The Electronics CBT software provides flexible, skills-based education in basic electronics. The learning package provides an overview of Current, Voltage, Resistance, Ohm's Law, Parallel and Series Circuits, Magnetism, AC/DC Circuits Capacitance, Inductance, Transformers, Resonance, Filters, Transistors, Semiconductors, Amplifiers, Op Amps and Digital Electronics.
The multimedia program presents twenty-four modules of interactive curriculum using text, video, 2D and 3D animations, photos, audio clips and interactive lab simulations. The Electronics CBT presents an in-depth, interactive coverage of the fundamentals of electronics, built within an innovative state-of-the-art computer-based training and simulation environment. The module material is delivered using video, audio, text, 2D and 3D animations, photos, and over 450 simulation-based laboratory exercises using CircuitLogix Pro. Click on the link below for a demonstration of the lab simulation software used in the Electronics CBT.
The following links provide you with detailed descriptions of the modules contained in the Electronics Technician CBT.
Module 1 - INTRODUCTION TO ELECTRONICS
This module is designed to introduce the student to the fundamental concepts of electronics and describe some basic applications. This module covers units of measure, scientific notation, SI system, and engineering notation. The principles of molecules and atomic structure are also presented in this module as well as an introduction to electric charges.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 2 - CURRENT, VOLTAGE, & RESISTANCE
This module introduces students to the fundamentals of current, voltage and resistance. In addition, the module introduces essential concepts such as the relationship between temperature and resistance, electron velocity, and the direction of current flow. The module also covers wire sizes, the resistor color code, and troubleshooting resistors.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 3 - OHM'S LAW, POWER, & ENERGY
This module is designed to cover the fundamentals of Ohm's law, work, energy and power. A discussion of power dissipation and rating of circuit components is presented, as well as efficiency, the kilowatt hour. The theoretical and practical aspects of basic circuit calculations are also presented in this module using a combination of video, animation, and a laboratory projects using CircuitLogix.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 4 - SERIES CIRCUITS
This module covers resistance, current, and voltage in a series circuit, and presents an introduction to the polarity of voltages, voltage dividers, and the concept of internal resistance. The student will learn to apply Kirchhoff's voltage law to solve problems and design voltage dividers. Fuses and switches are also presented with an emphasis on practical applications and troubleshooting.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 5 - PARALLEL CIRCUITS
This module will provide the student with an introduction to voltage in parallel circuits and the application of Ohm's law to these circuit configurations. The module is designed to demonstrate the effect of current, voltage, and resistance in parallel circuits and describe how Kirchhoff's current law can be applied to problem solving and troubleshooting techniques.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 6 - SERIES PARALLEL CIRCUITS
This module covers resistance, current, and voltage in series parallel circuits. The student will learn to apply Ohm's law to solving for specific quantities in these circuit configurations. The module also covers power, loaded voltage dividers and the Wheatstone Bridge as well as troubleshooting applications and problem solving.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 7 - DC MEASURING INSTRUMENTS
This module includes the study of both analogue and digital dc measuring instruments including ammeters, voltmeters, and ohmmeters. Voltmeter loading and sensitivity are presented with an emphasis on practical applications and safe operation of these instruments. This module also covers multimeters, electronic meters, and an introduction to digital measuring instruments.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 8 - NETWORK THEOREMS
Network Theorems provides an overview of fundamental circuit analysis techniques. The student will learn the methods used to solve problems using loop analysis, Nodal analysis, Thévenin's theorem, Norton's theorem, and the Superposition theorem. The maximum power transfer theorem is emphasized by demonstrating both theoretical and practical considerations of power expended versus power consumed. This module also covers Millman's theorem and the conversion voltage and current sources.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 9 - MAGNETISM
This module provides an introduction to magnetism including the nature of magnetism, magnetic fields, and magnetic materials. Electromagnets and permanent magnets are also presented using a combination of video and animation allowing the student to gain a better understanding of magnetic field theory. The Hall effect sensor is also introduced in this module.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 10 - MAGNETIC CIRCUITS
This module will focus on the magnetic circuit and the magnetic properties of materials. The student will learn the principles of magnetic force, reluctance, permeance, and permeability. Ampere's circuit law is also discussed as well as design considerations for air gaps in magnetic circuits. This module also introduces the student to the effects of magnetic hysteresis and residual magnetism on a magnetic circuit.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 11 - ALTERNATING VOLTAGES & CURRENTS
This module introduces the student to the fundamentals of alternating voltages and currents. In addition to sine waves, the module also covers non sinusoidal waveforms and harmonic frequencies. The principles of frequency, period, and wavelength are presented emphasizing practical applications and troubleshooting techniques. Theoretical areas of study include instantaneous, RMS and average values of sine waves.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 12 - AC MEASURING INSTRUMENTS
This module includes the study of both analogue and digital AC measuring instruments including ammeters, voltmeters and ohmmeters. Oscilloscopes, signal generators, and frequency counters are presented with an emphasis on practical applications and safe operation of these instruments. This module is designed to reinforce troubleshooting techniques using AC meters.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 13 - CAPACITANCE AND CAPACITORS
This module covers the principles of capacitance including relative permittivity, dielectric strength and leakage current. The types of capacitors covered in this module include electrolytic, ceramic, mylar and tantalum. Series and parallel configurations of capacitor circuits are included in the module as well as an introduction to bypass and coupling capacitors.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 14 - INDUCTANCE AND INDUCTORS
This module introduces the student to electromagnetic induction, Faraday's law and Lenz's law. Various types of inductors are described and the student will learn to calculate the values of transients in RL circuits. This module also covers inductors in series and parallel, and the effect on current, voltage and inductive reactance in these circuits.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 15 - TRANSFORMERS
This module is designed to present an overview of transformers and their applications in electronic circuits. Module work will be primarily based on transformer principles, design considerations and reinforcement of key concepts such as reflected load and maximum power transfer. Transformer types such as pulse, center tap, multiple winding and auto transformers are also discussed.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 16 - ALTERNATING CURRENT CIRCUITS
This module includes resistance in ac circuits, inductive reactance and capacitive reactance as well as coverage of impedance and the impedance triangle. In addition the module is designed to provide the student with an overview of series and parallel RL, RC and RLC circuits. The module also introduces the student to power in ac circuits and effective resistance.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 17 - RESONANCE
This module will build on previous topics by presenting an introduction to resonance in series and parallel circuits. The module also covers bandwidth, tuning circuits, and the decibel. The Q of a series circuit is also presented using practical and theoretical examples of problem solving for resonance.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 18 - COUPLING AND FILTER CIRCUITS
It is in this module that the student learns the principles of direct coupling, transformer coupling, and capacitive coupling. Filter circuit such as low pass, high pass, band pass and band stop filters are presented emphasizing practical design and troubleshooting considerations. An introduction to Bode plots and active filters is also covered in this module. Bode plot assignments are completed using laboratory software.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 19 - SEMICONDUCTOR FUNDAMENTALS
This module introduces the student to the PN junction and i application in modern electronic circuits. Semiconductor diodes and configurations such as half wave and full wave rectifiers are presented using both theoretical and practical examples which are reinforced by laboratory experiments. Other diodes such as Zener, Varactor, and Light Emitting Diodes (LEDs) are also introduced in this module.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 20 - TRANSISTORS AND THYRISTORS
Bipolar Junction Transistors (BJTs) are covered in this module and their application in amplifier and switching circuits is also presented. This module also introduces Field Effects Transistors (FETs), and thyristors such as Silicon Controlled Rectifiers (SCRs) and Triacs. In addition the module also includes transistor troubleshooting problems and assignments as well as laboratory experiments for transistor circuits.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 21 - AMPLIFIER CIRCUITS
This module covers common base, common collector and common-emitter amplifiers. In addition, the student is introduced to the effect of AC signals on amplifiers, FET amplifiers and multistage amplifiers. The student will also learn the differences between Class A, B, and C amplifiers and their applications in industry. Emphasis is placed on design, problem solving, and troubleshooting of amplifier circuits.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 22 - INTEGRATED CIRCUITS
This module will provide the student with an overview of operational amplifiers and their characteristics. The student will learn basic op amp configurations such as inverting and non inverting amplifiers, as well as summing amplifiers and comparators. An introduction to analogue to digital converters is also presented in this module. Integrators, differentiators, oscillators and active filters are included emphasizing real world control applications.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 23 - DIGITAL ELECTRONICS
This module covers a wide variety of topics relating to digital electronics including number systems, logic gates, flip flops and counters. Boolean algebra and DeMorgan's theorem is also introduced as well as troubleshooting and problem solving techniques for digital logic circuits. The logic gates presented in the module include AND, OR, NOR, NAND and inverters.
Learning Outcomes:
Upon completion of this module the student will be able to:
Module 24 - MICROPROCESSORS
This module provides an overview of the basic theory and operation of microprocessors and their logical and programming characteristics. It will introduce the concepts of instruction sets, machine language programming, input/output, interrupts and interfacing techniques. Hardware and software aspects of popular 8-bit and 32-bit microprocessors are studied in detail. Specific topics include microprocessor architecture (registers, memory maps, status, program counter, and stack), logic operations, assembly language programming, embedded-systems design and an introduction to control algorithms. In addition, the module also covers microcontrollers and an introduction to PC architecture.
Learning Outcomes:
Upon completion of this module the student will be able to: