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Ultimate Electric Circuits Course Bundle
Basic Concepts
What Is an Electric Circuit ? (2:21)
Course Files
System of Units (6:47)
What Is an Electric Charge ? (5:10)
What Is an Electric Current ? (8:03)
Example 1 (1:09)
Example 2 (2:21)
Example 3 (2:21)
What Is Voltage ? (7:21)
What Is Power ? (5:52)
What Is Energy ? (3:39)
Example 4 (2:33)
Example 5 (2:20)
Dependent and Independent Sources (7:21)
Example 6 Part 1 (3:37)
Example 6 Part 2 (1:22)
Application 1 Cathode Ray Tube (3:44)
Example 7 (3:54)
Application 2 Electricity Bills (1:57)
Example 8
Basic Laws
Introduction to Basic Laws (1:28)
Definition of Resistance (6:29)
Ohm's Law (2:04)
Types of Resistances (5:45)
Open and Short Circuit (5:02)
Definition of Conductance (4:03)
Example 1 (1:34)
Example 2 (3:04)
Example 3 (3:11)
Branch, Node and Loops (7:08)
Series and Parallel Connection (3:44)
KCL (3:39)
KVL (3:17)
Example 4 (4:47)
Example 5 (2:09)
Example 6 (5:32)
Series Resistors and Voltage Division (6:53)
Parallel Resistors and Current Division (11:49)
Analogy between Resistance and Conductance (6:39)
Example 7 (3:23)
Example 8 (3:54)
Introduction to Delta-Wye Transformation (5:46)
Delta to Wye Transformation (5:22)
Wye to Delta Transformation (6:50)
Example 9 (2:42)
Example 10 (14:55)
Application Lighting Bulbs (3:28)
Example 11 (5:14)
Methods of Analysis
Introduction to Methods of Analysis (1:41)
Nodal Analysis with No Voltage Source (14:31)
Example 1 (5:43)
Cramer's Method (4:05)
Nodal Analysis with Voltage Source (6:35)
Example 2 (5:27)
Example 3 (12:35)
Mesh Analysis with No Current Source (10:19)
Example 4 (3:41)
Example 5 (6:05)
Mesh Analysis with Current Source (6:47)
Example 6 (7:43)
Nodal Vs Mesh Analysis (4:22)
Application DC Transistor (4:26)
Example 7 (3:53)
Circuit Theorems
Introduction to Circuit Theorems (2:02)
Linearity of Circuit (7:25)
Example 1 (3:49)
Superposition Theorem (7:02)
Example 2 (4:20)
Example 3 (5:56)
Source Transformation (7:37)
Example 4 (5:05)
Example 5 (3:03)
Thevenin Theorem (9:44)
Example 6 (6:04)
Example 7 (4:57)
Norton's Theorem (5:19)
Example 8 (3:29)
Example 9 (5:00)
Maximum Power Transfer (4:51)
Example 10 (2:57)
Resistance Measurement (4:56)
Example 11 (0:26)
Example 12 (3:57)
Summary (4:43)
Operational Amplifiers
Introduction to Operational Amplifiers (3:28)
Construction of Operational Amplifiers (7:09)
Equivalent Circuit of non Ideal Op Amp (9:42)
Vo Vs Vd Relation Curve (3:30)
Example 1 (9:16)
Ideal Op Amp (7:05)
Example 2 (4:15)
Inverting Amplifier (5:23)
Example 3 (1:51)
Example 4 (2:01)
Non Inverting Amplifier (7:58)
Example 5 (3:17)
Summing Amplifier (4:40)
Example 6 (2:17)
Difference amplifier (5:34)
Example 7 (7:33)
Cascaded Op Amp Circuits (6:27)
Example 8 (4:10)
Application Digital to Analog Converter (5:40)
Example 9 (3:54)
Instrumentation Amplifiers (5:26)
Example 10 (1:00)
Summary (4:28)
Capacitors and Inductors
Introduction to Capacitors and Inductors (2:27)
Capacitor (6:28)
Capacitance (2:24)
Voltage-Current Relation in Capacitor (3:17)
Energy Stored in Capacitor (6:20)
DC Voltage and Practical Capacitor (1:55)
Example 1 (0:42)
Example 2 (1:06)
Example 3 (4:51)
Equivalent Capacitance of Parallel Capacitors (2:26)
Equivalent Capacitance of Series Capacitors (2:58)
Example 4 (1:55)
Definition of Inductors (5:52)
Definition of Inductance (3:01)
Voltage-Current Relation in Inductor (3:00)
Power and Energy Stored in Inductor (2:24)
DC Source and Inductor (3:45)
Example 5 (2:06)
Series Inductors (3:11)
Parallel Inductors (3:33)
Small Summary to 3 Basic Elements (2:24)
Example 6 (1:10)
Example 7 (4:48)
Application Integrator (4:47)
Example 8 (3:24)
Application Differentiator (2:26)
Example 9 (6:03)
Summary (4:51)
First Order Circuits
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