10.1 Resistors in series and parallel (Page 5/17)

Page 5 / 17

Combinations of series and parallel can be reduced to a single equivalent resistance using the technique illustrated in [link] . Various parts are identified as either series or parallel, reduced to their equivalents, and further reduced until a single resistance is left. The process is more time consuming than difficult.

The diagram has a set of five circuits. The first circuit has a combination of seven resistors in series and parallel combinations. It has a resistor R sub one in series with a set of three resistors R sub two, R sub three, and R sub four in parallel and connected in series with a combination of resistors R sub five and R sub six, which are parallel. A resistor R sub seven is connected in parallel to R sub one and the voltage source. The second circuit calculates combinations of all parallel resistors in circuit one and replaces them with their equivalent resistance. It has a resistor R sub one in series with R sub p and R sub p prime. A resistor R sub seven is connected in parallel to R sub one and the voltage source. The third circuit takes the combination of the series resistors R sub p and R sub p prime and replaces it with R sub s. It has a resistor R sub one in series with R sub s. A resistor R sub seven is connected in parallel to R sub s and the voltage source. The fourth circuit shows a parallel combination of R sub seven and R sub s are calculated and replaced by R sub p double prime. The circuit now has a series combination voltage source, R sub one and R sub p double prime. The fifth circuit shows the final equivalent of the first circuit. It has a voltage source connecting across a final equivalent resistance R sub s prime. — This combination of seven resistors has both series and parallel parts. Each is identified and reduced to an equivalent resistance, and these are further reduced until a single equivalent resistance is reached.

The simplest combination of series and parallel resistance, shown in [link] , is also the most instructive, since it is found in many applications. For example, $R_{1}$ could be the resistance of wires from a car battery to its electrical devices, which are in parallel. $R_{2}$ and $R_{3}$ could be the starter motor and a passenger compartment light. We have previously assumed that wire resistance is negligible, but, when it is not, it has important effects, as the next example indicates.

Calculating resistance, $IR$ Drop, current, and power dissipation: combining series and parallel circuits

[link] shows the resistors from the previous two examples wired in a different way—a combination of series and parallel. We can consider $R_{1}$ to be the resistance of wires leading to $R_{2}$ and $R_{3}$ . (a) Find the total resistance. (b) What is the $IR$ drop in $R_{1}$ ? (c) Find the current $I_{2}$ through $R_{2}$ . (d) What power is dissipated by $R_{2}$ ?

Circuit diagram in which a battery of twelve point zero volts is connected to a combination of three resistors. Resistors R sub two and R sub three are connected in parallel to each other, and their combination is connected in series to resistor R sub one. R sub one has a resistance of one point zero zero ohms, R sub two has a resistance of six point zero zero ohms, and R sub three has a resistance of thirteen point zero ohms. — These three resistors are connected to a voltage source so that $R_{2}$ and $R_{3}$ are in parallel with one another and that combination is in series with $R_{1}$ .

Strategy and Solution for (a)

To find the total resistance, we note that $R_{2}$ and $R_{3}$ are in parallel and their combination $R_{p}$ is in series with $R_{1}$ . Thus the total (equivalent) resistance of this combination is

R_{tot} = R_{1} + R_{p} .

First, we find $R_{p}$ using the equation for resistors in parallel and entering known values:

\frac{1}{R_{p}} = \frac{1}{R_{2}} + \frac{1}{R_{3}} = \frac{1}{6.00 Ω} + \frac{1}{13.0 Ω} = \frac{0.2436}{Ω} .

Inverting gives

R_{p} = \frac{1}{0.2436} Ω = 4 . 11 Ω .

So the total resistance is

R_{tot} = R_{1} + R_{p} = 1 . 00 Ω + 4 . 11 Ω = 5 . 11 Ω .

Discussion for (a)

The total resistance of this combination is intermediate between the pure series and pure parallel values ( $20.0 Ω$ and $0.804 Ω$ , respectively) found for the same resistors in the two previous examples.

Strategy and Solution for (b)

To find the $IR$ drop in $R_{1}$ , we note that the full current $I$ flows through $R_{1}$ . Thus its $IR$ drop is

V_{1} = {IR}_{1} .

We must find $I$ before we can calculate $V_{1}$ . The total current $I$ is found using Ohm’s law for the circuit. That is,

I = \frac{V}{R_{tot}} = \frac{12.0 V}{5.11 Ω} = 2 . 35 A .

Entering this into the expression above, we get

V_{1} = {IR}_{1} = (2.35 A) (1.00 Ω) = 2 . 35 V .

Discussion for (b)

The voltage applied to $R_{2}$ and $R_{3}$ is less than the total voltage by an amount $V_{1}$ . When wire resistance is large, it can significantly affect the operation of the devices represented by $R_{2}$ and $R_{3}$ .

Strategy and Solution for (c)

To find the current through $R_{2}$ , we must first find the voltage applied to it. We call this voltage $V_{p}$ , because it is applied to a parallel combination of resistors. The voltage applied to both $R_{2}$ and $R_{3}$ is reduced by the amount $V_{1}$ , and so it is

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10.1 Resistors in series and parallel (Page 5/17)

Calculating resistance, IR size 12{ ital "IR"} {} Drop, current, and power dissipation: combining series and parallel circuits

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Calculating resistance, $IR$ Drop, current, and power dissipation: combining series and parallel circuits