16.3

Ohm’s Law / Energy and Power / Electric Meters

Within a battery, a chemical reaction occurs that transfers electrons

from one terminal to another terminal.

This potential difference across the terminals is called the voltage.

Voltage

Ohm’s Law

Voltage produces a flow of charge, or current, within a

conductor.

The flow is restrained by the resistance it encounters.

The rate at which energy is transferred by electric current is

power.

Ohm’s Law

The relationship among voltage, current, and resistance is

called Ohm’s Law.

Ohm’s Law states:

Current in a circuit is directly proportional to the voltage

across the circuit, and is inversely proportional to the

resistance of the circuit.

Voltage

(Volts)

(Joules / Coulomb)

Current

(Amperes)

(Coulomb / Sec)

Resistance

(Ohms Ω)

Drop across a

resistive device Current passing

through a

resistive device

Ohm’s Law

Ohm’s Law

Ohm’s Law

Example #1

The current in a wire is 24 amperes when connected to a 1.5

volt battery. Find the resistance of the wire.

R = 0.0625 Ω

Ohm’s Law

Example #2

In a simple electric circuit, a 24 Ω resistor is connected across a

6 volt battery. What is the current in the circuit?

I = 0.25 A

Ohm’s Law

Example #3

A high-beam filament of an automobile headlight carries a current

of 4.5 amps. The voltage difference between its terminals is 12 V.

Calculate the resistance of the filament.

R = 2.667 Ω

Ohm’s Law

Example #4

Calculate the current when a 12-V battery is connected across a 4

Ω resistor.

I = 3 A

Ohm’s Law

V = 12 V R = 6 Ω

I = 2 A

V = 12 V R = 3 Ω

I = 4 A

Ohm’s Law

Electric Circuits

In an electric circuit, an energy source and an energy consuming

device are connected by conducting wires through which electric

charges move.

Electric Circuits

Electric Circuits are typically represented using diagrams know as schematics. Schematics are simplified, standard representation in which common circuit elements are represented with specific symbols, and wires connecting the elements in the circuits are represented by lines.

Electric Circuits

Circuit Symbols

Electric Circuits

In order for current to flow through a circuit, you must have a

source of potential difference.

Typical sources of potential difference are batteries (which are

just two or more cells connected together), and power

supplies (electron pumps).

In drawing a cell or battery on a circuit schematic, remember

that the longer side of the symbol is the positive terminal.

Electric Circuits

Electric circuits must form a complete conducting path

(closed loop) in order for current to flow.

In the example circuit shown below left, the circuit is

incomplete because the switch is open, therefore no current

will flow and the lamp will not light.

Electric Circuits

In the circuit below, the switch is closed, creating a closed

loop path. Current will flow and the lamp will light up.

Energy and Power

Just like mechanical power is the rate at which mechanical

energy is expended, electrical power is the rate at which

electrical energy is expended.

Formula(s):

IVP

RIIRIP 2

R

VV

R

VP

2

SI Unit of Power: Watts (W)

Example #1

A 110 volt toaster over draws a current of 6 amps on its highest

setting as it converts electrical energy into thermal energy. What

is the toaster’s power rating?

Energy and Power

P = 660 W

Example #2

A potential drop of 50 volts is measured across a 250 Ω resistor.

What is the power in the resistor?

Energy and Power

P = 10 W

Example #3

How much electrical energy is required to move 4µC charge

through a potential difference of 6 volts?

Energy and Power

W = 2.4 x 10-5 J

Example #4

What is the resistance of a 60 watt light bulb operated at 120

volts?

Energy and Power

R = 240 Ω

Voltmeters are tools used to measure the potential

difference (voltage) between two points in a circuit.

The voltmeter is connected in parallel with the element to

be measured, meaning an alternate current path around the

element to be measured and through the voltmeter is

created.

Voltmeters have very high resistance so as to minimize the

current flow through the voltmeter and the voltmeter's

impact on the circuit.

Electric Meters - Voltmeters

In the diagram below, a voltmeter is connected to correctly

measure the potential difference (voltage) across the lamp.

Electric Meters - Voltmeters

Ammeters are tools used to measure the current in a circuit.

The ammeter is connected in series with the circuit, so that

the current to be measured flows directly through the

ammeter.

Ammeters have very low resistance to minimize the

potential drop (voltage) through the ammeter and the

ammeter's impact on the circuit, so inserting an ammeter

into a circuit in parallel can result in extremely high

currents and may destroy the ammeter.

Electric Meters - Ammeters

In the diagram below, a ammeter is connected to correctly

measure the current flowing through the circuit.

Electric Meters - Ammeters

Electric Meters

Electric Meters - Voltage

Electric Meters - Series

Electric Meters

Electric Meters

Example #1

In the electric circuit diagram, possible locations of an ammeter

and voltmeter are indicated by circles 1, 2, 3, and 4. Where should

the ammeter be located and where should a voltmeter be located

to correctly measure the total current and voltage?

Electric Meters

Example #2

Which circuit diagrams below correctly shows the connection of

ammeter A and voltmeter V to measure the current through and

potential difference across resistor R?

Electric Meters

Example #3

A student uses a voltmeter to measure the potential difference

across a resistor. To obtain a correct reading, the student must

connect the voltmeter:

a. In series with the resistor

b. In parallel with the resistor

c. Before connecting the other circuit components

d. After connecting the other circuit components

Electric Meters