Description

The 'Electrical Circuits Laws and Methods' course is designed to provide a comprehensive understanding of electric circuits, laws, and analytical methods. It covers fundamental concepts, basic laws, methods of analysis, circuit theorems, operational amplifiers, and capacitors and inductors. Students will learn essential principles to analyze and design electrical circuits effectively.

Learning Outcomes:

Understand the basic concepts of electric circuits, including electric charge, current, voltage, power, and energy.

Apply Ohm's Law and other basic laws to analyze resistive circuits and determine currents and voltages.

Use nodal and mesh analysis methods to analyze and solve complex electrical circuits with various sources.

Apply circuit theorems such as the Superposition Theorem, Thevenin's Theorem, and Norton's Theorem to simplify circuit analysis.

Comprehend the properties and applications of operational amplifiers in various amplifier configurations.

Analyze capacitors and inductors in DC circuits, calculate their stored energy, and understand their equivalent capacitance and inductance in series and parallel configurations.

Why buy this Electrical Circuits Laws and Methods?

Unlimited access to the course for a lifetime.

Opportunity to earn a certificate accredited by the CPD Quality Standards and CIQ after completing this course.

Structured lesson planning in line with industry standards.

Immerse yourself in innovative and captivating course materials and activities.

Assessments designed to evaluate advanced cognitive abilities and skill proficiency.

Flexibility to complete the Course at your own pace, on your own schedule.

Receive full tutor support throughout the week, from Monday to Friday, to enhance your learning experience.

Unlock career resources for CV improvement, interview readiness, and job success.

Certification

After studying the course materials of the Electrical Circuits Laws and Methods there will be a written assignment test which you can take either during or at the end of the course. After successfully passing the test you will be able to claim the pdf certificate for £5.99. Original Hard Copy certificates need to be ordered at an additional cost of £9.60.

Who is this course for?

The Electrical Circuits Laws and Methods course is designed for undergraduate and graduate electrical engineering students as a foundational study of circuit theory.

It is suitable for electronics enthusiasts eager to grasp the functioning and design of electrical circuits for various applications.

Engineering technicians and technologists working in fields like telecommunications and manufacturing can benefit from this course to better understand and troubleshoot electrical circuits in practical settings.

Electrical technicians and electricians can enhance their problem-solving abilities and theoretical knowledge of electrical circuits by taking this course.

Hobbyists and DIY enthusiasts interested in electronics projects will find value in learning circuit design and troubleshooting through this course.

Professionals in engineering and related fields can use this course for continuing education to refresh their knowledge and stay up-to-date with advancements in electrical circuit theory and methods.

Prerequisites

This Electrical Circuits Laws and Methods does not require you to have any prior qualifications or experience. You can just enrol and start learning.This Electrical Circuits Laws and Methods was made by professionals and it is compatible with all PC's, Mac's, tablets and smartphones. You will be able to access the course from anywhere at any time as long as you have a good enough internet connection.

Career path

Electrical Engineer: £28,000 - £70,000 per year

Electronics Engineer: £30,000 - £75,000 per year

Electrician: £24,000 - £45,000 per year

Power Systems Engineer: £32,000 - £80,000 per year

Telecommunications Engineer: £28,000 - £70,000 per year

Automation and Control Systems Engineer: £35,000 - £80,000 per year

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	00:03:00
	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 10	00:03:00
	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	00:01:00
	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	00:04:00
	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	00:05:00
	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 - Electrical Circuits Laws and Methods	00:00:00

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Electrical Circuits Laws and Methods

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