Connections: Conservation Laws

Example 4.1 Calculating Resistance, Current, Voltage Drop, and Power Dissipation: Analysis of a Series Circuit

Suppose the voltage output of the battery in Figure 4.3 is $\text{12}\text{.}0\text{V}\text{12}\text{.}0\text{V}$ and the resistances are $R_1=1\text{.}\text{00}\Omega \text{,}{R}_1=1\text{.}\text{00}\Omega \text{,}$ $R_2=6\text{.}\text{00}\Omega \text{,}{R}_2=6\text{.}\text{00}\Omega \text{,}$ and $R_3=\text{13}\text{.}0\Omega \text{.}{R}_3=\text{13}\text{.}0\Omega \text{.}$ (a) What is the total resistance? (b) Find the current. (c) Calculate the voltage drop in each resistor and show that these add to equal the voltage output of the source. (d) Calculate the power dissipated by each resistor. (e) Find the power output of the source and show that it equals the total power dissipated by the resistors.

Strategy and Solution for (a)

The total resistance is simply the sum of the individual resistances, as given by the equation

Strategy and Solution for (b)

The current is found using Ohm’s law, $V=\text{IR}\text{.}V=\text{IR}\text{.}$ Entering the value of the applied voltage and the total resistance yields the current for the circuit.

Strategy and Solution for (c)

The voltage—or $\text{IR}\text{IR}$ drop—in a resistor is given by Ohm’s law. Entering the current and the value of the first resistance yields

Similarly,

and

Discussion for (c)

The three $\text{IR}\text{IR}$ drops add to $\text{12}\text{.}0\text{V}\text{,}\text{12}\text{.}0\text{V}\text{,}$ as predicted.

Strategy and Solution for (d)

The easiest way to calculate power in watts (W) dissipated by a resistor in a DC circuit is to use Joule’s law, $P=\text{IV}\text{,}P=\text{IV}\text{,}$ where $PP$ is electric power. In this case, each resistor has the same full current flowing through it. By substituting Ohm’s law $V=\text{IR}V=\text{IR}$ into Joule’s law, we get the power dissipated by the first resistor as

Similarly,

and

Discussion for (d)

Power can also be calculated using either $P=\text{IV}P=\text{IV}$ or $P=\frac{V^2}{R}\text{,}P=\frac{V^2}{R}\text{,}$ where $VV$ is the voltage drop across the resistor (not the full voltage of the source). The same values will be obtained.

Strategy and Solution for (e)

The easiest way to calculate power output of the source is to use $P=\text{IV}\text{,}P=\text{IV}\text{,}$ where $VV$ is the source voltage. This gives

Discussion for (e)

Note, coincidentally, that the total power dissipated by the resistors is also 7.20 W, the same as the power put out by the source. That is,

Power is energy per unit time (watts), so conservation of energy requires the power output of the source to be equal to the total power dissipated by the resistors.

Major Features of Resistors in Series

Example 4.2 Calculating Resistance, Current, Power Dissipation, and Power Output: Analysis of a Parallel Circuit

Let the voltage output of the battery and resistances in the parallel connection in Figure 4.4 be the same as the previously considered series connection: $V=\text{12}\text{.}0\text{V}\text{,}V=\text{12}\text{.}0\text{V}\text{,}$ $R_1=1\text{.}\text{00}\text{Ω}\text{,}{R}_1=1\text{.}\text{00}\text{Ω}\text{,}$ $R_2=6\text{.}\text{00}\text{Ω}\text{,}{R}_2=6\text{.}\text{00}\text{Ω}\text{,}$ and $R_3=\text{13}\text{.}0\text{Ω}\text{.}{R}_3=\text{13}\text{.}0\text{Ω}\text{.}$ (a) What is the total resistance? (b) Find the total current. (c) Calculate the currents in each resistor and show that these add to equal the total current output of the source. (d) Calculate the power dissipated by each resistor. (e) Find the power output of the source and show that it equals the total power dissipated by the resistors.

Strategy and Solution for (a)

The total resistance for a parallel combination of resistors is found using the equation below. Entering known values gives

Thus,

Note that in these calculations, each intermediate answer is shown with an extra digit.

We must invert this to find the total resistance $R_{\text{p}}\text{.}{R}_{\text{p}}\text{.}$ This yields

The total resistance with the correct number of significant digits is $R_{\text{p}}=0\text{.}\text{804}\text{Ω}.R_{\text{p}}=0\text{.}\text{804}\text{Ω}.$

Discussion for (a)

$R_{\text{p}}$ is, as predicted, less than the smallest individual resistance.

Strategy and Solution for (b)

The total current can be found from Ohm’s law, substituting $R_{\text{p}}{R}_{\text{p}}$ for the total resistance. This gives

Discussion for (b)

Current $II$ for each device is much larger than for the same devices connected in series (see the previous example). A circuit with parallel connections has a smaller total resistance than the resistors connected in series.

Strategy and Solution for (c)

The individual currents are easily calculated from Ohm’s law since each resistor gets the full voltage. Thus,

Similarly,

and

Discussion for (c)

The total current is the sum of the individual currents.

This is consistent with conservation of charge.

Strategy and Solution for (d)

The power dissipated by each resistor can be found using any of the equations relating power to current, voltage, and resistance since all three are known. Let us use $P=\frac{V^2}{R}P=\frac{V^2}{R}$ since each resistor gets full voltage. Thus,

Similarly,

and

Discussion for (d)

The power dissipated by each resistor is considerably higher in parallel than when connected in series to the same voltage source.

Strategy and Solution for (e)

The total power can also be calculated in several ways. Choosing $P=\text{IV}P=\text{IV}$ and entering the total current yields

Discussion for (e)

Total power dissipated by the resistors is also 179 W.

This is consistent with the law of conservation of energy.

Overall Discussion

Note that both the currents and the powers in parallel connections are greater than for the same devices in series.

Major Features of Resistors in Parallel

Example 4.3 Calculating Resistance, $\text{IR}\text{IR}$ Drop, Current, and Power Dissipation: Combining Series and Parallel Circuits

Figure 4.6 shows the resistors from the previous two examples wired in a different way—a combination of series and parallel. We can consider $R_1{R}_1$ to be the resistance of wires leading to $R_2{R}_2$ and $R_3\text{.}{R}_3\text{.}$ (a) Find the total resistance. (b) What is the $\text{IR}\text{IR}$ drop in $R_1{R}_1$? (c) Find the current $I_2{I}_2$ through $R_2\text{.}{R}_2\text{.}$ (d) What power is dissipated by $R_2\text{?}{R}_2\text{?}$

Figure 4.6 These three resistors are connected to a voltage source so that $R_2{R}_2$ and $R_3{R}_3$ are in parallel with one another and that combination is in series with $R_1\text{.}{R}_1\text{.}$

Strategy and Solution for (a)

To find the total resistance, we note that $R_2{R}_2$ and $R_3{R}_3$ are in parallel and their combination $R_{\text{p}}{R}_{\text{p}}$ is in series with $R_1\text{.}{R}_1\text{.}$ Thus, the total (equivalent) resistance of this combination is

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

Inverting gives

So the total resistance is

Discussion for (a)

The total resistance of this combination is intermediate between the pure series and pure parallel values $\text{(}\mathrm{20.0\; \Omega }$ and $\mathrm{0.804\; \Omega }\text{,}$ respectively) found for the same resistors in the two previous examples.

Strategy and Solution for (b)

To find the $\text{IR}\text{IR}$ drop in $R_1\text{,}{R}_1\text{,}$ we note that the full current $II$ flows through $R_1\text{.}{R}_1\text{.}$ Thus, its $\text{IR}\text{IR}$ drop is

We must find $II$ before we can calculate $V_1\text{.}{V}_1\text{.}$ The total current $II$ is found using Ohm’s law for the circuit. That is,

Entering this into the expression above, we get

Discussion for (b)

The voltage applied to $R_2{R}_2$ and $R_3{R}_3$ is less than the total voltage by an amount $V_1\text{.}{V}_1\text{.}$ When wire resistance is large, it can significantly affect the operation of the devices represented by $R_2{R}_2$ and $R_3\text{.}{R}_3\text{.}$

Strategy and Solution for (c)

To find the current through $R_2\text{,}{R}_2\text{,}$ we must first find the voltage applied to it. We call this voltage $V_{\text{p}}{V}_{\text{p}}$ because it is applied to a parallel combination of resistors. The voltage applied to both $R_2{R}_2$ and $R_3{R}_3$ is reduced by the amount $V_1\text{,}{V}_1\text{,}$ so it is

Now the current $I_2{I}_2$ through resistance $R_2{R}_2$ is found using Ohm’s law.

Discussion for (c)

The current is less than the 2.00 A that flowed through $R_2{R}_2$ when it was connected in parallel to the battery in the previous parallel circuit example.

Strategy and Solution for (d)

The power dissipated by $R_2{R}_2$ is given by

Discussion for (d)

The power is less than the 24.0 W that this resistor dissipated when connected in parallel to the 12.0-V source.