Electric Circuits Complete Training
Step into the world of Electrical Circuits with our transformative course. Explore operational amplifiers and unravel capacitors and inductors. Elevate your expertise for a charged future.
Course Highlights
The Electric Circuits Complete Training course is your one-stop shop for learning everything you need to know about electric circuits. From the basics of voltage and current to advanced topics like circuit analysis and theorems, this course will teach you everything you need to become a certified electrical engineer. This course isn’t just a collection of units; it’s a transformative experience that will reshape your understanding of circuits. Imagine peeling back the layers of mystery that shroud the behaviour of electrons, revealing the intricate dance of currents and voltages that power our modern lives.
From the very first unit, you’ll be drawn into a tapestry of knowledge where basic concepts become the foundation upon which you’ll construct your expertise. As you progress, the journey unfolds through the corridors of basic laws and methods of analysis, guiding you towards the heart of circuitry’s core principles. But this isn’t just theory – brace yourself for interactive simulations that let you witness the magic of circuits coming to life before your eyes.
Venture deeper, and you’ll encounter the enlightening world of operational amplifiers, where abstract concepts materialise into powerful tools used in countless electronic applications. Capacitors and inductors, often shrouded in mystique, will be demystified, allowing you to wield their potential confidently.
Are you ready to step into the realm of electric circuits like never before? This course isn’t just about learning – it’s about transformation. Whether you’re an aspiring engineer, a curious tinkerer, or someone seeking a deeper understanding of the technology shaping our world, this journey will equip you with skills that resonate far beyond the confines of the classroom. Let your curiosity ignite, your understanding deepens, and your potential be amplified with Electric Circuits Complete Training.
Learning outcome
- Grasp fundamental concepts of electric circuits.
- Apply basic laws to analyse circuit behaviour.
- Employ diverse methods to dissect circuit complexities.
- Utilise circuit theorems for efficient problem-solving.
- Understand operational amplifiers and their functions.
Course media
Why should I take this course?
- Gain mastery over electric circuit essentials.
- Acquire skills applicable to various engineering fields.
- Unlock the ability to design and troubleshoot circuits.
- Boost your career prospects with practical knowledge.
- Learn from engaging modules and real-world examples.
Career Path
- Electrical Engineer
- Electronics Technician
- Circuit Designer
- Systems Analyst
- Automation Specialist
Requirements
- Basic understanding of mathematics and physics.
- Familiarity with fundamental electrical terms.
- Access to a computer for online course materials.
Course Curriculum
Course Curriculum
| Unit 1- Basic Concepts | |||
| Module 1- What Is an Electric Circuit | 00:02:00 | ||
| Module 2-System of Units | 00:07:00 | ||
| Module 3- What Is an Electric Charge | 00:05:00 | ||
| Module 4- What Is an Electric Current | 00:08:00 | ||
| Module 5-Example 1 | 00:01:00 | ||
| Module 6- Example 2 | 00:02:00 | ||
| Module 7- Example 3 | 00:02:00 | ||
| Module 8- What Is Voltage | 00:07:00 | ||
| Module 9- What Is Power | 00:06:00 | ||
| Module 10- What Is Energy | 00:04:00 | ||
| Module 11- Example 4 | 00:03:00 | ||
| Module 12- Example 5 | 00:02:00 | ||
| Module 13- Dependent and Independent Sources | 00:05:00 | ||
| Module 14- Example 6 Part 1 | 00:04:00 | ||
| Module 15- Example 6 Part 2 | 00:01:00 | ||
| Module 16- Application 1 Cathode Ray Tube | 00:04:00 | ||
| Module 17-Example 7 | 00:04:00 | ||
| Module 18- Application 2 Electricity Bills | 00:02:00 | ||
| Module 19- Example 8 | 00:03:00 | ||
| Unit 2- Basic Laws | |||
| Module 1- Introduction to Basic Laws | 00:01:00 | ||
| Module 2- Definition of Resistance | 00:06:00 | ||
| Module 3- Ohm’s Law | 00:02:00 | ||
| Module 4- Types of Resistances | 00:06:00 | ||
| Module 5- Open and Short Circuit | 00:05:00 | ||
| Module 6- Definition of Conductance | 00:04:00 | ||
| Module 7- Example 1 | 00:02:00 | ||
| Module 8- Example 2 | 00:03:00 | ||
| Module 9- Example 3 | 00:03:00 | ||
| Module 10- Branch, Node and Loops | 00:07:00 | ||
| Module 11- Series and Parallel Connection | 00:04:00 | ||
| Module 12- KCL | 00:04:00 | ||
| Module 13- KVL | 00:03:00 | ||
| Module 14- Example 4 | 00:05:00 | ||
| Module 15- Example 5 | 00:02:00 | ||
| Module 16- Example 6 | 00:06:00 | ||
| Module 17- Series Resistors and Voltage Division | 00:07:00 | ||
| Module 18-Parallel Resistors and Current Division | 00:12:00 | ||
| Module 19- Analogy between Resistance and Conductance | 00:07:00 | ||
| Module 20-Example 7 | 00:03:00 | ||
| Module 21-Example 8 | 00:04:00 | ||
| Module 22- Introduction to Delta-Wye Connection | 00:06:00 | ||
| Module 23-Delta to Wye Transformation | 00:05:00 | ||
| Module 24- Wye to Delta Transformation | 00:07:00 | ||
| Module 25-Example 9 | 00:03:00 | ||
| Module 26- Example 10 | 00:15:00 | ||
| Module 27- Application Lighting Bulbs | 00:03:00 | ||
| Module 28-Example 11 | 00:05:00 | ||
| Unit 3- Methods of Analysis | |||
| Module 1- Introduction to Methods of Analysis | 00:02:00 | ||
| Module 2- Nodal Analysis with No Voltage Source | 00:15:00 | ||
| Module 3- Example 1 | 00:06:00 | ||
| Module 4-Cramer’s Method | 00:04:00 | ||
| Module 5-Nodal Analysis with Voltage Source | 00:07:00 | ||
| Module 6- Example 2 | 00:05:00 | ||
| Module 7- Example 3 | 00:13:00 | ||
| Module 8-Mesh Analysis with No Current Source | 00:10:00 | ||
| Module 9-Example 4 | 00:04:00 | ||
| Module 10- Example 5 | 00:00:00 | ||
| Module 11-Mesh Analysis with Current Source | 00:07:00 | ||
| Module 12-Example 6 | 00:08:00 | ||
| Module 13-Nodal Vs Mesh Analysis | 00:04:00 | ||
| Module 14-Application DC Transistor | 00:04:00 | ||
| Module 15-Example 7 | 00:04:00 | ||
| Unit 4- Circuit Theorems | |||
| Module 1-Introduction to Circuit theorems | 00:02:00 | ||
| Module 2-Linearity of Circuit | 00:07:00 | ||
| Module 3-Example 1 | 00:04:00 | ||
| Module 4-Superposition Theorem | 00:07:00 | ||
| Module 5- Example 2 | 00:04:00 | ||
| Module 6-Example 3 | 00:06:00 | ||
| Module 7-Source Transformation | 00:08:00 | ||
| Module 8-Example 4 | 00:05:00 | ||
| Module 9-Example 5 | 00:03:00 | ||
| Module 10-Thevenin Theorem | 00:10:00 | ||
| Module 11-Example 6 | 00:06:00 | ||
| Module 12-Example 7 | 00:05:00 | ||
| Module 13- Norton’s Theorem | 00:05:00 | ||
| Module 14-Example 8 | 00:04:00 | ||
| Module 15-Example 9 | 00:05:00 | ||
| Module 16-Maximum Power Transfer | 00:05:00 | ||
| Module 17-Example 10 | 00:03:00 | ||
| Module 18-Resistance Measurement | 00:05:00 | ||
| Module 19-Example 11 | 00:01:00 | ||
| Module 20-Example 12 | 00:04:00 | ||
| Module 21-Summary | 00:05:00 | ||
| Unit 5- Operational Amplifiers | |||
| Module 1-Introduction to Operational Amplifiers | 00:03:00 | ||
| Module 2-Construction of Operational Amplifiers | 00:07:00 | ||
| Module 3-Equivalent Circuit of non Ideal Op Amp | 00:10:00 | ||
| Module 4-Vo Vs Vd Relation Curve | 00:04:00 | ||
| Module 5-Example 1 | 00:09:00 | ||
| Module 6-Ideal Op Amp | 00:07:00 | ||
| Module 7- Example 2 | 00:04:00 | ||
| Module 8-Inverting Amplifier | 00:05:00 | ||
| Module 9-Example 3 | 00:02:00 | ||
| Module 10-Example 4 | 00:02:00 | ||
| Module 11-Non Inverting Amplifier | 00:08:00 | ||
| Module 12-Example 5 | 00:03:00 | ||
| Module 13-Summing Amplifier | 00:05:00 | ||
| Module 14-Example 6 | 00:02:00 | ||
| Module 15-Difference amplifier | 00:06:00 | ||
| Module 16-Example 7 | 00:08:00 | ||
| Module 17-Cascaded Op Amp Circuits | 00:06:00 | ||
| Module 18-Example 8 | 00:04:00 | ||
| Module 19-Application Digital to Analog Converter | 00:06:00 | ||
| Module 20-Example 9 | 00:04:00 | ||
| Module 21-Instrumentation Amplifiers | 00:05:00 | ||
| Module 22-Example 10 | 00:01:00 | ||
| Module 23-Summary | 00:04:00 | ||
| Unit 6- Capacitors and Inductors | |||
| Module 1-Introduction to Capacitors and Inductors | 00:02:00 | ||
| Module 2-Capacitor | 00:06:00 | ||
| Module 3-Capacitance | 00:02:00 | ||
| Module 4-Voltage-Current Relation in Capacitor | 00:03:00 | ||
| Module 5-Energy Stored in Capacitor | 00:06:00 | ||
| Module 6-DC Voltage and Practical Capacitor | 00:02:00 | ||
| Module 7-Example 1 | 00:01:00 | ||
| Module 8-Example 2 | 00:01:00 | ||
| Module 9-Example 3 | 00:05:00 | ||
| Module 10-Equivalent Capacitance of Parallel Capacitors | 00:02:00 | ||
| Module 11-Equivalent Capacitance of Series Capacitors | 00:03:00 | ||
| Module 12-Example 4 | 00:02:00 | ||
| Module 13-Definition of Inductors | 00:06:00 | ||
| Module 14-Definition of Inductance | 00:03:00 | ||
| Module 15-Voltage-Current Relation in Inductor | 00:03:00 | ||
| Module 16-Power and Energy Stored in Inductor | 00:02:00 | ||
| Module 17-DC Source and Inductor | 00:04:00 | ||
| Module 18-Example 5 | 00:02:00 | ||
| Module 19-Series Inductors | 00:03:00 | ||
| Module 20-Parallel Inductors | 00:04:00 | ||
| Module 21-Example 6 | 00:01:00 | ||
| Module 22-Small Summary to 3 Basic Elements | 00:02:00 | ||
| Module 23-Example 7 | 00:05:00 | ||
| Module 24-Application Integrator | 00:05:00 | ||
| Module 25-Example 8 | 00:03:00 | ||
| Module 26-Application Differentiator | 00:02:00 | ||
| Module 27-Example 9 | 00:06:00 | ||
| Module 28-Summary | 00:05:00 | ||
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1 Year Access 
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10 hours, 15 minutes