of elements (structures, ionization energy, physical and

chemical properties)

Properties of selected types of compounds – hydrides, oxides, acids and bases

Chemistry of B and Al; C and Pb; and Bi.

Main Group Chemistry (Groups VI and VII) and Transition Metal

Chemistry

(a) Main Group Chemistry (VI and VII):

i. Trends in properties of elements;

ii. Properties of selected types of compounds;

iii. Chemistry of O and S; F and Cl

(b) Transition Series

i. Properties of elements and compounds of d-block elements,

lanthanides and actinides

ii. Electronic configuration; Complexes and IUPAC nomenclature of

complexes;

iii. Chemistry of Cr, Fe, Co, Ni, and Cu; particularly of the most

common states

Chemistry of Alcohols, Ethers, Aldehydes and Ketones Nomenclature (IUPAC)

Preparation, Structure, Physical Properties and General Reactions

Introduction to Aromatic Compounds

Carbohydrates, Proteins and Lipids Simple treatment of carbohydrates – monosaccharides (e.g. glucose, fructose),

disaccharides and polysaccharides

Proteins – amino acids, peptide bonds, etc.

Lipids – Fats and Oils, Soap and Detergent.

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MTH 102: Elementary Mathematics II:


Course Content:

Trigonometry:

Circular measure, small angles, definition and properties of sine, cosine,

tangent, etc.; Formulae for sin(𝐴 + 𝐵), cos(𝐴 + 𝐵), tan(𝐴 + 𝐵), sin (𝐴

2),

cos (𝐴

2), tan (

𝐴

2), etc.; Sine and Cosine formulae, Factor formulae, inverse

trigonometric functions. General solutions of trigonometric equations such as

𝑎 cos 𝜃 + 𝑏 sin 𝜃 = 𝑐, etc.

Calculus:

Differentiation of algebraic, exponential, trigonometric functions, products and

quotients of functions, applications of differentiation to curve sketching, etc.

Maxima and minima. Definite and indefinite integrals with applications to

areas and volumes. Simple techniques of integration such as integration by

parts, etc. Simple first-order ordinary differential equations.

Coordinate Geometry:

Coordinates, equations of line, circle, ellipse, hyperbola and parabola

Statistics

Finite sample spaces, definition of probability on finite sample spaces and

examples. Probability as proportion of areas, conditional probability of events.

Independence, tree diagrams, variables and cumulative frequency distribution,

mean, median, variance and covariance. Conditional expectation and linear

correlation using scatter diagrams.

MTH 104: Vectors:


Course Content:

Introduction to vectors, vector addition, components of a vector, unit vectors

i,j,k, magnitude of a vector. Vector multiplication (Scalar, vector, scalar triple

product and vector triple product). Applications to geometry and kinematics

(including relative velocity). Solutions of simple vector equations.

Differentiation and integration of vectors.

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PHY 102: General Physics II

[3-0-0] (3 Credit Units) Rain Semester

Course Content: Fundamental laws of electricity and magnetism and their applications. Electron

Physics: Introduction to Physics of electronics and some applications. Optics:

Principles and applications of geometrical and physical optics.

PHY 108- Experimental Physical IB [0-0-1] (1 Credit Unit) Rain Semester

Course Content:


PHY 102.

2. PART-TWO COURSES

A. Harmattan-Semester Courses (Part-Two)

EEE 201: Applied Electricity I:


Course Content:

Introduction to electrostatics, Gauss's theorem and application, electrostatic

potential and equipotential surface capacitances, energy of a charged

conductor.

Foundation of electric circuit theory, Circuit elements resistors, capacitors and

inductor, Network theorems - Norton, Thevenin and Superposition theorems,

Transient response of RC, RL and RLC Circuits. Elementary discussion of

Semi-conductors - pn junction diode, npn and pnp transistors. Full-wave and

half-wave rectification circuits and smoothing circuits. Electric lamps and

illumination.

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EEE 291- Applied Electricity Laboratory I

[0-0-1] (1 Credit Unit) Harmattan Semester

Course Content:


EEE 201.

MTH201 – Mathematical Methods I


Course Content:

Sequences and Series: Limits, Continuity, Differentiability, Implicit functions,

sequences, series, tests for convergence. Sequences and series of functions.

Calculus: Partial differentiation, total derivatives, Implicit functions, Change

of variables, Taylor’s theorem and maxima and minima of function of two

variables. Lagrangian multiplier.

Numerical Methods: Introduction to iterative methods, Newton’s method

applied to finding roots. Trapezium and Simpson’s rules of integration.

Differential Equations: Introduction, equation of first order and first degree,

separable equations, homogeneous equations, exact equations, linear equations,

Bernoulli’s and Riccati equations. Applications to mechanics and electricity.

Orthogonal and oblique trajectories. Second order equations with constant

coefficients

CSC 201: Computer Programming


Course Content:

Brief survey of programming paradigms – Procedural programming – Object-

oriented programming, Functional programming – Declarative programming,

non-algorithmic programming – Scripting languages. The effects of scale on

programming methodology.

Programming the computer in current version of FORTRAN: Declarative

statements; Input and Output statements; Program compilation and execution;

Control and conditional statements; Loops and iteration; Functions, routines

and sub-programmes.

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Input/output; File processing; Port addressing.

Program testing and debugging techniques.

MEE203 – Engineering Drawing I


Course Content:

Introduction – use of drawing instruments, paper sizes, scales and drawing

layouts. Lines and lettering, electric circuit diagrams. Geometrical drawing –

plane geometry, conics and cycloids. Dimensioning and tolerances. Orthogonal

projections. Sectional views. Fastening devices – rivets and screw fasteners.

Conventional practices. Isometric projections. Oblique projections. Freehand

sketching . Graphic charts and diagrams

MEE205 – Engineering Mechanics I


Course Content:

Independence, dimensions and coordinates in space. Vectors and vector

algebra. Forces, couples and their systems: composition, resolution. Varigon’s

theorem, equivalence and reduction of systems, wrench. Rigid bodies and

equilibrium. Centres of gravity, centroids and their applications. Structures and

machines. Friction, Moments of Inertia. Virtual work.

CHE 201-Engineering Thermodynamics

[2-1-0] (3 Credit Units) Hamattan Semester Course Content:

Definition of terms and general concepts of system, surrounding, process,

temperature, heat, work and energy. First Law of Thermodynamics.

Applications to open systems. Second Law of Thermodynamics. Application to

heat engine entropy. First and Second Law combined. Perfect Gases. Joule

Thompson coefficient. Equilibrium processes. Maxwell's relations. Two phase

system Thermodynamic functions of solution. PVT relationship. Work from

heat energy. Refrigeration.

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MME 201-Engineering Materials

[2-1-0] (3 Credit Units) Harmatttan Semester

Course Content: Atomic and crystal structure. Crystal imperfections. Simple phase diagram of

alloys. The relationship between structure and properties. Mechanical

properties-engineering and true stress-strain curves, ultimate strength, ductility,

impact strength, hardness and torsion. Creep and fatigue failure. Electrical

properties-conductivity and superconductivity. Optical and magnetic properties

of materials. Stability of materials in the service environment, corrosive media,

sub-zero and elevated temperature, irradiation. Basic criteria for the selection of

materials for engineering applications. Engineering properties of wood,

concrete, ceramics, polymers, ferrous and non-ferrous metals and alloys;

cryogenic, corrosive media and nuclear applications.

Basic Engineering raw materials-mineral rocks, metallic and non-metallic

mineral deposits, rocks for bulk use, tar sand, graphites. Mineral prospecting

and exploration. Relation between mining, mineral processing and

materials/metallurgical processing of materials. Introduction to mineral

processing.

Introduction to joining processes and casting processes. The role and functions

of Materials Engineers in the design, operation and maintenance of machinery

and equipment in metallurgical, ceramic and plastic industries.

B. Rain-Semester Courses (Part-Two)

EEE 202 - Applied Electricity II


Course Content: Magnetic field of currents in space: Magnetic flux and flux density, corkscrew

rule, solenoid and magnetomotive force, Periodic wave force - their average

and effective values. Characteristics and use of non-linear elements in

simple circuits. Single-phase alternating current circuits - complex impedances

and admittance. Series and parallel resonant circuits. Magnetic circuits, mutual

inductances, transformers. Introduction to electrical generators and meters.

Power factor correction, Introduction to measuring instruments; Moving coil

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instruments, oscilloscope, electrostatic voltmeters, A.C. and D.C. bridges.

Pre-requisite: EEE 201

EEE 292- Applied Electricity Laboratory II

[0-0-1] (1 Credit Unit) Rain Semester

Course Content:


EEE 202.

MTH202 – Mathematical Methods II


Course Content:

Vector Theory: Vector and scalar field functions. Grad, div, curl; directional

derivatives. Orthogonal curvilinear coordinates.

Complex Numbers: The algebra and geometry of complex numbers, De

‘Moivre’s theorem. Elementary transcendental functions. The 𝑛𝑡ℎ root of unity

and of a general complex number.

Linear Algebra: Vector spaces. Linear independence. Basis, change of basis

and dimension. Linear equations and matrices, Linear maps. The diagonal,

permutations, triangular matrices.

Elementary Matrix: The inverse matrix. Rank and nullity. Determinants.

Adjoints, cofactors, inverse matrix. Determinantal rank. Cramer’s rule,

canonical forms, similar matrices. Eigenvalues and eigenvectors, quadratic

forms.

MEE204 – Engineering Drawing II


Course Content:

Auxiliary projections. True lengths, sizes and shapes. Simple developments.

Interpenetration and development. Mechanical drawing of machine parts –

cams, gears, couplings, bearings, pipe joints and valves. Structural drawing –

materials representation, dimensioning of structural details and welds.

Structures – wood, concrete, structural detailing , shop drawings and sketches.

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Simple assembly drawing. Introductory pen work, lettering and tracing of

completed drawings.

MEE206 – Engineering Mechanics II


Course Content:

Kinematics and Kinetics of Particles. Work, Energy, Power, Momentum and

Impulse. Kinematics and Kinetics of Rigid Bodies in Plane Motion.

Analysis of elementary dynamic systems – dynamic system elements:

mechanical, electrical, fluid and thermal, modeling of physical systems.

Newton’s laws of motion. D’Alembert’s principles and Lagrange’s equations.

Particle dynamics in non-inertia frame of reference and application of

Lagrange’s equations.

CVE 202 – Strength of Materials


Course Content:

Further analysis of shearing force and bending moments in beams. Direct

stresses due to load and temperature. Loading tests of ductile and brittle

materials. Elastic constants. Modified Young’s modulus, Poisson’s ratio.

Properties of beam sections. Deflection of beams. Torsion of shafts. Bending of

curved bars and rigid frames. Buckling of struts and columns.

CSC 208: Computer Technology

[0-0-2] (2 Units) Harmattan Semester

Course Content:

This is a programming laboratory course consisting of applications of

programming, through case study problems. Students are expected to carry out

four laboratory assignments and make two oral presentations after the

completion of the second and the fourth assignments. Programmes will be

developed using FORTRAN 90 or latest version of FORTRAN.

Laboratory Assignment I: Programming basics – Data type, basic programme

structure; Compiling and executing programmes in text and graphic

environment.

Laboratory Assignment II: Loop, arrays, searching and sorting

Laboratory Assignment III: Function, Routine, Subroutine subprogramme:

multiple procedure calls from a main programme.

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Laboratory Assignment IV: Extensive programming problem with application

to student's field of study and interest.

AGE 202: Workshop Practice


Course Content: Workshop safety measures, Introduction to Workshop hand and powered tools

emphasizing safety measures to be taken during operation. Workshop

materials, various gauges and measuring devices. Tolerance of products.

General description of the function and capabilities of grinding machines.

Practice in grinding tools and drills. Function and capabilities of drilling

machines, lathe machines, milling machines and shaping machines. Jigs,

Fixtures, Practice in the use of the machines.

EEE 200: Student Industrial Work Experience Scheme I


Course Content:

This course is the first phase of the Industrial Training Scheme for Engineering

students, in particular, and Electronic and Electrical Engineering students, in

particular. The students are taught the importance of application of theoretical

knowledge in industrial engineering situations. The students are also introduced

to all the sections of their respective Departments and made to do simple

Electronic and Electrical Engineering projects that have industrial significance.

3. PART-THREE COURSES

A. Harmattan-Semester Courses (Part-Three)

EEE 301- Physics Electronics [2-1-0] (3 Credit Units) Harmattan Semester

Course Content

Elementary Physical Electronics: Crystal Structures, electron and energy band

schemes, semiconductor devices, diodes, Zener diodes, transistors, and FETs.

Characteristics and biasing of bipolar and FET transistors, CE, CB, CC, CS,

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CG, CD. Review of two port network theory applied to transistor circuits.

Small signal models: Z-, Y-, and H- parameters. Microwave devices (Tunnel,

IMPATT and BARITT diodes). Introduction to opto-electronic devices: Solar

cells, laser etc.

Pre-requisite : EEE 201

EEE 303 - Electric Machines I


Course Content

TRANSFORMERS: Coupled circuits, Air cored transformers equivalent

circuits, Iron cored transformers equivalent circuits, Referred impedance, no-

load test, short circuit test and efficiency of single phase transformers. Three

phase transformers. Group connection of windings, auto transformers,

instrument transformers.

DC MACHINES: Armature winding, principles of commutation. Torque and

emf expressions. Generator and motor configurations. Characteristics of series ,

shunt and compound wound motors. Speed control and electric breaking, cross

field machines, commutator machines.


EEE 305 - Electric Circuit Theory I


Course Content

Node, loop and cut-set analysis of linear networks. Network graph theory and

its applications. Frequency response of networks: Poles and zeros, Bode pots

and root locus concepts. Periodic non-sinusoidal currents in linear circuits.

Two-port networks, ladder networks and electric filters.

Pre-requisites: EEE 202

EEE 307 - Electrotechnic Laboratory I


Course Content


the courses.

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EEE 309 - Acoustic Systems


Course Content

Electro-acoustical system: Principles and properties of sound, simple

acoustical systems. acoustic transducers, linear systems and natural modes.

Loud speakers: Properties, types, response and distribution patterns. Electro-

acoustic recording and reproduction. Ultrasonic systems, transducers and

applications.

Magnetic Application of Magnetic Materials: Ferro and Ferri Magnetics:

Magnetic circuits and shielding. Magnetic recording techniques and systems

including electro-acoustic and video tape recording. Units of recording level.

Microphones and types.


EEE 311- Electromagnetic Theory I


Course Content

Electrostatic and Magnetostatic fields, Time varying electromagnetic filed in

different material media. Poisson's and Laplace's equations and methods of

solution. Boundary value problems.


EEE 313-Electrical Measurement and Instrumentation I


Course Content

Principles of measurements: errors and accuracy - units of measurements,

standard symbols for electric measuring instruments and electrical standards.

Instruments of direct measurement of current and voltage - moving coil,

moving iron, electrodynamic and electrostatic measuring instruments.

Measurement of current and voltage by comparison. Measurement of

resistance, inductance and capacitance, Measurement of electrical energy,

power, power factor and frequency. Measurement of Magnetic field strength

and magnetization (B-H) curve. Principles of cathode-ray oscilloscope.

Introduction to semiconductor device te4sters, electronic counters and digital

meters.


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CHE 305- Engineering Analysis I

[2-1-0] (3 Credit Units) Hamattan Semester

Course Content: Linear algebra elements of matrices, determinants, inverse of matrix, theory of

linear equations, eigen-values and eigen-vectors. Analytical geometry-

coordinate transformation-solid geometry, polar, cylindrical and spherical

coordinates. Elements of functions of several variables. Ordinary integrals and

multiple integrals. Evaluation of double integrals, triple integrals, line integrals,

surface integrals. Derivatives and integrals of vectors. The gradient of scalar.

Flux, divergence and curl of a vector field. Gauss', Green's and Stoke's

Theorems and applications. Single-valued functions. Multi-valued functions.

Analytic functions. Cauchy-Riemann equations. singularities and zeros.

Contour integration including the use of Cauchy's integral theorem. Taylor and

Law rent's series. The residue theorem. Bilinear transformation.

B. Rain-Semester Courses (Part-Three) EEE 302- Electronic Engineering


Course Content:

Analysis of single and multi-stage transistor amplifiers. Frequency response

analysis, Power amplifiers: Class A, B, C and push-pull amplifiers. Feedback

amplifiers. Oscilloscopes.

Introduction to operational amplifiers. Stabilized power supplies. Use of

electronic device in voltage regulation.

EEE 304 - Electrical Machines II


Course Content

ASYNCHRONOUS (INDUCTION) MACHINES: Magnetic flux, distribution

of induced emf, equivalent circuit, power balance, equivalent circuit referred to

stator. Torque-slip characteristics for generating and motoring actions. The

circle

diagram. Methods of starting and speed control. Double cage induction motor.

Single phase motors.

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SYNCHRONOUS MACHINES: Synchronous machine theory, Equivalent

circuit and phasor diagrams for cylindrical rotor. Effect of change in

excitation, the V-characteristics with regards to transmission lines. Short

circuit analysis of synchronous machine, d-, q- axis analysis of salient pole

machines.


EEE 306 - Electric Circuit Theory II


Course Content

Some properties of three-phase system: Balanced Delta and Wye connected

loads. Delta-Wye transformation. Unbalanced Delta and Wye connected loads.

Use of symmetrical components method to solve unbalanced three-phased

networks. Operational methods of transient analysis of limped network -

Laplace transforms. Fourier transforms methods of non-linear a.c circuits.

Prerequisite: EEE 305

EEE 308 - Electrotechnics Laboratory II

[0-0-1] (1 Credit Unit) Rain Semester

Course Content


the courses.

EEE 310- Operational Amplifiers and Active Networks

2-1-0 (3 Credit Units) Rain Semester

Course Content:

Complex frequency plane. Feedback circuits and sensitivity, Stability: Nyquist

and Routh's criteria for stability. Introduction to operational amplifiers, other

linear circuits and applications. Differentiators, integrators, differential

amplifiers for measurements. Active filters using operational amplifiers: Low

pass, high pass, band-pass and Butterworth filters. Timing circuits using ICs.

Phase locked loop.

Pre-requisite EEE 301

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EEE 312-Electromagnetic Theory II

2-0-0 (2 Credit Units) Rain Semester

Course Content:

Maxwell's equations and its applications, Poynting's theorem, wave equations:

Plane waves and plane wave propagation. Electromagnetic waves and

electromagnetic wave propagation in bounded and unbounded media. Radiation

of electromagnetic waves.


AGE 302: Statistics for Engineers


Course Content: Statistical concepts, Normal distribution, Hypothesis testing. Analysis of

Variance, Factorial experiments, Regression Analysis.

CHE 306- Engineering Analysis II


Course Content: Series solution of second order linear differential equations with variable

coefficients. Bessel and Legendre equations. Equations with variable

coefficients. Sturm-Louiville boundary value problems. Solutions of equations

in two or three dimensions by separation of variables. Eigen-value problems.

Use of operators in the solution of partial differential equations and linear

integral equations. Integral transforms and their inverses including Fourier,

Laplace, Mellin and Handel transforms. Convolution integral and Hilbert

transforms. Calculus of finite differences. Interpolation formulae. Finite

difference equations. Runge-Kutta and other methods in the solution of

ordinary and partial differential equations. Numerical methods for the solution

of non-linear equations. Numerical integration and differentiation.

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EEE 300: Student Industrial Work Experience Scheme II [2-0-1] (3 Credit Units) Rain Semester

Course Content: This course is the second phase of the Industrial Training Scheme for

Engineering students, in particular, and Electronic and Electrical Engineering

students, in particular.

The students are employed as interns for a minimum period of three (3) months

in industrial establishments with sections where Electronic and Electrical

Engineering tasks are being performed. The student learns the industrial

applications and applicability of theoretical concepts and principles taught in

class.

4. PART-FOUR COURSES

A. Harmattan-Semester Courses (Part-Four)

CVE 401 - Technical Report Writing


Course Content:

Role of technical reports in engineering projects. Fundamental principles of

technical writing. Formats of different types of reports – outlines, purpose and

scope, technical discussion details, role of appendix, function of figures, tables

and illustrations. Literature search, references (citing and listing). Nature of

recommendations and conclusion. Guides of writing memoranda, business

letters. Oral presentation of technical reports. (One or two term papers to be

prepared on assigned work).

EEE 401- Computational Analysis


Course Content:

Solution of linear equations - Gaussian elimination, triangulation and iterative

methods. Solution of non-linear equations - Newton-Raphson's, Bairstow's,

Aitken and iterative solution techniques. Synthetic division and Lehmer.

Numerical integration and differentiation - Newton-Cotes formular, Gauss's

integration formula. The eigenvalue problem - characteristic polynomial, the

power

method, Givens and Householder methods, Numerical solution of differential

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equations, Methods of Taylor, Euler Predictor -Corrector and Runge-Kutta.

Pre-requisite: CHE 306

EEE 403-Electric Power Principles


Course Content:

Power Sources: Principles and methods of energy conversion employing steam,

gas, water, nuclear, wind and magnetohydrodynamic generation. Design and

organization of power stations. Siting of power stations. Power station

auxiliaries. Components of power generation systems: Prime mover systems,

generators; characteristics, equivalent circuits, control and operation. Voltage

regulation, Economics of power generation. Supply System; transmission and

distribution systems, rated

voltages and frequency. Substations; types, switch gear and busbar structures.


EEE 405- Electrical Engineering Laboratory


Course Content: Laboratory experiments designed for students to apply and verify theories

covered in the courses.

EEE 407- Pulse and Digital Technique


Course Content

Non-sinusoidal oscillators, switching, timing and wave shaping circuits.

Digital electronics, Introduction to basic logic function, AND, OR, NOT etc.

Boolean algebra, simple logic circuits. Minimization of logic functions, K-map,

logic families TTL, RTL, CMOS etc. Sequential circuits RS, JK, flip flop

register and counters. Number systems and codes, arithmetic circuits, decoders,

multiplexers and demultiplexers, memory devices.


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EEE 409-Servomechanism and Control


Course Content:

Control System concept; open and closed loop control systems, block diagrams,

Review of Laplace transforms; Transfer functions of electrical and control

systems. Electromechanical devices: Simple and multiple gear trains, electrical

and mechanical analogies. Error detector and transducer in control systems.

The amplidyne: AC and DC technogenerator and servomotors rotary

and translational transducers. Hydraulic and pneumatic servomotors and

controllers. Dynamics of simple servomechanism: Steady state error and error

constants, the use of non-dimensional notations

and the frequency response test. Log and Polar plots of control systems, Basic

stability concepts in control systems.

Prerequisites: EEE 306

EEE 411- Communication Principles


Course Content:

Basic concepts of a communication system - Source, channel and user. Signal

and systems analysis, Fourier series. Fourier transforms, Amplitude modulation

and demodulation methods, DSBSC, SSB, VSB. Comparison of AM systems,

Angle modulation and demodulation; Frequency and phase modulation.

Wideband and narrowband F.M, A.M, detectors and FM discriminations.

Sampling principles, theorems and techniques. Pulse modulation: PAM, PWM

and PCM.


EEE 413-Electronic Devices, Design and Fabrication.


Course Content:

Design principle and fabrication of the following: Thermionic devices; cathode

ray tubes and television tubes. Semi-conductor devices: junction diodes

including Zener, varactor and tunnel

diodes. Bipolar, unijunction and field effect transistors, light emitting diodes

(LED), Laser diode, Gunn effect devices, solar cells, photodiodes; photo-

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transistor and thryristors.


B. Rain-Semester Courses (Part-Four)

EEE 400: Student Industrial Work Experience Scheme III [9-0-0] (9 Credit Units) Rain Semester

Course Content: This course is the third and final phase of the Industrial Training Scheme for

Engineering students, in particular, and Electronic and Electrical Engineering

students, in particular.

The students are employed as interns for a minimum period of six (6) months in

industrial establishments with sections where Electronic and Electrical

Engineering tasks are being performed. The student learns the industrial

applications and applicability of theoretical concepts and principles taught in

class.

5. PART-FIVE COURSES

A. Harmattan-Semester Courses (Part-Five)

EEE 501: Final Year Project I


Course Content:

This course is a first of two Part-Five project courses. It deals with the

formulation and execution of a project in a specific area of specialization in

Electronic and Electrical Engineering under the supervision of an appropriately

assigned member of academic staff of the Department.

The student uses the theoretical, practical, documentation and articulation skills

acquired over the previous and current sessions to make appropriate practical

project designs, make constructions/simulations of such designs, document the

results of the implementations, write a detailed thesis of the project and make a

formal presentation of the project to assigned members of staff of the

Department.

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EEE 503: Control Engineering I


Course Content:

Linear control system. Stability: Nyquist stability criterion, Bode diagram

approach; the root locus and root contour method. Design of linear servo

systems; Compensation designs using the Bode and root locus methods.

Multiple loop feedback systems; Minimization of unwanted disturbances.

Single and multi-term electronic process controllers. Hydraulic and

pneumatic controller; Introduction to analogue and hybrid

computation, Sensitivity of control systems.

AC control system: Synchos; suppressed carrier modulation, hybrid AC/DC

control systems; practical considerations in A.C. control design.


EEE 505-Application of Electromagnetic Principles


Course Content:

Review of transmission line theory/use of Smith's Chart. Single, double, stub,

machine on lines, quarter wave line as impedance transformers. Common

waveguides, Propagation in rectangular waveguides, attenuation in guides,

guide terminations, resonant cavities. Introduction to radio wave propagation in

the MW and HF bands, HF communication on power lines.

EEE 507- Electrical Measurement and Instrumentation II


Course Content:

Measurement of non electrical quantities - Transducers, Instrumentation

amplifiers for the measurement of voltage and current, Differential amplifiers

circuits, Data logger

electromatric amplifiers for measurement of low level current and voltage.

Linear and nonlinear converters. Multiplier, sample and hold circuits. Design

of high stability power supply. Digital instrument, X-Y Plotters.


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EEE 515- Introduction to Modern Control


Course Content:

Introduction to state space analysis; matrix representation of control systems;

transfer function matrices and stability,

Solution of state equations; eigenvalues, eigenvectors and modes.

Lyapunov stability analysis; first and second methods of Lyapunov; stability

analysis of linear and non-linear systems using the Lyapunov method. Optimal

control theory and application. Controllability and Observability. Application

of calculus of variation, dynamic programming and Pontryagins

maximum principles; Time optimal control system, optimal systems based

on the quadratic performance indices. Minimum time problem, minimum fuel

consumption problem and minimum energy problem. Lyapunov second and

approach to solution of optimal control problems.

Model reference control system. Introduction to Adaptive control system.

Prerequiste: EEE 409

EEE 521-Instrumentation Engineering II


Course Content: Introduction to the design of electronic equipment. Specifications including

environmental factors such as humidity and temperature. Tolerance and safety

measures. Reliability and testing. Duplication of least reliable parts (standbye).

Ergonomic, aesthetics and economics. Miniature and microminiature

construction using printed circuits and integrated circuits. Maintainability,

Computer design methods.

TPD 501: Industrial Economics


Course Content: Basic concepts, factors of production, supply and demand, price elasticity

analysis, business organization. The business firm production functions, price

system and competition. Basic principles of Engineering Economy, cost

concepts and analysis. Interests calculations, concept of equivalence and

money-time relationships. Basic methods of engineering economy and their

applications in valuation. Evaluating alternatives. Depreciation, taxation and

replacement studies. Capital budgeting.

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TPD 503: Industrial Law and Management


Course Content:

Principles of Management. Decision theory. Basic concepts in production and

operations management. Plant location and facility layout. Capacity

management, inventory control, scheduling and network analysis. Quality

control, replacement problems. Functions of Law. Basic principles of Nigerian

Law. Engineers and law of contract. Law of business associations. Trade marks

and patents.

B. Rain-Semester Courses (Part-Five) EEE 502: Final Year Project II


Course Content:

This course is the second of two Part-Five project courses. It deals with the

completion of the efforts of EEE 501.

The student uses the theoretical, practical, documentation and articulation skills

acquired over the previous and current sessions to make appropriate practical

project designs, make constructions/simulations of such designs, document the

results of the implementations, write a detailed thesis of the project and make a

formal presentation of the project to assigned members of staff of the

Department.

EEE 504 - Digital Signal Processing


Course Content:

Network synthesis; realizability of driving point impedance, synthesis of two-

terminal networks, Foster form realization, minimum phase and non-minimum

phase networks. Discrete signals and Z-transform, digital Fourier Transform,

fast Fourier transform, the approximation problem in network theory. Filter

design and synthesis. Spectral transforms and their application in the synthesis

of high-pass and band-pass filters. Digital filtering , digital transfer function,

one dimensional recursive and non-recursive filters, computer techniques

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in filter synthesis. Hardware and software realization of filters. Basic image

processing concepts.


EEE 506- Electrical Services and Energy Utilization


Course Content:

Design and organization of power supply: rated voltages and frequency. Types

of power consumers and their characteristics. Lighting systems and installation;

Lighting control circuits, Electrical heating: heating of buildings, electrical

furnaces, electrical welding, air conditioning and refrigeration.

Electro- chemical processes, Motor control for industrial systems; General and

special factory drives. Regulations on installation and operation of electrical

equipment. Metering and tarrif systems


EEE 508 –Reliability and Maintainability of Electrical and Electronic Systems.


Course Content:

Introduction to reliability, maintainability, availability and elementary

reliability theory. Application to power system and electronic components. Test

characteristics of electrical and electronic components. Types of fault.

Designing for higher reliability. Packaging, mounting, ventilation, protection

from humidity and dust.

EEE 510-Micro-Computer Hardware and Software Techniques


Course Content:

Elements of digital computers, computer design; control unit, micro-

programming. Bus: organization and addressing schemes. Microprocessors,

system architecture, bus control, instruction, execution and addressing modes.

Machine code, assembly language and high level language programming.

Micro-processors as state machines, microprocessor interfacing: input/output,

technique, interrupt systems and direct memory access: interfacing system

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development tools, simulators, EPROM

programming, assemblers and loaders. Overview of available microprocessor

and microcomputer systems, operating systems and compiler, Microprocessor

applications.


EEE 516-Control Engineering II


Course Content:

Non-linear differential equations, Characteristics of non-linear systems;

common non-linearities. Analysis of non-linear systems; Linearizing

approximations, piece-wise linear approximation, the describing function

concept and derivation for common non-linearities, the dual input describing

function; stability analysis using the describing function. Limit cycle

prediction. The phase plane method and construction of phase trajectories,

stability analysis by the phase plane method. Introduction to state space

analysis; Matrix representation of control systems. Introduction to sample

data systems; The z-transforms; pulse transfer function and stability analysis in

the z-plane.


EEE 518-Dynamic System Simulation


Course Content:

Analogue and hybrid computer hardware units. Simulation study of different

equations; Generation of time base reference amplitude and time scaling:

simulation of control systems from block diagrams, transfer functions and state

equations, Analogue memory and its applications repetitive and interactive

operation of an analogue computer. Digital Simulation: Comparison of digital

and analogue/hybrid simulation: Block form and expression based languages;

interaction; function generation; iterative computation. Hybrid Computers;

Hardware and software; Assembly routines and interpretive language for

hybrid computing; sequential and

simultaneous hybrid computing. Special applications; On-line computing

processes; Computer techniques for plotting Root-locus Bode Plots etc.,

Minimum fuel and regulator problem by hybrid and digital techniques etc.

Application program in computer aided design of Electronic and Electrical

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Systems.

Prerequiste: EEE 407

TPD 502 – Technology Policy


Course Content:

Science, Technology and Development. Technological change and industrial

development, government intervention in S & T in Nigeria and other

developing countries, S & T policy formulation and implementation. Policy

statements, policy targets, policy instruments and strategies, monitoring devices

and policy review. Technological capability and transfer of technology.

Course Curriculum for the Degree of Bachelor of...

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