Electrical Engineering Technology Ontario College Advanced Diploma
ObjectivesThe innovative three-year Electrical Engineering Technology program has been designed to prepare the student with both theoretical and practical experience, enabling them to work in a wide variety of electrical engineering areas inlcuding alternative energy and process control. After the first two years from which the student has gained experience with electrical motors, controls, PLCs, generators, transformers and their industrial applications, students choose, in the third year of this program, one of two options they wish to specialize in. In third year, students can pursue either the Alternative Energy option or Process Control option. The Alternative Energy option prepares the student for this fast-growing field to work with wind turbines, photovoltaic systems, geothermal, micro-hydro, bio-fuels and various other alternative energy systems. The Process Control option continues with advanced PLC applications as applied to a variety of industrial processes including machine controls, PID controls, batching operations, remote monitoring and servo systems.
Practical experienceThere is a co-op component associated with this program.
Academic titleElectrical Engineering Technology Ontario College Advanced Diploma
Course descriptionLevel One
EECE1090 Electrical Fundamentals
Description: This is the first course in Electrical Fundamentals. No electrical or electronics background is assumed. Topics include: basic atomic structure; electrical current flow in conductors; Ohm's Law; resistors; series and parallel resistor networks; power; Kirchhoff's Laws; magnetism; inductance; capacitance; reactance and transformers. The course concludes with RL and RC circuits; impedance and power.
Hours: 75
Credits: 5
EECE1110 Digital Fundamentals
Description: This course is intended to introduce students to the introductory concepts of digital logic and covers basic logic functions, truth tables, Boolean algebra and circuit reduction techniques for the implementation of combinational logic designs. Sequential logic design principles are included using various bistable devices, counters and registers. Other topics studied include; codes, arithmetic logic units, logic families and applications.
Hours: 75
Credits: 5
EECE1120 Electronic Skills
Description: This practical course develops the student's skills in the fabrication and documentation of electronic prototypes. Topics include sketching, electronic drawing, use of metal working tools, soldering and desoldering techniques. This course is designed as a project oriented course to develop and demonstrate skills required to continue in the electronics field.
Hours: 45
Credits: 3
EECE1130 Computer Aided Design
Description: An introduction to computer aided drafting and design using Autocad. Practical assignments will supplement the theory of other courses.
Hours: 30
Credits: 2
INST1020 Instrumentation And Measurement
Description: This course introduces students to a wide variety of instruments that are used in both the electrical and electronic fields. Topics will include both Analog and Digital Voltmeters, Ohmmeters and Ammeters, as well as Grounds, Oscilloscopes and Signal Generators. How measurements are taken, accuracy of measurements, calibration and contruction of the most commonly used pieces of test equipment.
Hours: 30
Credits: 2
LIBS1540 Student Success for Higher Learning
Description: This course enables students to develop skills that will enhance their success in college. Students will identify their unique learning styles and develop strategies for success in their academic and personal lives.
Hours: 45
Credits: 3
MATH1150 Mathematics I (Electronics)
Description: This course is oriented towards the direct application of mathematical techniques to electrical and electronic fundamentals. The topics include algebraic manipulation, graphs, complex algebra and vectors, linear and quadratic equations, engineering and scientific notation.
Hours: 60
Credits: 4
Level Two
EECE1140 Electrical Fundamentals (Power)
Description: This is the first course in electrical power devices. A brief electrical background is assumed.
Topics include: energy and power, DC circuit theory, electromagnetism, DC motors, AC theory and circuits, AC motors, power transmission and distribution.
Hours: 75
Credits: 5
Pre-Requisites: EECE1090, MATH1150
CoRequisites: MATH1160
EECE1450 Electrical/Electronic Power Devices
Description: This is the first course in electrical/electronic power devices. An understanding of basic electricity is assumed. Topics include: diodes, LEDS, transistors, SCRs, 1 phase rectifiers and other semiconductor devices.
Hours: 45
Credits: 3
Pre-Requisites: EECE1090, INST1020, MATH1150
CoRequisites: MATH1160
INST1010 Introduction To Instrumentation
Description: This course introduces the student to a wide variety of instruments as used in the electrical, electronic and process control industries. The topics covered include: temperature sensors, strain gages, opto-electronic devices, proximity sensors, pressure, level, and flow measuring equipments. In addition there will be some topics on pneumatic type instruments.
Hours: 60
Credits: 4
Pre-Requisites: EECE1090, INST1020
MATH1160 Mathematics II (Electronics)
Description: This is a continuation of Mathematics I and provides for a sound understanding and continued development of trigonometry, algebra, and graphing as related to Electronics.
Hours: 45
Credits: 3
Pre-Requisites: MATH1150
PHYS2010 Magnetic Circuits
Description: Magnetic Circuits introduces the student to the fundamental concepts of magnetism. Magnetic theory is established by investigating the properties of magnetic material and the interaction of currents and magnetic fields. Parallels are drawn between DC circuits and magnetic circuits with the introduction of reluctance, magneto-motive force, permeability, ampere-turns, and hysteresis. Practical applications are made to electrical equipment and related control pieces.
Hours: 30
Credits: 2
Pre-Requisites: EECE1090, MATH1150
PROG1030 Programming
Description: This hands-on course provides an introduction to the C programming language.
Hours: 45
Credits: 3
Electives: General Education
Description: Student must complete a minimum of 36 Hours
Level Three
CNTR2180 Programmable Logic Controllers I
Description: This course introduces the student to the use of modern manufacturing techniques that programmable controllers allow. In an industrial environment where automation is being applied, students will learn that programmable logic controllers can make work easier and safer while maintaining quality, efficiency and productivity.
Hours: 45
Credits: 3
CODE2040 Electrical Code
Description: This course is designed to introduce the student to the Electrical Safety Code. The student will learn to apply the electrical code to various electrical installations.
Hours: 30
Credits: 2
EECE2070 Electrical Projects
Description: This course is designed to give the student the skills and knowledge necessary to complete common repairs to electrical machines and electro-mechanical equipment. The student will develop testing and troubleshooting techniques on standard equipment, learn to sketch and draw components, fabricate simple brackets and parts, solder and perform standard shop practices common to the industry.
Hours: 45
Credits: 3
Pre-Requisites: EECE1120
EECE2100 DC Test Floor Practice
Description: D.C. test floor practice is designed to provide the student with the skills and knowledge necessary to investigate the operating characteristics of D.C. machinery, circuits and associated apparatus and to compare results with other tests. Students will be required to use skills and knowledge obtained in Direct Current Theory to set up, connect and test D.C. equipment.
Hours: 45
Credits: 3
Pre-Requisites: EECE1140, MATH1160, PHYS2010
CoRequisites: EECE2130
EECE2130 DC Motor/Generator And Control Theory
Description: This course is designed to introduce the student to the theory of operation and control of various DC motors. Various types of generators and motors such as shunt, series and compound are studied with particular attention to load testing, efficiency, speed, winding configuration, and connections. Machine control applications introduce the student to voltage regulation, motor starting techniques and various control devices.
Hours: 45
Credits: 3
Pre-Requisites: EECE1140, MATH1160, PHYS2010
CoRequisites: EECE2100
EECE2140 Industrial Power Electronics
Description: This course provides the student with basic troubleshooting techniques for application to industrial power electronic apparatus. The student is given an understanding of the operating principles of a variety of circuits and systems including DC and AC motor drives. The student will also be able to select appropriate test equipment and to locate and repair faults in electronic equipment, components and common systems.
Hours: 45
Credits: 3
Pre-Requisites: EECE1140, EECE1450
EECE2200 Introduction to Alternate Energy
Description: This course is intended to introduce the student to photovoltaic and battery technologies. The student will explore both the theoretical and practical applications of photovoltaic systems. The student will learn the necessary calculations to size a photovoltaic system and incorporate the proper battery sizes for that system.
Hours: 45
Credits: 3
Electives: General Education
Description: Student must complete a minimum of 36 Hours
Level Four
CNTR2040 Programmable Logic Controllers II
Description: This course is split into two sections Part A and Part B. Each section is designed to elevate the student’s previous knowledge of PLCs to allow for sequence controls and data manipulation. The learner will achieve this by applying higher levels of programming instructions and data transfer commands. The various methods of interconnecting PLCs will also be explored to aid in the understanding of the manufacturing process.
Hours: 60
Credits: 4
Pre-Requisites: CNTR2180
EECE2110 Power Transformers
Description: This is the first course in transformers for electrical technicians. A brief electrical background is assumed. Topics include: Basic construction and operation of a transformer, current and voltage relationships, polarity of coils, single phase and three phase arrangements, transformer losses.
Hours: 60
Credits: 4
Pre-Requisites: EECE1140, PHYS2010
EECE2480 AC Test Floor Practice
Description: AC Test Floor Practice is designed to provide the student with the skills and knowledge necessary to prepare test reports and compare operating characteristics of AC machinery, circuits and associated apparatus. Normal and changed conditions affecting efficiency, current and voltage, power, power factor, and frequency are investigated in both large and small machinery and apparatus, which as closely as possible, produce conditions found in industry. Students will be required to use skills and knowledge obtained in Alternating Current Theory to set up, connect, control and test A.C. equipment.
Hours: 45
Credits: 3
Pre-Requisites: EECE2100, EECE2130
CoRequisites: EECE2490
EECE2490 AC Motor/Alternator And Control Theory
Description: This course is designed to introduce the student to the theory of operation and control of various AC motors and alternators. Three-phase and single-phase synchronous and induction machines are studied with respect to operating characteristics and physical configurations. Various control devices are examined with their respective machines.
Hours: 45
Credits: 3
Pre-Requisites: EECE2130
CoRequisites: EECE2480
EECE2500 Safety Standards for Electrical Systems
Description: This course informs the student of the need to be aware of workplace standards. They will learn how machines are made safer to reduce liability and improve productivity. Using a risk assessment will enhance the reasons why safeguarding requirements and techniques are utilized in today’s manufacturing industries.
Hours: 15
Credits: 1
EECE2510 Alternate Energy Practice
Description: The students will learn how to design a solar energy system, by applying necessary calculations to size, solar arrays and batteries required. They will also learn the necessary Code Rules that apply to these installations. Sun charts will be needed to determine battery numbers, total sun hours and proper angles of the system components for a given area. The Standard Offer Contract and Environmental Assessments will also be explored in this course. Connecting and testing of these components on a regular basis to prove the calculations and system design performance will be required.
Hours: 15
Credits: 1
Pre-Requisites: EECE2200
INST2010 Instrumentation for Electrical Systems
Description: This course introduces the student to the application of various types of monitoring and control devices as used in the electrical industry. PID controllers used for motor, temperature and pressure control are among the topics covered. Various topics in Fibre Optics are included.
Hours: 60
Credits: 4
Pre-Requisites: EECE2140, INST1010
Level Five
COMP3010 Advanced Computer Applications
Description: This course is designed to introduce the student to the advanced structure, operation, and programming of a personal computer. The areas covered will include: components of microprocessors and RAM memory, serial I/O, parallel I/O, floppy drives, hard drives, CD/DVD's, and details of the operating system, networking and hardware interfacing. There will also be topics on programming in C and C++, Visual Basic, and engineering applications with Excel spreadsheets.
Hours: 60
Credits: 4
Pre-Requisites: PROG1030
EECE3060 Advanced AC Theory and Power Systems
Description: This course continues the study of AC Theory and uses mathematical principles to solve complex electrical circuits. AC topics include complex series and parallel circuits, harmonics, Fourier analysis and resonance. Additional power systems topics will be as follows: high voltage power transmissions, breakers and switchgear and protection and control systems.
Hours: 60
Credits: 4
Pre-Requisites: EECE2490
EECE3270 Advanced Code
Description: In this course the students will learn to interpret Canadian Electrical Codes in conjunction with all applicable building codes. They will also explore Government requirements as to environmental assessments and regulations pertaining to alternate electrical production systems.
Hours: 15
Credits: 1
Pre-Requisites: CODE2040
MATH3040 Calculus And Mathematical Modelling
Description: Prerequisite(s): OAC or equivalent Calculus and Physics. Completion of Electrical Eng. Technician Program. This course is designed to introduce the student to modelling physical systems with mathematics. The course will include differential equations, laplace transforms, block diagrams, and stability analysis.
Hours: 60
Credits: 4
Pre-Requisites: MATH1160
Electives: General Education
Description: Student must complete a minimum of 36 Hours
Electives: Program Option 1
Description: Student must complete a minimum of 60 Hours
Elective Courses:
EECE3040 Alternative Energy System Design I
Description: This course continues the theory of electric motors covered in the DC Motor/Generator and Control Theory and the AC Motor/Generator and Control Theory courses. It is designed to expand the student's knowledge of the theory of operation, the construction and application of DC commutator machines, induction machines, synchronous machines, AC commutator machines and special machines such as stepper, servo, synchro, linear induction and brushless DC motors.
Hours: 60
Credits: 4
Pre-Requisites: EECE2510
EECE3320 Advanced Machine Control Systems
Description: This course is designed to expand the students knowledge of machine control systems. This course will include additional, advanced PLC controls using AB SLC 500 and Control Logix processors. Applications will focus on motor controls, particularly with interfacing PLC's to electronic drives.
Hours: 60
Credits: 4
Pre-Requisites: CNTR2040
Electives: Program Option 2
Description: Student must complete a minimum of 45 Hours
Elective Courses:
EECE3100 Advanced Digital Electronics
Hours: 45
Credits: 3
Pre-Requisites: EECE1110 EECE3280 Alternative Energy Lab I
Hours: 45
Credits: 3
Pre-Requisites: EECE2510
CoRequisites: EECE3040
Level Six
EECE3030 Transformer Design
Description: This course introduces the student to advanced transformer concepts. Included in the areas of study will be transformer testing and electrical design. Emphasis will be placed on design concepts and the course will include a practical project.
Hours: 60
Credits: 4
Pre-Requisites: EECE2110
MATH3030 Advanced Mathematical Modelling
Description: This course is designed to introduce the student to differential equations as applied to electrical systems. A variety of problems and solutions will be considered.
Hours: 60
Credits: 4
Pre-Requisites: MATH3040
Electives: Program Option 3
Description: Student must complete a minimum of 45 Hours
Elective Courses:
EECE3150 Process/Batch Control Systems
Description: This course is organized to introduce the student to the concepts of applying logic to the solution of problems. Basic principles will be used to solve various levels of electrical problems.
Hours: 60
Credits: 4
Pre-Requisites: INST2010
EECE3220 Alternative Energy Lab II
Description: Prerequisite(s): Electric Motor Theory This course is designed to introduce the student to some of the important aspects of designing and re-designing electric machines. The areas covered would include: flux densities, stator-rotor slot combiniations, maximum rotor diameters, cord factors, distribution factors, amperage/ACM requirements, multi-speed windings, and star/delta Winding connections. This course would include a practical technology project.
Hours: 45
Credits: 3
Pre-Requisites: EECE3040, EECE3280
CoRequisites: EECE3290
Electives: Program Option 4
Description: Student must complete a minimum of 60 Hours
Elective Courses:
CNTR3050 Electronic Machine Controls
Description: Prerequisite(s): Completion of Electrical Eng. Technician Program and OAC (or equivalent) Calculus and Physics. This course is designed to introduce the student to power electronic applications. The subject matter will concentrate on DC and AC drives, servo systems and robotic controls. The student will be required to design and build a project using power electronic devices. Some emphasis will be placed on troubleshooting techniques.
Hours: 60
Credits: 4
Pre-Requisites: EECE3320
EECE3290 Alternative Energy System Design II
Hours: 60
Credits: 4
Pre-Requisites: EECE3040, EECE3280
Electives: Program Option 5
Description: Student must complete a minimum of 30 Hours
Elective Courses:
EECE3300 Planning and Installation
Hours: 45
Credits: 3
Pre-Requisites: EECE3040
CoRequisites: EECE3290
EECE3310 OPC Systems for PLCs
Hours: 30
Credits: 2
Pre-Requisites: EECE3320
CoRequisites: CNTR3050
Electives: Program Option 6
Description: Student must complete a minimum of 60 Hours
Elective Courses:
EECE3330 Final Project/Report - PC
Hours: 60
Credits: 4
Pre-Requisites: EECE3320