21.1 Resistors in series and parallel (Page 3/18)

Page 3 / 18

\begin{array}{l} R_{s} & = & R_{1} + R_{2} + R_{3} \\ = & 1.00 Ω + 6.00 Ω + 13.0 Ω \\ = & 20.0 Ω. \end{array}

Strategy and Solution for (b)

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

I = \frac{V}{R_{s}} = \frac{12.0 V}{20.0 Ω} = 0 . 600 A .

Strategy and Solution for (c)

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

V_{1} = {IR}_{1} = (0.600 A) (1.0 Ω) = 0 . 600 V .

Similarly,

V_{2} = {IR}_{2} = (0.600 A) (6.0 Ω) = 3 . 60 V

and

V_{3} = {IR}_{3} = (0.600 A) (13.0 Ω) = 7 . 80 V .

Discussion for (c)

The three $IR$ drops add to $12.0 V$ , as predicted:

V_{1} + V_{2} + V_{3} = (0 . 600 + 3 . 60 + 7 . 80) V = 12 . 0 V .

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 , $P = IV$ , where $P$ is electric power. In this case, each resistor has the same full current flowing through it. By substituting Ohm’s law $V = IR$ into Joule’s law, we get the power dissipated by the first resistor as

P_{1} = I^{2} R_{1} = (0.600 A)^{2} (1.00 Ω) = 0 . 360 W .

Similarly,

P_{2} = I^{2} R_{2} = (0.600 A)^{2} (6.00 Ω) = 2 . 16 W

and

P_{3} = I^{2} R_{3} = (0.600 A)^{2} (13.0 Ω) = 4 . 68 W .

Discussion for (d)

Power can also be calculated using either $P = IV$ or $P = \frac{V^{2}}{R}$ , where $V$ 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 $P = IV$ , where $V$ is the source voltage. This gives

P = (0.600 A) (12.0 V) = 7 . 20 W .

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,

P_{1} + P_{2} + P_{3} = (0 . 360 + 2 . 16 + 4 . 68) W = 7 . 20 W .

Power is energy per unit time (watts), and 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

Series resistances add: $R_{s} = R_{1} + R_{2} + R_{3} + . . . .$
The same current flows through each resistor in series.
Individual resistors in series do not get the total source voltage, but divide it.

Resistors in parallel

[link] shows resistors in parallel , wired to a voltage source. Resistors are in parallel when each resistor is connected directly to the voltage source by connecting wires having negligible resistance. Each resistor thus has the full voltage of the source applied to it.

Each resistor draws the same current it would if it alone were connected to the voltage source (provided the voltage source is not overloaded). For example, an automobile’s headlights, radio, and so on, are wired in parallel, so that they utilize the full voltage of the source and can operate completely independently. The same is true in your house, or any building. (See [link] (b).)

Part a shows two electrical circuits which are compared. The first electrical circuit is arranged with resistors in parallel. The circuit has three paths, with a voltage source V at one end. Just after the voltage source, the circuit has current I. The first path has resistor R sub one and current I sub one after the resistor. The second path has resistor R sub two and current I sub two after the resistor. The third path has resistor R sub three with current I sub three after the resistor. The first circuit is equivalent to the second circuit. The second circuit has a voltage source V and an equivalent parallel resistance R sub p. Part b shows a complicated electrical wiring diagram of a distribution board that supplies electricity to a house. — (a) Three resistors connected in parallel to a battery and the equivalent single or parallel resistance. (b) Electrical power setup in a house. (credit: Dmitry G, Wikimedia Commons)

To find an expression for the equivalent parallel resistance $R_{p}$ , let us consider the currents that flow and how they are related to resistance. Since each resistor in the circuit has the full voltage, the currents flowing through the individual resistors are $I_{1} = \frac{V}{R_{1}}$ , $I_{2} = \frac{V}{R_{2}}$ , and $I_{3} = \frac{V}{R_{3}}$ . Conservation of charge implies that the total current $I$ produced by the source is the sum of these currents:

Questions & Answers

if three forces F1.f2 .f3 act at a point on a Cartesian plane in the daigram .....so if the question says write down the x and y components ..... I really don't understand

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the value of V1 and V2

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advantages of electrons in a circuit

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we're do you find electromagnetism past papers

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it is the force or component of the force that the surface exert on an object incontact with it and which acts perpendicular to the surface

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what is the half reaction of Potassium and chlorine

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how to calculate coefficient of static friction

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how to calculate static friction

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How to calculate a current

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a structure of a thermocouple used to measure inner temperature

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a fixed gas of a mass is held at standard pressure temperature of 15 degrees Celsius .Calculate the temperature of the gas in Celsius if the pressure is changed to 2×10 to the power 4

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what is acceleration

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a rate of change in velocity of an object whith respect to time

Khuthadzo

how can we find the moment of torque of a circular object

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Acceleration is a rate of change in velocity.

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t =r×f

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Source: OpenStax, College physics for ap® courses. OpenStax CNX. Nov 04, 2016 Download for free at https://legacy.cnx.org/content/col11844/1.14

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