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Sample Problem: KCL 5

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Linear Circuits 1: DC Analysis

Instituto de Tecnología de Georgia

4.5 (196 calificaciones) | 15K estudiantes inscritos

This course explains how to analyze circuits that have direct current (DC) current or voltage sources. A DC source is one that is constant. Circuits with resistors, capacitors, and inductors are covered, both analytically and experimentally. Some practical applications in sensors are demonstrated.

Revisiones

4.5 (196 calificaciones)

5 stars
129 ratings
4 stars
39 ratings
3 stars
21 ratings
2 stars
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1 star
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DM

May 09, 2018

Great course, learned a lot of things that they don't teach at my school, Thanks for the opportunity.

SA

Apr 10, 2019

its a great course to develop a greater knowledge in linear circuits and has helped me a lot.

De la lección

Module 2

The module describes some basic principles used in circuit analysis.

Sample Problem: DC Op Amp 19:29

Sample Problem: DC Op Amp 25:33

Sample Problem: DC Op Amp 34:23

Sample Problem: DC Op Amp 46:22

Sample Problem: DC Op Amp 55:33

Sample Problem: Current Division 13:57

Sample Problem: Current Division 25:20

Sample Problem: Parallel and Series Resistors 12:24

Sample Problem: Parallel and Series Resistors 28:07

Sample Problem: KVL6:05

Sample Problem: KVL 25:48

Sample Problem: KVL 32:28

Sample Problem: KCL 12:12

Sample Problem: KCL 24:43

Sample Problem: KCL 32:51

Sample Problem: KCL 41:26

Sample Problem: KCL 52:10

Sample Problem: Op Amps 19:17

Sample Problem: Op Amps 25:29

Sample Problem: Op Amps 34:59

Sample Problem: Nodes, Branches, Paths, and Loops3:19

Sample Problem: Summing Op Amp6:05

Sample Problem: Differential Amp6:47

Sample Problem: Inverting Op Amp5:09

Sample Problem: Non-inverting Op Amp7:54

Sample Problem: Max Power (Depend Sources)4:06

Sample Problem: Dependent Sources 15:10

Sample Problem: Dependent Sources 24:48

Sample Problem: Series/Parallel (Independ Sources) 12:59

Sample Problem: Series/Parallel (Independ Sources) 27:22

Sample Problem: Series/Parallel (Independ Sources) 33:00

Sample Problem: Series/Parallel (Independ Sources) 44:35

Sample Problem: Op Amps 49:10

Sample Problem: Op Amps 59:29

Sample Problem: Op Amps 65:33

Sample Problem: Op Amps 74:23

Sample Problem: Op Amps 86:22

Sample Problem: Op Amps 95:33

Sample Problem: Op Amps 109:17

Sample Problem: Op Amps 115:29

Sample Problem: Op Amps 124:59

Impartido por:

Dr. Bonnie H. Ferri
Professor
Dr. Joyelle Harris
Director of the Engineering for Social Innovation Center
Dr Mary Ann Weitnauer

Transcripción

The topic of this problem is Kirchhoff's Current Law.

In this problem we have a circuit that has a current source IT in it,

it has three resisters.

The resisters have current flow associated with them as seen in the circuit.

So we have 10 miliamps, 40 miliamps, and

20 miliamps going through each one of those individual resisters.

So looking for i sub t.

So we're going to use Kirchhoff's Current Law to be able to answer this problem.

First of all, we want to restate what Kirchhoff's Current Law is.

It is the algebraic sum of all the currents entering any

node at any instant in time is zero.

So if we look at the top node for instance,

we have two nodes in this problem, right?

We have one at the top and we have one at the bottom.

So if we use Kirchhoff's Current Law at the top node and

we take the algebraic sum of the currents entering the node at the top,

then we can determine what the unknown current I sub t is.

So looking at that, we see that I sub t is flowing into the nodes.

So we're going to use Kirchhoff's Current Law and

we're going to sum the currents into the node.

So, it's I sub t flowing into the node at the top.

And we have 10 milliamps flowing out of the nodes.

So, it's going to be -10 milliamps for

the current flowing out through the first resistor.

Then, we have another 40 milliamps flowing through a second resistor.

And we have 20 milliamps flowing out of the node and

through the third and right most resister.

And we know again, through Kirchhoff's Current Law,

that the sum of those is going to be equal to zero.

So if we take that and we solve for I sub T,

then our I sub T is going to be equal to 10 plus

40 plus 20, or 70 milliamps.

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