Electric Circuit Analysis/Resistors in Parallel

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The Lessons in
ELECTRIC CIRCUITS ANALYSIS COURSETemplate:Center bottom

What you need to remember from Resistors in Series.

If you ever feel lost, do not shy away from going back to the previous lesson & going through it again. You can learn by repetition.

• Total Series Resistance: (${\displaystyle R_E=R_1+R_2}$)

The total Resistance of resistors in series is the sum of the resistance of every resistor in series.

• Voltage Divider Equation 2.3: ${\displaystyle V_1=\frac{R_1\times V_s}{R_1+R_2}}$

• Current through Resistors connected in Series is the same for all resistors.

This Lesson is about Resistors in Parallel. The student/user is expected to understand the following at the end of the lesson.

• Two resistors connected in Parallel: ${\displaystyle R_{eq}=\frac{R_1\times R_2}{R_1+R_2}}$

• Current Divider Principle: ${\displaystyle I_i=I_s\times \frac{R_{eq}}{R_i}}$

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The best way to understand Parallel circuits is to start with the definition. A circuit is parallel to another circuit or several circuits if and only if they share common terminals; i.e. if both the branches touch each other's endpoints. Here is an example:

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R1, R2, and the voltage source are all in parallel. To prove this fact consider the top and bottom parts of the circuit.

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The areas in yellow are all connected together, as well as the areas in blue. So all the branches have the same terminals, which means that R1, R2, and the source are all in parallel.


If we take this discussion of the water flow analogy. Electric current can be seen as water and the conductors as water pipes.

Something interesting happens as the current reaches the common node of resistors that are connected in parallel: the total current is divided into the parallel branches.

If two or more branches are parallel then the voltage across them is equal. So based on this we can conclude that ${\displaystyle V_{R1}=V_{R2}=5V}$. However, unlike series resistors, the current across the branches is not necessarily equal.

For series resistors to find the total resistance we simply add them together. For parallel resistors, it's a little more complicated. Instead, we use the following equation:

${\displaystyle R_{eq}=\frac{1}{\frac{1}{R_1}+\frac{1}{R_2}+...+\frac{1}{R_n}}}$

However, for the case of only two resistors, we can use the following simplified form:

Equation 4.2: Total Parallel Resistance

${\displaystyle R_{eq}=\frac{R_1{R}_2}{R_1+R_2}}$

It is well to note at this point that the total resistance of parallel-connected resistors will always be less than the resistance of the smallest of the individual resistors.

In series connection, we deduced that voltage is divided amongst resistors. For parallel-connected resistors, however, the current is divided. So, as we did with the voltage division principle, here is the mathematical formula:

Equation 4.3: Current Divider Formula

${\displaystyle I_i=I_s\times \frac{R_{eq}}{R_i}}$

Using this formula you can work out the currents flowing through individual resistors.

We have spent three lectures hacking on about what and why resistors and resistive circuits in two connection schemes are used (i.e. series and parallel connections). The question now is, where and how in real life do these connections happen?

One simple application of these connection schemes is the Shunt Application. In the electric measurement industry, most often enough, we wish to measure currents and voltages of very high magnitudes (in the range of 500kV upwards). The problem is that metering devices have delicate electronic components and usually have small voltage and current ratings.

The solution to the above problem is to have a metering device connected in parallel to a resistor, with the resistor thus called a "shunt" resistor since it is there to protect (shunt) the metering device as shown in Part 4.

Template:Image If we know the current rating of a device and the total current in the system, we can then work out the shunt current and, thus, the shunt resistance.

Template:Image Figure 3.4 shows a parallel resistive circuit with the following parameters.
${\displaystyle V_s=10\text{Volts}}$; ${\displaystyle R_1=3\mathrm{\Omega }}$; ${\displaystyle R_2=7\mathrm{\Omega }}$.

Find ${\displaystyle R_{eq}}$, $I_1$ and $I_2$

Solution: from Equation 4.2 we see that.

${\displaystyle R_{eq}=\frac{R_1{R}_2}{R_1+R_2}}$

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Thus it can be said that the supply current has been divided between R1 and R2.

We know that when solving these problems, we look at the data given and thus we can see how we need to manipulate our equations in order to achieve our objective.The following example highlights this point. See to it that you follow the method used and the reasoning behind it.

Template:Image Figure 4.5 shows a parallel resistive circuit with the following parameters.
$I_s=5\text{Amps}$; ${\displaystyle R_1=2\mathrm{\Omega }}$; ${\displaystyle R_2=3\mathrm{\Omega }}$.

Find: ${\displaystyle I_1,I_2}$ and ${\displaystyle V_s}$

Solution: from Equation 3.2 we see that.

${\displaystyle R_{eq}=\frac{R_1{R}_2}{R_1+R_2}}$

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Let's take some time to Reflect on the Material covered thus far. We have learned a great deal about simple resistive circuits and the possible connections they afford us. Here I think you'll want to remember:

• Voltage: (V or v - Volts)The electrical potential between two points in a circuit.
• Current: (I or i - Amperes)The amount of charge flowing through a part of a circuit.
• Power: (W - Watts)Simply P = IV. It is the current times the voltage.
• Source: A voltage or current source is the supplier for the circuit.
• Resistor: (R measured in Ω - Ohms)A circuit element that "constricts" current flow.

• Total Series Resistance: (${\displaystyle R_E=R_1+R_2}$)

• Voltage Divider: ${\displaystyle V_1=\frac{R_1\times V_s}{R_1+R_2}}$

• Current through resistors connected in series is the same for all resistors.

• Two resistors connected in parallel: ${\displaystyle R_{eq}=\frac{R_1\times R_2}{R_1+R_2}}$

• The Current Divider Principle: ${\displaystyle I_1=I_s\times \frac{R_{eq}}{R1}}$

Do Exercise 4 in Part 8. After being completely satisfied with your work, you can go on to the next page - for the quiz! Good luck :-)

Please visit the following page to supplement material covered in this lesson

• 1. The role of resistors in electrical circuits
  2. Resistor Reduction

1. Given 2 resistors ${\displaystyle R_1=R_2=5\mathrm{\Omega }}$ in parallel, find the ${\displaystyle R_{eq}}$.
2. Given 3 resistors ${\displaystyle R_1=2\mathrm{\Omega }}$, ${\displaystyle R_2=3\mathrm{\Omega }}$, and ${\displaystyle R_3=7\mathrm{\Omega }}$ in parallel, and given that the supply current is ${\displaystyle 15A}$, find ${\displaystyle R_{eq}}$, ${\displaystyle I_1}$, ${\displaystyle I_2}$, ${\displaystyle I_3}$ and the supply voltage ${\displaystyle I_s}$ across these resistors.
3. Given 4 resistors: ${\displaystyle R_1=2\mathrm{\Omega }}$ connected in series to a parallel branch of 3 resistors: ${\displaystyle R_2=3\mathrm{\Omega }}$; ${\displaystyle R_3=7\mathrm{\Omega }}$ and ${\displaystyle R_4=4\mathrm{\Omega }}$ Find: total resistance as seen by the voltage source.
4. Is it possible to effectively connect voltage sources in parallel? If so, what conditions must be met?

• Answers to Exercise 4

Once you finish your Exercises you can post your score here! To post your score just e-mail your course coordinator your name and score *Template:Email.

• 1. Ozzimotosan -- 100%
  2. Doldham -- 75% & Corrected
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