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Electric Circuits Masterclass for Beginners

Learn electric circuits from scratch without any previous knowledge with dozens of examples in electrical engineering

Khadija Academy

Summary

Price
£49.99 inc VAT
Study method
Online, On Demand What's this?
Duration
35.2 hours · Self-paced
Qualification
No formal qualification
Certificates
  • Reed courses certificate of completion - Free
Additional info
  • Tutor is available to students

Overview

"Ultimate Electric Circuits Course from A to Z for Beginners"

This is the only course with everything you need to know about the basics of electric circuits for complete beginners without any previous knowledge.

This course starts with the basic concepts of electricity to the level you will be very familiar with circuits.

Certificates

Reed courses certificate of completion

Digital certificate - Included

Will be downloadable when all lectures have been completed

Curriculum

15
sections
173
lectures
35h 11m
total

    • 1: Electric Circuits Course Content 04:43
    • 2: Introduction to Electrical Systems 15:10
    • 3: Electric Circuits, Charges, and Current 31:07
    • 4: Solved Examples 1 10:36
    • 5: Voltage, Energy, and Power 25:53
    • 6: Solved Examples 2 10:32
    • 7: Dependent and Independent Sources 21:08
    • 8: Cathode Ray Tube and Electricity Bills 16:09
    • 9: Special Thanks 02:45
    • 10: Course Slides 1:55:00 PDF

    • 11: Introduction to Basic Laws 09:05
    • 12: Ohm's Law and Conductance 19:08
    • 13: Solved Examples 1 06:51
    • 14: Branch, Nodes, Loops, Series and Parallel Connection 08:53
    • 15: Kirchhoff's Laws KVL and KCL 11:57
    • 16: Solved Examples 2 09:39
    • 17: Voltage Division, Current Division, Analogy between Resistance and Cond 22:07
    • 18: Solved Examples 3 09:59
    • 19: Delta-Wye and Wye-Delta Transformations 11:47
    • 20: Solved Examples 4 18:59
    • 21: Application on Basic Laws with a Solved Example 09:44

    • 22: Methods of Analysis and Nodal Analysis with No Voltage Source 24:46
    • 23: Solved Example 1 09:39
    • 24: Nodal Analysis with a Voltage Source 11:19
    • 25: Solved Examples 2 19:44
    • 26: Mesh Analysis with No Current Source 11:12
    • 27: Solved Examples 3 10:15
    • 28: Mesh Analysis with a Current Source 07:55
    • 29: Solved Example 4 10:20
    • 30: Nodal vs Mesh Analysis 04:06
    • 31: Application Transistor Circuit with a Solved Example 08:06

    • 32: Introduction to Circuit Theorems 01:32
    • 33: Superposition Theorem 08:08
    • 34: Example 1 on Superposition Theorem 05:34
    • 35: Example 2 on Superposition Theorem 13:10
    • 36: Source Transformation Theorem 07:35
    • 37: Example 1 on Source Transformation Theorem 12:17
    • 38: Example 2 on Source Transformation Theorem 09:18
    • 39: Thevenin Theorem 13:01
    • 40: Example 1 on Thevenin Theorem 11:45
    • 41: Example 2 on Thevenin Theorem 09:01
    • 42: Norton Theorem 04:49
    • 43: Example 1 on Norton Theorem 11:51
    • 44: Example 2 on Norton Theorem 08:07
    • 45: Maximum Power Transfer 13:35
    • 46: Example on Maximum Power Transfer 06:28

    • 47: Introduction to Operational Amplifiers 22:31
    • 48: Example on Non Ideal Op Amp 14:43
    • 49: Construction of Ideal Operational Amplifiers 04:07
    • 50: Example on Ideal Operational Amplifiers 06:37
    • 51: Construction of Inverting Operational Amplifiers 05:06
    • 52: Example 1 on Inverting Operational Amplifiers 03:26
    • 53: Example 2 on Inverting Operational Amplifiers 03:19
    • 54: Construction of Non Inverting Operational Amplifiers 07:14
    • 55: Example on Non Inverting Operational Amplifiers 05:36
    • 56: Construction of Summing Operational Amplifiers 04:51
    • 57: Example on Summing Operational Amplifiers 04:40
    • 58: Construction of Difference Operational Amplifiers 08:37
    • 59: Example on Difference Operational Amplifiers 04:05
    • 60: Cascaded Operational Amplifiers 02:47
    • 61: Example on Cascaded Operational Amplifiers 06:57
    • 62: Digital to Analog Converter 09:06
    • 63: Example on Digital to Analog Converter 03:22
    • 64: Instrumentation Amplifiers 05:04
    • 65: Example on Instrumentation Amplifiers 02:28

    • 66: Introduction to Capacitors 23:28
    • 67: Equations of a Capacitor 25:21
    • 68: Solved Examples on Capacitors 23:32
    • 69: Series and Parallel Capacitors 11:00
    • 70: Solved Examples on Series and Parallel Capacitors 12:34
    • 71: Introduction to Inductors 29:04
    • 72: Solved Examples on Inductors 12:57
    • 73: Series and Parallel Inductors 14:31
    • 74: Solved Examples on Series and Parallel Inductors 15:01
    • 75: Application Integrator 09:25
    • 76: Application Differentiator 11:54

    • 77: Introduction to First Order Circuits 06:52
    • 78: Source-Free RC Circuit 21:50
    • 79: Example 1 on Source-Free RC Circuit 06:06
    • 80: Example 2 on Source-Free RC Circuit 07:29
    • 81: Source-Free RL Circuit 14:53
    • 82: Example 1 on Source-Free RL Circuit 10:55
    • 83: Example 2 on Source-Free RL Circuit 05:17

    • 84: Lesson 1 Step Response of an RC Circuit 27:03
    • 85: Lesson 2 Example 1 on Step Response of an RC Circuit 07:00
    • 86: Lesson 3 Example 2 on Step Response of an RC Circuit 12:18
    • 87: Lesson 4 Step Response of an RL Circuit 13:02
    • 88: Lesson 5 Example 1 on Step Response of an RL Circuit 04:36
    • 89: Lesson 6 Example 2 on Step Response of an RL Circuit 14:33

    • 90: Introduction to AC Electric Circuits 26:14
    • 91: Solved Examples 1 09:56
    • 92: Phasor Representation of AC 17:09
    • 93: Solved Examples 2 18:15
    • 94: Phasor Relationships for Circuit Elements 17:35
    • 95: Impedance and Admittance 31:43
    • 96: Kirchhoff’s Laws and Impedance Combinations in the Frequency Domain 13:05
    • 97: Solved Example 1 on Impedance Combination 07:45
    • 98: Solved Example 2 on Voltage Division 06:01
    • 99: Solved Example 3 on Impedance Combinations 10:19

    • 100: Solved Example 1 on Nodal Analysis 15:00
    • 101: Solved Example 2 on Nodal Analysis 06:55
    • 102: Solved Example 1 on Mesh Analysis 07:48
    • 103: Solved Example 2 on Mesh Analysis 09:31
    • 104: Solved Example 1 on Superposition Theorem 08:13
    • 105: Solved Example 2 on Superposition Theorem 15:33
    • 106: Solved Example on Source Transformation 06:22
    • 107: Solved Example 1 on Thevenin Theorem 07:42
    • 108: Solved Example 2 on Thevenin Theorem 07:37
    • 109: Solved Example on Norton Theorem 09:34

    • 110: Introduction to AC Power Analysis 05:12
    • 111: Instantaneous Power and Average Power 18:06
    • 112: Solved Examples 1 10:38
    • 113: Maximum Average Power Transfer 11:12
    • 114: Solved Examples 2 09:13
    • 115: Effective or RMS Value in AC Circuits 11:33
    • 116: Solved Examples 3 12:03
    • 117: Apparent Power and Power Factor 09:59
    • 118: Solved Examples 4 09:42
    • 119: Complex Power and Power Triangle 19:39
    • 120: Solved Examples 5 11:52
    • 121: Power Factor Correction 17:06
    • 122: Solved Example 6 06:07

    • 123: Introduction to Resonance in Electric Systems 11:42
    • 124: Definition and Equations of a Series Resonant Circuit 30:51
    • 125: Quality Factor of a Series Resonant Circuit 20:19
    • 126: Total Impedance VS Frequency in a Series Resonant Circuit 16:03
    • 127: Bandwidth and Selectivity Curve of a Series Resonant Circuit 14:56
    • 128: Derivation of Cutoff Frequencies 21:41
    • 129: Example 1 on Series Resonant Circuit 09:14
    • 130: Example 2 on Series Resonant Circuit 04:41
    • 131: Example 3 on Series Resonant Circuit 05:51
    • 132: Example 4 on Series Resonant Circuit 08:00
    • 133: Example 5 on Series Resonant Circuit 08:51

    • 134: Parallel Resonant Circuit 14:32
    • 135: Unity Power Factor of a Parallel Resonant Circuit 12:46
    • 136: Maximum Impedance of a Parallel Resonant Circuit 07:00
    • 137: Quality Factor of a Parallel Resonant Circuit 12:56
    • 138: Bandwidth and Cutoff Frequencies of a Parallel Resonant Circuit 19:52
    • 139: Effect of High Quality Factor on the Parallel Resonant Circuit 24:06
    • 140: Example 1 on Parallel Resonant Circuit 11:17
    • 141: Example 2 on Parallel Resonant Circuit 15:41
    • 142: Example 3 on Parallel Resonant Circuit 07:49
    • 143: Example 4 on Parallel Resonant Circuit 11:44
    • 144: Example 5 on Parallel Resonant Circuit 04:23
    • 145: Example 6 on Parallel Resonant Circuit 10:54

    • 146: Example 1 on Simulation of a Simple Electric Circuit 10:08
    • 147: Example 2 on Simulation of a Simple Electric Circuit 12:25
    • 148: Example 3 on Simulation of a Simple Electric Circuit 07:27
    • 149: Simulation of an Inverting Amplifier 12:00
    • 150: Simulation of non-Inverting and Summing Amplifiers 07:30
    • 151: Simulation of Differentiator Op-Amp 10:09
    • 152: Simulation of Source-Free RC Circuit 11:49
    • 153: Simulation of Source-Free RL Circuit 11:36
    • 154: Simulation of Step Response of an RC Circuit 18:16
    • 155: Simulation of Step Response of an RL Circuit 09:46
    • 156: Simulation of Charging and Discharging Capacitor Using Matlab 10:25
    • 157: Simulation of a Series Resonant Circuit 20:45
    • 158: Simulation of a Parallel Resonant Circuit 16:59

    • 159: Course Content 01:50
    • 160: Why are Complex Numbers Important? 03:25
    • 161: What is an Imaginary Number? 05:39
    • 162: Properties of Imaginary Numbers 05:11
    • 163: What is a Complex Number? 05:01
    • 164: Operation and Properties of Complex Numbers 10:04
    • 165: Solved Examples on Complex Numbers 10:27
    • 166: Graphical Representation and Polar Form of Complex Numbers 12:50
    • 167: Solved Examples on Trignometric and Algebric Form 12:06
    • 168: Operations on Complex Numbers in Trigonometric Form 10:26
    • 169: Solved Examples on Operations of Trigonometric Form 16:05
    • 170: Exponential Form of Complex Numbers 01:17
    • 171: Solved Examples on Exponential Form 10:20
    • 172: Cubic Roots of Unity 10:42
    • 173: Solved Examples on Cubic Roots of Unity 15:52

Course media

Description

Throughout the course you will get:

  • Basics concepts of electric circuits: This will help you understand the very basic definitions of electricity including voltage, current, power, and more.

  • Basic laws of electric circuits: This part will teach you about the branches, nodes, KVL, KCL, Ohm's law, and Delta-Wye transformations.

  • Methods of analysis: You will learn how to analyze electric circuits using nodal analysis and mesh analysis.

  • Circuit theorems: In this part, you will learn more advanced circuit analysis techniques such as the superposition theorem, source transformation theorem, Thevenin theorem, Norton theorem, and maximum power transfer.

  • Operational amplifiers: You will be introduced to operational amplifiers including inverting, non-inverting, summing, difference, and cascaded amplifiers. These amplifiers are helpful in inverting or amplification or adding or subtracting different input signals.

  • Capacitors and inductors: These components are really important in the electrical system and other applications. You will find inductors as a representation of electrical machines and capacitors that can be used in power factor correction.

  • First-order circuits: These circuits are composed of resistors and inductors or resistors and capacitors. We will understand how to analyze them in the free and forced responses.

  • Basics of AC circuits: AC power or alternating power is the one which we have in our homes. We will learn about them and what is the difference between them and AC circuits.

  • Analysis of AC circuits: In this part, we will start analyzing our AC circuits with the different theorems that had been discussed at the beginning of the course.

  • Resonant circuits: In this part, we will discuss both series and parallel resonant circuits, these circuits have a crucial effect on electric circuits as well as have practical applications.

  • Electric circuit simulations using MATLAB: We will learn the simulation of many electric circuits in the well-known simulation program MATLAB Simulink. This will be a fun part that will increase your knowledge about electric circuits.

All of these topics are in a step by step lessons with many solved examples.

Take this bundle if you've been looking for ONE COURSE BUNDLE with in-depth insight into the basics of electric circuits.

Who is this course for?

  • Anyone who wants knowledge about electric circuits
  • Anyone who is interested in knowing the main concepts of electric circuits
  • Anyone who is a student and wants to learn about DC circuits
  • Anyone who is a student and wants to learn about AC circuits

Requirements

  • No prior knowledge about electric circuits.

  • Simple mathematics knowledge.

Career path

You will be able to understand well electrical circuits and become ready for our next course on electrical machines.

Questions and answers

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Legal information

This course is advertised on Reed.co.uk by the Course Provider, whose terms and conditions apply. Purchases are made directly from the Course Provider, and as such, content and materials are supplied by the Course Provider directly. Reed is acting as agent and not reseller in relation to this course. Reed's only responsibility is to facilitate your payment for the course. It is your responsibility to review and agree to the Course Provider's terms and conditions and satisfy yourself as to the suitability of the course you intend to purchase. Reed will not have any responsibility for the content of the course and/or associated materials.

FAQs

Study method describes the format in which the course will be delivered. At Reed Courses, courses are delivered in a number of ways, including online courses, where the course content can be accessed online remotely, and classroom courses, where courses are delivered in person at a classroom venue.

CPD stands for Continuing Professional Development. If you work in certain professions or for certain companies, your employer may require you to complete a number of CPD hours or points, per year. You can find a range of CPD courses on Reed Courses, many of which can be completed online.

A regulated qualification is delivered by a learning institution which is regulated by a government body. In England, the government body which regulates courses is Ofqual. Ofqual regulated qualifications sit on the Regulated Qualifications Framework (RQF), which can help students understand how different qualifications in different fields compare to each other. The framework also helps students to understand what qualifications they need to progress towards a higher learning goal, such as a university degree or equivalent higher education award.

An endorsed course is a skills based course which has been checked over and approved by an independent awarding body. Endorsed courses are not regulated so do not result in a qualification - however, the student can usually purchase a certificate showing the awarding body's logo if they wish. Certain awarding bodies - such as Quality Licence Scheme and TQUK - have developed endorsement schemes as a way to help students select the best skills based courses for them.
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