20.2 Ohm’s Law: Resistance and Simple Circuits - College Physics 2e

Learning Objectives

By the end of this section, you will be able to:

Explain the origin of Ohm’s law.
Calculate voltages, currents, or resistances with Ohm’s law.
Explain what an ohmic material is.
Describe a simple circuit.

What drives current? We can think of various devices—such as batteries, generators, wall outlets, and so on—which are necessary to maintain a current. All such devices create a potential difference and are loosely referred to as voltage sources. When a voltage source is connected to a conductor, it applies a potential difference $V$ that creates an electric field. The electric field in turn exerts force on charges, causing current.

Ohm’s Law

The current that flows through most substances is directly proportional to the voltage $V$ applied to it. The German physicist Georg Simon Ohm (1787–1854) was the first to demonstrate experimentally that the current in a metal wire is directly proportional to the voltage applied:

$I \propto V .$

20.12

This important relationship is known as Ohm’s law. It can be viewed as a cause-and-effect relationship, with voltage the cause and current the effect. This is an empirical law like that for friction—an experimentally observed phenomenon. Such a linear relationship doesn’t always occur.

Resistance and Simple Circuits

If voltage drives current, what impedes it? The electric property that impedes current (crudely similar to friction and air resistance) is called resistance $R$ . Collisions of moving charges with atoms and molecules in a substance transfer energy to the substance and limit current. Resistance is defined as inversely proportional to current, or

$I \propto \frac{1}{R} .$

Example 20.4

Calculating Resistance: An Automobile Headlight

What is the resistance of an automobile headlight through which 2.50 A flows when 12.0 V is applied to it?

Strategy

We can rearrange Ohm’s law as stated by $I = V/R$ and use it to find the resistance.

Solution

Rearranging $I = V/R$ and substituting known values gives

$R = \frac{V}{I} = \frac{12 . 0 V}{2 . 50 A} = 4 . 80 Ω .$

20.16

Discussion

This is a relatively small resistance, but it is larger than the cold resistance of the headlight. As we shall see in Resistance and Resistivity, resistance usually increases with temperature, and so the bulb has a lower resistance when it is first switched on and will draw considerably more current during its brief warm-up period.

Resistances range over many orders of magnitude. Some ceramic insulators, such as those used to support power lines, have resistances of $10^{12} Ω$ or more. A dry person may have a hand-to-foot resistance of $10^{5} Ω$ , whereas the resistance of the human heart is about $10^{3} Ω$ . A meter-long piece of large-diameter copper wire may have a resistance of $10^{- 5} Ω$ , and superconductors have no resistance at all (they are non-ohmic). Resistance is related to the shape of an object and the material of which it is composed, as will be seen in Resistance and Resistivity.

Additional insight is gained by solving $I = V/R$ for $V,$ yielding

$V = IR.$

20.17

This expression for $V$ can be interpreted as the voltage drop across a resistor produced by the flow of current $I$ . The phrase $IR$ drop is often used for this voltage. For instance, the headlight in Example 20.4 has an $IR$ drop of 12.0 V. If voltage is measured at various points in a circuit, it will be seen to increase at the voltage source and decrease at the resistor. Voltage is similar to fluid pressure. The voltage source is like a pump, creating a pressure difference, causing current—the flow of charge. The resistor is like a pipe that reduces pressure and limits flow because of its resistance. Conservation of energy has important consequences here. The voltage source supplies energy (causing an electric field and a current), and the resistor converts it to another form (such as thermal energy). In a simple circuit (one with a single simple resistor), the voltage supplied by the source equals the voltage drop across the resistor, since $PE = q Δ V$ , and the same $q$ flows through each. Thus the energy supplied by the voltage source and the energy converted by the resistor are equal. (See Figure 20.9.)

20.2 Ohm’s Law: Resistance and Simple Circuits - College Physics 2e | OpenStax (2)

Figure 20.9 The voltage drop across a resistor in a simple circuit equals the voltage output of the battery.

PhET Explorations

Making Connections: Conservation of Energy

In a simple electrical circuit, the sole resistor converts energy supplied by the source into another form. Conservation of energy is evidenced here by the fact that all of the energy supplied by the source is converted to another form by the resistor alone. We will find that conservation of energy has other important applications in circuits and is a powerful tool in circuit analysis.

PhET Explorations

Ohm's Law

See how the equation form of Ohm's law relates to a simple circuit. Adjust the voltage and resistance, and see the current change according to Ohm's law. The sizes of the symbols in the equation change to match the circuit diagram.

Access multimedia content

20.2 Ohm’s Law: Resistance and Simple Circuits - College Physics 2e | OpenStax (2024)

FAQs

What is the Ohm's law of resistance and simple circuit? ›

A simple circuit is one in which there is a single voltage source and a single resistance. One statement of Ohm's law gives the relationship between current I, voltage V, and resistance R in a simple circuit to be I = V/R. Resistance has units of ohms (Ω), related to volts and amperes by 1 Ω = 1 V/ 1 A.

Find Out More ›

When a resistance of 20 ohms has a current of 2 amps? ›

Solution: A resistance of 20 ohms has a current of 2 amperes flowing in it. 40 V Potential difference is there between its ends. Hence, 40 volt is the required value of potential difference.

See Details ›

What is the Ohm's law in Openstax? ›

Description of Ohm's Law

The current that flows through most substances is directly proportional to the voltage V applied to it. The German physicist Georg Simon Ohm (1787–1854) was the first to demonstrate experimentally that the current in a metal wire is directly proportional to the voltage applied: I ∝ V .

Read The Full Story ›

What is Ohm's law Physics 2? ›

Ohm's Law and Resistance. Ohm's law states that the voltage or potential difference between two points is directly proportional to the current or electricity passing through the resistance, and directly proportional to the resistance of the circuit. The formula for Ohm's law is V=IR.

What is Ohm's law in answer? ›

Ohm's law: Ohm's law states that the voltage across a conductor is directly proportional to the current flowing through it, provided all physical conditions and temperature, remain constant. The mathematical expression for Ohm's law: potential difference ∝ current V ∝ I. Taking proportionality constant , now. V = IR.

Show Me More ›

What is the formula for resistance? ›

How do you calculate the resistance of a resistor? If the current and voltage drop through the resistor is known, the resistance can be calculated using Ohm's law. This law states that R=V/I.

How do you calculate the power across each 20 ohm resistance? ›

Calculate the power across each 20 ohm resistance. Explanation: This is a series connected circuit hence the current across each resistance is the same. To find current: I=V/R=200/20=5A. To find power: P=I²R=5²*20=500W.

Is Ohm's Law hard? ›

Most (if not all) of us have seen the formulas. They're relatively simple, and many of us can easily use rudimentary high school algebra to calculate two values from any other two by just manipulating the formulas. For example, if we know voltage and resistance, we can calculate current and power.

Tell Me More ›

What are the three formulas in Ohm's law? ›

Putting these into words Ohm's Law states that: Voltage equals resistance multiplied by current. Resistance equals voltage divided by current. Current equals voltage divided by resistance.

How do you prove Ohm's law mathematically? ›

Ohm's Law Equation : V = IR, where V is the voltage across the conductor, I is the current flowing through the conductor and R is the resistance provided by the conductor to the flow of current.

Discover More Details ›

What is the Ohm's law for a short circuit? ›

This is due to Ohm's Law, which states that current through a resistor is equal to the voltage across the resistor divided by the resistance, I = V / R . The resistance is usually zero in the event of a short circuit. There are zero ohms in a short circuit.

Get More Info ›

What is the law of resistance in a circuit? ›

Ohm's Law is V = IR, where V = voltage, I = current, and R = resistance. Ohm's Law allows you to determine characteristics of a circuit, such as how much current is flowing through it, if you know the voltage of the battery in the circuit and how much resistance is in the circuit.

Learn More Now ›

What is the law of resistance and resistance? ›

If the temperature and other physical variables stay constant, the resistance of a conductor is exactly proportional to its length. It means that R ∝ l , i.e., if the length rises, the resistance increases as well, and if the length reduces, the resistance lowers as well.

Get More Info Here ›

What does Ohm's law say about resistance? ›

Since voltage is a measure of work per unit charge, Ohm's Law means that for higher resistance materials, it takes more work to push the same flow of current through.

Know More ›

20.2 Ohm’s Law: Resistance and Simple Circuits - College Physics 2e | OpenStax (2024)