ELECTROMAGNETICS | SYLLABUS | IOE | 2066

ELECTROMAGNETICS

EX 503
Lecture  :  3
year  :   II
Tutorial  :  1  
Part  :   I
Practical  :  3/2

Course Objectives:
To provide basic understanding of the fundamentals of Electromagnetics.

1.  Introduction  (3 hours)
1.1  Co-ordinate system.
1.2  Scalar and vector fields.
1.3  Operations on scalar and vector fields.

2.  Electric field     (11 hours)

DIGITAL LOGIC | SYLLABUS | IOE | 2066

DIGITAL LOGIC

EX 502

Lecture  :   3
Year  :   II
Tutorial  :   0    
Part  :   I
Practical  :  3  

Course Objective:
To introduce basic principles of digital logic design, its implementation and applications.

1.  Introduction   (3 hours)

1.1.  Definitions for Digital Signals
1.2.  Digital Waveforms
1.3.  Digital Logic
1.4.  Moving and Storing Digital Information
1.5.  Digital Operations
1.6.  Digital Computer
1.7.  Digital Integrated Circuits
1.8.  Digital IC Signal Levels
1.9.  Clock wave form
1.10.  Coding
1.10.1.  ASCII Code
1.10.2.  BCD
1.10.3.  The Excess – 3 Code
1.10.4.  The Gray Code

2.  Digital Logic  (1 hours)

2.1.  The Basic Gates – NOT, OR, AND
2.2.  Universal Logic Gates – NOR, NAND
2.3.  AND-OR-INVERT Gates
2.4.  Positive and Negative Logic
2.5.  Introduction to HDL

ELECTRONIC DEVICES AND CIRCUITS | SYLLABUS | IOE

ELECTRONIC DEVICES AND CIRCUITS

EX 501
Lecture  :   3            
Year  :  II
Tutorial  :   1    
Part  :   I
Practical  :   3/2

Course Objectives:
•  To introduce the fundamentals of analysis of electronic circuits
•  To provide basic understanding of  semiconductor devices and analog integrated circuits

1.  Diodes  (5 hours)

1.1  The Ideal Diode
1.2  Terminal Characteristics of Junction Diodes
1.3  Physical Operation of Diodes
1.4  Analysis of Diode Circuits
1.5  Small Signal Model and Its Application
1.6  Operation in the Reverse Breakdown Region - Zener Diodes

2.  The Bipolar Junction Transistor            (10 hours)

THEORY OF COMPUTATION | SYLLABUS | IOE | SECOND YEAR

THEORY OF COMPUTATION

CT 502
Lecture  :   3    
year  :  II
Tutorial  :   1    
Part  :   I
Practical  :  0      
      
Course Objectives:
To provide basic understanding of theory of automata, formal languages, turing machines and computational complexity.

1.  Introduction   (4 hours)
1.1  Set, relation, function, Proof techniques.
1.2  Alphabets, language, regular expression.

2.  Finite Automata   (12 hours)
2.1  Deterministic Finite Automata.
2.2  Non-Deterministic Finite Automata.
2.3  Equivalence of regular language and finite automata.
2.4  Regular language, properties of regular language.
2.5  Pumping lemma for regular language.
2.6  Decision algorithms for regular languages.

ELECTRIC CIRCUIT THEORY | SYLLABUS | IOE

ELECTRIC CIRCUIT THEORY

EE 501
Lecture  :   3
Year  :   II
Tutorial  :   1    Part   :   I
Practical  :   1.5

Course Objectives:
To continue work in Basic Electrical  Engineering  including the use of the Laplace Transform to determine the time and frequency domain responses of electric circuits.

1.  Network Analysis of AC circuit & dependent sources    (8 hours)
1.1  Mesh Analysis
1.2  Nodal Analysis
1.3  Series & parallel resonance in RLC circuits
1.3.1  Impedance and phase angle of series Resonant Circuit
1.3.2  Voltage and current in series resonant circuit
1.3.3  Band width of the RLC circuit.
1.3.4  High-Q and Low-Q circuits

2.  Initial Conditions:          (2 hours)
2.1  Characteristics of various network elements
2.2  Initial value of derivatives
2.3  Procedure for evaluating initial conditions
2.4  Initial condition in the case of R-L-C network

OBJECT ORIENTED PROGRAMMING | SYLLABUS | MARKING SCHEME | IOE

OBJECT ORIENTED PROGRAMMING

CT 501
Lecture  :   3    
Year  :   II
Tutorial   :   0    
Part  :    I
Practical  :   3    

Course Objective:
The objective of the course is to familiarize students with the C++ programming language and use the language to develop pure object oriented programs.

1.  Introduction to Object Oriented Programming  (3 hours)

1.1  Issues with Procedure Oriented Programming
1.2  Basic of Object Oriented Programming (OOP)
1.3  Procedure Oriented versus Object Oriented Programming
1.4  Concept of Object Oriented Programming
1.4.1  Object
1.4.2  Class
1.4.3  Abstraction
1.4.4  Encapsulation
1.4.5  Inheritance
1.4.6  Polymorphism
1.5  Example of Some Object Oriented Languages
1.6  Advantages and Disadvantages of OOP

ENGINEERING MATHEMATICS III | SYLLABUS | IOE | SECOND YEAR

ENGINEERING MATHEMATICS III

SH 501
Lecture  :   3
Year  :   II
Tutorial  :   2
Part  :   I
Practical  :   0

Course Objective:
The purpose of this course is to round out the students’ preparation for more sophisticated applications with an introduction to linear algebra, Fourier Series, Laplace Transforms, integral transformation theorems and linear programming.
1.  Determinants and Matrices       (11 hours)
1.1.  Determinant and its properties
1.2.  Solution of system of linear equations
1.3.  Algebra of matrices
1.4.  Complex matrices
1.5.  Rank of matrices
1.6.  System of linear equations
1.7.  Vector spaces
1.8.  Linear transformations
1.9.  Eigen value and Eigen vectors
1.10.  The Cayley-Hamilton theorem and its uses
1.11.  Diagonalization of matrices and its applications

WORKSHOP TECHNOLOGY | SYLLABUS | IOE | FIRST YEAR

WORKSHOP TECHNOLOGY

ME 453
Lecture  :   1  
Year: I
Practical  :   3
Part: I/II

Course Objective:
The subject aims at imparting knowledge and skill components in the field of basic workshop technology. It deals with different hand and machine tools required for manufacturing simple metal components and articles.

Objectives:
After the completion of the course, the student shall be able to
1.  Practice workshop safety rules effectively
2.  Acquire knowledge and use simple hand tools
3.  Acquire knowledge and use simple measuring and gauging instruments
4.  Operate simple drilling machines for producing small holes
5.  Operate various machine tools for producing simple metal components and articles
6.  Acquire knowledge and practice on foundry, forging and welding

1.  General safety Considerations    (2 hours)
1.1.  Bench Tools                  
1.2.  Machinist’s Hammers
1.3.  Screw Drivers
1.4.  Punches
1.5.  Chisels
1.6.  Scrapers
1.7.  Scribers
1.8.  Files
1.9.  Pliers and Cutters
1.10.  Wrenches
1.11.  Hacksaw
1.12.  Bench Vise
1.13.  Hand drill
1.14.  Taps and Dies
1.15.  Hand Shears
1.16.  Rules, Tapes and Squares
1.17.  Soldering Iron
1.18.  Rivets

FUNDAMENTALS OF THERMODYNAMICS | SYLLABUS | IOE | 2066

FUNDAMENTALS OF THERMODYNAMICS AND HEAT TRANSFER

ME 452
Lectures  :  3
Year  : I
Tutorial  :  1
Part  : I/II
Practical  :  1.5

Course Objectives:
After the completion of this course, students will able to understand basic concepts, laws of thermodynamics and heat transfer and their applications as well.

1.  Introduction   (4 hours)
1.1.  Definition and Scope of Engineering Thermodynamics
1.2.  Value of energy to society
1.3.  Microscopic versus Macroscopic Viewpoint
1.4.  Concepts and Definitions
1.4.1.  System, Surroundings, Boundary and Universe; Closed Systems, Open Systems, and Isolated Systems
1.4.2.  Thermodynamic Properties: Intensive, Extensive and Specific Properties
1.4.3.  Thermodynamic Equilibrium
1.4.4.  State, Process, and Path
Cyclic Process, Quasi-equilibrium Process, Reversible and Irreversible Process
1.4.5.  Common Properties: Pressure, Specific Volume, Temperature
1.5.  Zeroth Law of Thermodynamics, Equality of Temperature  

2.  Energy and Energy Transfer  (3 hours)
2.1.  Energy and its Meaning
2.2.  Stored Energy and Transient Energy; Total Energy
2.3.  Energy Transfer
2.3.1.  Heat Transfer
2.3.2.  Work Transfer
2.4.  Expressions for displacement work transfer  
2.5.  Power

Engineering Chemistry | Syllabus | Marking Scheme | 2066

ENGINEERING CHEMISTRY
SH 453
Theory  :  3
Year   : I
Tutorial  :  1
Part  : I/II
Practical  :  3

Course objectives:  
To develop the basic concepts of Physical Chemistry, Inorganic Chemistry and Organic Chemistry relevant to problems in engineering.

1.  Electro-chemistry and Buffer   (6 hours)
1.1.  Electro-chemical cells
1.2.  Electrode Potential and Standard Electrode Potential
1.3.  Measurement of Electrode Potential
1.4.  Nernst equation
1.5.  EMF of Cell
1.6.  Application of Electrochemical and Electrolytic cells
1.7.  Electrochemical Series and its Application
1.8.  Buffer: its type and mechanism
1.9.  Henderson’s equation for pH of buffer and related problems
1.10.  Corrosion and its type
1.11.  Factors influencing corrosion
1.12.  Prevention of corrosion

2.  Catalyst  (4 hours)
2.1.  Introduction
2.2.  Action of Catalyst (Catalytic Promoters and Catalytic Poisons)
2.3.  Characteristics of Catalyst
2.4.  Types of Catalyst
2.5.  Theories of Catalysis
2.6.  Industrial Applications of Catalysts

BASIC ELECTRONICS | Syllabus | Marking Scheme | BE First Year Second Part

BASIC ELECTRONICS ENGINEERING

EX 451
Lecture  :   3
Year  :   I
Tutorial  :  1 
Part  :   II
Practical  :   3/2

Course Objectives:
•  To understand the language of electronics, elements and their functionality
•  Basic understanding of analog systems and their applications
•  Basic understanding of digital systems and their applications

1.  Basic Cirtuits Concepts   (4 hours)
1.1  Passive components: Resistance, Inductance, Capacitance; series, parallel combinations; Kirchhoff's law: voltage, current; linearity
1.2  Signal sources: voltage and current sources; nonideal sources; representation under assumption of linearity; controlled sources: VCVS, CCVS, VCCS, CCCS; concept of gain, transconductance, transimpedance.
1.3  Superposition theorem; Thevenin's theorem; Norton's theorem
1.4  Introduction to filter

2.  Diodes  (7 hours)
2.1  Semiconductor diode characteristics
2.2  Modeling the semiconductor diode
2.3  Diode circuits: clipper; clamper circuits
2.4  Zener diode, LED, Photodiode, varacters diode, Tunnel diodes
2.5  DC power supply: rectifier-half wave, full wave (center tapped, bridge), Zener regulated power supply

Engineering Drawing II | BE First Year Second Part | Syllabus

ENGINEERING DRAWING II
ME 451

Lecture:  1
Year:      1
Tutorial: 0
Part:        II
Practical:3

COURSE OBJECTIVE: 
To make familiar with the conventional practices of sectional views. To develop basic concept and skill of pictorial drawing and working drawings. Also to make familiar with standard symbols of different engineering fields.
 
COURSE OUTLINE:

1. Conventional Practices for Orthographic and Sectional Views (12hours)

1.1 Conventional Practices in Orthographic views: Half Views and Partial Views, Treatment of Unimportant Intersections, Aligned Views, Treatment for Radially Arranged Features, Representation of Fillets and Rounds
1.2 Conventional Practices in Sectional views: Conventions for Ribs, Webs and Spokes in Sectional View, Broken Section, Removed Section, Revolved Section, Offset Section, Phantom Section and Auxiliary Sectional Views
1.3 Simplified Representations of Standard Machine Elements

Engineering Mathematics II | BE Syllabus | First Year Second Part | IOE | 2066

ENGINEERING MATHEMATICS II

SH 451
Lecture: 3
Year: 1
Tutorial: 2
Part: II

Course Objectives:
i) To develop the skill of solving differential equations and to provide knowledge of vector algebra and calculus
ii) To make students familiar with calculus of several variables and infinite series

1.  Calculus of two or more variables  (6 hours)
1.1.  Introduction: limit and continuity
1.2.  Partial derivatives 
1.2.1.  Homogeneous function, Euler’s theorem for the function of 
two and three variables 
1.2.2.  Total derivatives
1.3.  Extrema of functions of two and three variables; Lagrange’s Multiplier

2.  Multiple Integrals  (6 hours)
2.1.  Introduction
2.2.  Double integrals in Cartesian and polar form; change of order of integration
2.3.  Triple integrals in Cartesian, cylindrical and spherical coordinates;
2.4.  Area and volume by double and triple integrals

Master Entrance for Electrical Engineering | IOE | Syllabus | Model Question | 2066

Master Entrance for Electrical Engineering at IOE consist of 2 section, 120 marks and 3 hours. The details of question for master entrance is as follow.

SECTION A

1. Basic Electrical Circuits (12)

• Circuit fundamentals: Series & parallel circuits, circuit elements, independent & dependent
sources, Ohms law, Krichoff’s Voltage & Current Laws
• Network Theorems: Thevenin’s, Nortan’s, Maximum power & Reciprocity Theorems
• AC circuits: Concept of complex impedance, Phasor diagram, Active, Reactive &
Apparent power, Resonance in AC circuits
• Three phase circuits: Phase & line quantities in three phase system, 3-phase power
• Transient response: Transient response analysis for R-L, R-C & R-L-C circuits. Pole zero plots
• Two port Networks: Z -parameters, Y-parameters & ABCD-parameters

2. Electrical Machines (12)

• Electromagnets: Magnetic circuits, Fleming’s Right hand & Left hand rules, Farady’s Law of electromagnetic induction, Electromechanical energy conversion principle
• Transformers: Equivalent circuits, Phasor diagrams, Losses & efficiency, Voltage regulations, Instrument transformers, three phase transformer connections, parallel operation of 1-N & 3-N Transformers
• Synchronous m/c: Operating principle, Effect of excitation, Power angle characteristic, Phasor diagrams, Losses & efficiency, Voltage regulations, parallel operation of alternator
• Induction machine: Operating principle, T-S Characteristics, Losses and efficiency, Testing, Starting methods, Speed control
• DC motor: Operating principle, Characteristics of different types dc motor, Speed control and starter

Master in Mechanical & Industrial Engineering | Entrance Exam | Model Question | Syllabus | Marking Scheme | IOE

IOE Entrance Exam for Master in Mechanical Engineer consist of 2 section, 120 marks and 3 hours. The details of question sources is as follow.

SECTION B

1. Thermodynamics and Heat Transfer [14]

• Equality of Temperature and Zeroth Law of Thermodynamics, Heat Transfer and Work Transfer
• Control Mass and Control Volume Formulation of First Law, Steady State Applications
• Entropy, Second Law of Thermodynamics for an Isolated System, Control Mass and Control Volume Formulation of
• Second Law, Entropy Relations and Isentropic Process, Heat Engine, Heat Pump and Refrigerator
• Carnot Cycle, Brayton Cycle, Rankin Cycle, Otto Cycle, Diesel Cycle, Vapour Compression Cycle
• One dimensional steady state heat conduction through a plane wall, Radial steady state heat conduction through a hollow cylinder, Heat flow through composite structures, Electrical Analogy for thermal resistance, Convection Fundamentals and Radiation Heat Transfer Fundamentals

2. Fluid Mechanics and Fluid Machine [14]

• Basic concepts of fluid and flow
• Flow measurement
• Continuity equation, Momentum equation, Bernoull’s equation and their applications
• Viscous flow, flow inside closed conduits and head losses
• Water turbines
• Water pumps

Entrance in Civil or Agricultural Engineering | Model Question | Syllabus | IOE | 2066 | CA

Master Syllabus for civil engineering student contains 2 sections. Each section of 60 marks. Section A consist question from mathematics (45 marks) and GRE English (15 marks). Section B consist question from core subject read at 4 years bachelor of engineering. The detail of syllabus is as follow.

SECTION-A 
The depth of subject matter in this section shall be similar to GRE. 

1. Critical Reasoning [5 ××× 3] 

Critical reasoning sections aim to test the candidate's comprehension of the interpretative abilities in English as a language of business and communication. Critical reasoning questios measure your ability to read with understanding, insight and discrimination. These questions explore your ability to analyze a written passage from several perpectives, including your ability to recognize explicitly stated elements as well as underlying statements or arguments and their implications. This section measures reading comprehension and critical reasoning skills in a multiple-choice format. 
The Critical reasoning section measures your ability to: 
• analyze and evaluate written material and synthesize information obtained from it. 
2. Mathematics [45 ××× 1] 

Applied Mechanics | Syllabus | Marking Scheme | First Year | 2066

APPLIED MECHANICS
CE  401
Lecture   :  3
Year      :  1
Tutorial  :  2
Part      :  II

Course Objective :
This course has been designed to provide basic knowledge of engineering mechanics to the students of all branches of engineering so that it would be helpful for them to understand structural engineering stress analysis principles in later courses or to use basics of mechanics in their branch of engineering. This course shall be considered as an introduction: common for all engineering faculties of Tribhuvan University in the first year of undergraduate. Emphasis has been given to Statics.

1  Introduction  (2 hours)
1.1 Definitions and scope of Applied Mechanics
1.2 Concept of Rigid and Deformed Bodies
1.3 Fundamental concepts and principles of mechanics: Newtonian Mechanics

2  Basic Concept in Statics and Static Equilibrium (4 hours)
2.1 Concept of Particles and Free Body Diagram
2.2 Physical meaning of Equilibrium and its essence in structural application
2.3 Equation of Equilibrium in Two Dimension

Basic Electrical Engineering | First year | Syllabus | Marking Scheme | 2066

BASIC ELECTRICAL ENGINEERING

EE 401
Lecture    : 3
Year       :  I
Tutorial   : 1
Part       :  I/II
Practical  : 3/2

Course Objectives: After completion of this course the student will understand the fundamental concept of DC, AC & 3-phase electrical circuits.

1  General Electric System (6 hours)
1.1  Constituent parts of an electrical system (source, load, communication & control)
1.2  Current flow in a circuit
1.3  Electromotive force and potential difference
1.4  Electrical units
1.5  Ohm’s law
1.6  Resistors, resistivity
1.7  Temperature rise & temperature coefficient of resistance
1.8  Voltage & current sources

2  DC circuits (4 hours)
2.1  Series circuits
2.2  Parallel networks
2.3  Krichhhof’s laws
2.4  Power and energy

Engineering Physics | Syllabus | Marking Scheme | First Year | 2066

ENGINEERING PHYSICS
SH 402

Theory    : 4
Year      : I
Tutorial  : 1
Part      : I/II
Practical : 2

Course objectives: To provide the concept and knowledge of physics with the emphasis of present day application. The background of physics corresponding to Proficiency Certificate Level is assumed.

1  Oscillation:  (7 hours)
1.1  Mechanical Oscillation: Introduction
1.2  Free oscillation
1.3  Damped oscillation
1.4  forced mechanical oscillation
1.5  EM Oscillation: Free, damped and Forced electromagnetic oscillation

2  Wave motion   (2 hours)  
2.1  Waves and particles,
2.2  Progressive wave,
2.3  Energy, power and intensity of progressive wave

Engineering Drawing I | IOE | First Year | Syllabus | Marking Scheme | 2066

ENGINEERING DRAWING I
ME 401

Lectures     : 1  
Year     : I
Tutorial     :   
Part      : I
Practical    : 3     
                       
Course Objective:            
To develop basic projection concepts with reference to points, lines, planes and geometrical solids. Also to develop sketching and drafting skills to facilitate communication.

1.       Instrumental Drawing,  Technical Lettering Practices and Techniques  (2 hours)
1.1.            Equipment and materials                
1.2.            Description of drawing instruments, auxiliary equipment and drawing materials 
1.3.            Techniques of instrumental drawing   
1.4.            Pencil sharpening, securing paper, proper use of T- squares, triangles, scales dividers, compasses, erasing shields,  French curves, inking pens
1.5.            Lettering strokes, letter proportions, use of pencils and pens, uniformity and appearance of letters, freehand techniques, inclined and vertical letters and numerals, upper and lower cases, standard English lettering forms

Matlab | Resources for Beginner | Video Tutorial | Matlab in 30 Minutes

Matlab Best Video Tutorial Resources for Beginners | Starting with Matlab

Below listed video are the best resources I have ever seen for matlab beginner. It assume that you have no programming background. For those, who have programming background also able to take benefit from these video.

1. Introduction to MATLAB

  • What is MATLAB? http://youtu.be/ahtUo7YguI8
  • The MATLAB Environment http://youtu.be/ULAlTJ-Tnks


2.Mathematical operations in MATLAB

  • MATLAB Variables http://youtu.be/HZhBcoiNRIc
  • MATLAB as a Calculator http://youtu.be/5NdCBMAUG2s
  • Mathematical Functions http://youtu.be/GDBhqEvpTDo


3. Vectors in MATLAB

  • Creating Vectors via Concatenation http://youtu.be/GUoIkyh4XaM
  • Creating Uniformly Spaced Vectors (Colon Operator) http://youtu.be/CZf-9CXgZfU
  • Accessing Elements of a Vector http://youtu.be/l41Pvbwk1XQ
  • Vector Arithmetic http://youtu.be/1ZbFr9YJMFg
  • Logical Operators http://youtu.be/Sv_6CpAEea8
  • Conditional Data Selection http://youtu.be/HXnOE0xFMbA


COMPUTER PROGRAMMING | C | Syllabus | Marking Scheme | IOE |

COMPUTER PROGRAMMING
CT 401
Lecture : 3 
Year : I
Part  : I
Practical : 3

Course Objective:      To acquaint the student with computer software and high level programming languages. Emphasis will be given on developing computer programming skills using computer programming in C and FORTRAN languages.
1.              Overview of computer software & programming languages  (2 hours)
1.1.       System software
1.2.       Application software
1.3.       General software features and recent trends
1.4.       Generation of programming languages
1.5.       Categorization of high level languages

Engineering Mathematics I | BE Syllabus | Marking Scheme

ENGINEERING MATHEMATICS I
EG ……SH

Lecture:  3 
Year: I
Tutorial: 2
Part: I
Practical :

Course Objectives:     
To provide students a sound knowledge of calculus and analytic geometry to apply them in their relevant fields.

1.          Derivatives and their Applications   (14 hours)
1.1.       Introduction
1.2.       Higher order derivatives
1.3.       Mean value theorem
1.3.1.     Rolle’s Theorem
1.3.2.     Lagrange’s mean value theorem
1.3.3.     Cauchy’s mean value theorem
1.4.       Power series of single valued function
1.4.1.     Taylor’s series
1.4.2.     Maclaurin’s series
1.5.       Indeterminate forms; L’Hospital rule
1.6.       Asymptotes to Cartesian and polar curves
1.7.       Pedal equations to Cartesian and polar curves; curvature and radius of curvature

IOE BE Entrance Exam Leak Question - 2069

BE - 2069 Leaked question and answer (IOE Bachelor of Engineering Entrance Exam).