Overview
By enroling in Electric Circuits for Electrical Engineering, you can kickstart your vibrant career and strengthen your profound knowledge. You can learn everything you need to know about the topic.
The Electric Circuits for Electrical Engineering course includes all of the most recent information to keep you abreast of the employment market and prepare you for your future. The curriculum for this excellent Electric Circuits for Electrical Engineering course includes modules at all skill levels, from beginner to expert. You will have the productivity necessary to succeed in your organisation once you have completed our Electric Circuits for Electrical Engineering Program.
So enrol in our Electric Circuits for Electrical Engineering course right away if you’re keen to envision yourself in a rewarding career.
Description
Enroling in this Electric Circuits for Electrical Engineering course can improve your Electric Circuits for Electrical Engineering perspective, regardless of your skill levels in the Electric Circuits for Electrical Engineering topics you want to master. If you’re already a Electric Circuits for Electrical Engineering expert, this peek under the hood will provide you with suggestions for accelerating your learning, including advanced Electric Circuits for Electrical Engineering insights that will help you make the most of your time. This Electric Circuits for Electrical Engineering course will act as a guide for you if you’ve ever wished to excel at Electric Circuits for Electrical Engineering.
Why Choose Us?
- This course is accredited by the CPD Quality Standards.
- Lifetime access to the whole collection of the learning materials.
- Online test with immediate results.
- Enroling in the course has no additional cost.
- You can study and complete the course at your own pace.
- Study for the course using any internet-connected device, such as a computer, tablet, or mobile device.
Will I Receive A Certificate Of Completion?
Upon successful completion, you will qualify for the UK and internationally-recognised CPD certificate and you can choose to make your achievement formal by obtaining your PDF Certificate at a cost of £4.99 and Hardcopy Certificate for £9.99.
Who Is This Course For?
This Electric Circuits for Electrical Engineering course is a great place to start if you’re looking to start a new career in Electric Circuits for Electrical Engineering field. This training is for anyone interested in gaining in-demand Electric Circuits for Electrical Engineering proficiency to help launch a career or their business aptitude.
Requirements
The Electric Circuits for Electrical Engineering course requires no prior degree or experience. All you require is English proficiency, numeracy literacy and a gadget with stable internet connection. Learn and train for a prosperous career in the thriving and fast-growing industry of Electric Circuits for Electrical Engineering, without any fuss.
Career Path
This Electric Circuits for Electrical Engineering training will assist you develop your Electric Circuits for Electrical Engineering ability, establish a personal brand, and present a portfolio of relevant talents. It will help you articulate a Electric Circuits for Electrical Engineering professional story and personalise your path to a new career. Furthermore, developing this Electric Circuits for Electrical Engineering skillset can lead to numerous opportunities for high-paying jobs in a variety of fields.
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 | 00:06:00 | ||
| 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 | 00:03:00 | ||
| 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 | 00:03:00 | ||
| 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 | ||
| Assignment | |||
| Assignment -Electric Circuits for Electrical Engineering | 00:00:00 | ||
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