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OhmOhm’’s Laws Law
Topics Covered in Chapter 3
3-1: The Current I = V/R
3-2: The Voltage V = IR
3-3: The Resistance R = V/I
3-4: Practical Units
3-5: Multiple and Submultiple Units
ChapterChapter33
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
Topics Covered in Chapter 3Topics Covered in Chapter 3
3-6: The Linear Proportion between V and I
3-7: Electric Power
3-8: Power Dissipation in Resistance
3-9: Power Formulas
3-10: Choosing a Resistor for a Circuit
3-11: Electric Shock
3-12: Open-Circuit and Short-Circuit Troubles
McGraw-Hill © 2007 The McGraw-Hill Companies, Inc. All rights reserved.
OhmOhm’’s Laws Law
Ohm's law states that, in an electrical circuit, the current passing through most materials is directly proportional to the potential difference applied across them.
33--11——33--3: Ohm3: Ohm’’s Law Formulass Law Formulas
There are three forms of Ohm’s Law:
I = V/R
V = IR
R = V/I
where:
I = Current
V = Voltage
R = Resistance
Fig. 3-4: A circle diagram to help in memorizing the Ohm’s Law formulas V = IR, I = V/R, and R= V/I. The V is always at the top.
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
33--1: The Current 1: The Current I I = = V/RV/R
I = V/R
In practical units, this law may be stated as:
amperes = volts / ohms
Fig. 3-1: Increasing the applied voltage V produces more current I to light the bulb with more intensity.
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
33--4: Practical Units4: Practical Units
The three forms of Ohm’s law can be used to define the practical units of current, voltage, and resistance:
1 ampere = 1 volt / 1 ohm
1 volt = 1 ampere × 1 ohm
1 ohm = 1 volt / 1 ampere
33--4: Practical Units4: Practical Units
?
20 V 4 Ω I = 20 V
4 Ω= 5 A
1 A
? 12 Ω V = 1A × 12 Ω = 12 V
3 A
6 V ? R =6 V
3 A= 2 Ω
Applying Ohm’s Law V
I R
ProblemProblem
Solve for the resistance, R, when V and I are known
a. V = 14 V, I = 2 A, R = ?
b. V = 25 V, I = 5 A, R = ?
c. V = 6 V, I = 1.5 A, R = ?
d. V = 24 V, I = 4 A, R = ?
33--5: Multiple and Submultiple Units5: Multiple and Submultiple Units
Units of Voltage
The basic unit of voltage is the volt (V).
Multiple units of voltage are: kilovolt (kV)
1 thousand volts or 103 V
megavolt (MV)1 million volts or 106 V
Submultiple units of voltage are: millivolt (mV)
1-thousandth of a volt or 10-3 V
microvolt (µV)1-millionth of a volt or 10-6 V
33--5: Multiple and Submultiple Units5: Multiple and Submultiple Units
Units of Current
The basic unit of current is the ampere (A).
Submultiple units of current are:
milliampere (mA)
1-thousandth of an ampere or 10-3 A
microampere (µA)
1-millionth of an ampere or 10-6 A
33--5: Multiple and Submultiple Units5: Multiple and Submultiple Units
Units of Resistance
The basic unit of resistance is the Ohm (Ω).
Multiple units of resistance are:
kilohm (kΩ)
1 thousand ohms or 103 Ω
Megohm (MΩ)
1 million ohms or 106 Ω
ProblemProblem
How much is the current, I, in a 470-kΩ resistor if its voltage is 23.5 V?
How much voltage will be dropped across a 40 kΩresistance whose current is 250 µA?
33--6: The Linear Proportion between 6: The Linear Proportion between
VV and and II
The Ohm’s Law formula I = V/R states that V and I are directly proportional for any one value of R.
Fig. 3.5: Experiment to show that I increases in direct proportion to V with the same R. (a) Circuit with variable V but constant R. (b) Table of increasing I for higher V. (c) Graph of Vand I values. This is a linear volt-ampere characteristic. It shows a direct proportion between V and I.Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
33--6: The Linear Proportion between 6: The Linear Proportion between
VV and and II
When V is constant:
I decreases as R increases.
I increases as R decreases.
Examples:
If R doubles, I is reduced by half.
If R is reduced to ¼, I increases by 4.
This is known as an inverse relationship.
33--6: The Linear Proportion between 6: The Linear Proportion between
VV and and II
Linear Resistance
A linear resistance has a constant value of ohms. Its Rdoes not change with the applied voltage, so V and I are directly proportional.
Carbon-film and metal-film resistors are examples of linear resistors.
33--6: The Linear Proportion between 6: The Linear Proportion between
VV and and II
0 1 2 3 4 5 6 7 8 9
1
2
3
4
Volts
Am
per
es
2 Ω
+
_
0 to 9 Volts
2 Ω1 Ω
4 Ω
The smaller the resistor, the steeper the slope.
33--6: The Linear Proportion between 6: The Linear Proportion between
VV and and II
Nonlinear Resistance
In a nonlinear resistance, increasing the applied Vproduces more current, but I does not increase in the same proportion as the increase in V.
Example of a Nonlinear Volt–Ampere Relationship:
As the tungsten filament in a light bulb gets hot, its resistance increases.
VoltsA
mp
ere
sVolts
Am
pere
s
33--6: The Linear Proportion between 6: The Linear Proportion between
VV and and II
Another nonlinear resistance is a thermistor.
A thermistor is a resistor whose resistance value changes with its operating temperature.
As an NTC (negative temperature coefficient)
thermistor gets hot, its resistance decreases.
Volts
Am
pere
s
Thermistor
Volts
Am
pere
s
Thermistor
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
33--7: Electric Power7: Electric Power
The basic unit of power is the watt (W).
Multiple units of power are: kilowatt (kW):
1000 watts or 103 W
megawatt (MW):1 million watts or 106 W
Submultiple units of power are: milliwatt (mW):
1-thousandth of a watt or 10-3 W
microwatt (µW):1-millionth of a watt or 10-6 W
33--7: Electric Power7: Electric Power
Work and energy are basically the same, with identical units.
Power is different. It is the time rate of doing work.
Power = work / time.
Work = power × time.
33--7: Electric Power7: Electric Power
Practical Units of Power and Work:
The rate at which work is done (power) equals the product of voltage and current. This is derived as follows:
First, recall that:
1 volt =1 coulomb
1 joule 1 coulomb
1 second1 ampere =and
33--7: Electric Power7: Electric Power
Power = Volts × Amps, or
P = V × I
Power (1 watt) =1 joule
1 coulomb×
1 coulomb
1 second
1 joule
1 second=
33--7: Electric Power7: Electric Power
Kilowatt Hours
The kilowatt hour (kWh) is a unit commonly used for large amounts of electrical work or energy.
For example, electric bills are calculated in kilowatt hours. The kilowatt hour is the billing unit.
The amount of work (energy) can be found by multiplying power (in kilowatts) × time in hours.
33--7: Electric Power7: Electric Power
To calculate electric cost, start with the power:
An air conditioner operates at 240 volts and 20 amperes.
The power is P = V × I = 240 × 20 = 4800 watts.
Convert to kilowatts:
4800 watts = 4.8 kilowatts
Multiply by hours: (Assume it runs half the day)
energy = 4.8 kW × 12 hours = 57.6 kWh
Multiply by rate: (Assume a rate of $0.08/ kWh)
cost = 57.6 × $0.08 = $4.61 per day
ProblemProblem
How much is the output voltage of a power supply if it supplies 75 W of power while delivering a current of 5 A?
How much does it cost to light a 300-W light bulb for 30 days if the cost of the electricity is 7¢/kWh.
33--8: Power Dissipation in Resistance8: Power Dissipation in Resistance
When current flows in a resistance, heat is produced from the friction between the moving free electrons and the atoms obstructing their path.
Heat is evidence that power is used in producing current.
33--8: Power Dissipation in Resistance8: Power Dissipation in Resistance
The amount of power dissipated in a resistance may be calculated using any one of three formulas, depending on which factors are known:
P = I2×R
P = V2 / R
P = V×I
ProblemProblem
Solve for the power, P, dissipated by the resistance, R
a. I = 1 A, R = 100Ω , P = ?
b. I = 20 mA, R = 1 kΩ , P = ?
c. V = 5 V, R = 150Ω , P = ?
d. V = 22.36 V, R = 1 kΩ , P = ?
How much power is dissipated by an 8-Ω load if the current in the load is 200 mA?
33--9: Power Formulas9: Power Formulas
There are three basic power formulas, but each can be in three forms for nine combinations.
PV
R=
2
RV
P=
2
V PR=
P VI=
IP
V=
VP
I=
P I R=2
IP
R=
RP
I=
2
Where:P = Power V = Voltage I = Current R=Resistance
33--9: Power Formulas9: Power Formulas
Combining Ohm’s Law and the Power Formula
All nine power formulas are based on Ohm’s Law.
Substitute IR for V to obtain:
P = VI
= (IR)I
= I2R
P = VIV = IR
R
VI =
33--9: Power Formulas9: Power Formulas
Combining Ohm’s Law and the Power Formula
Substitute V/R for I to obtain:
P = VI
= V × V/ R
= V2 / R
33--9: Power Formulas9: Power Formulas
Applying Power Formulas:
20 V 4 ΩΩΩΩ
5 A P = VI = 20 × 5 = 100 W
P = I2R = 25 × 4 = 100 W
P = V
2
R=
400
4= 100 W
ProblemProblem
What is the resistance of a device that dissipates 1.2 kW of power when its current is 10 A?
How much current does a 960 W coffeemaker draw from the 120 V power line?
What is the resistance of a 20 W, 12 V halogen lamp?
33--10: Choosing a Resistor10: Choosing a Resistor
for a Circuitfor a Circuit
Follow these steps when choosing a resistor for a circuit:
Determine the required resistance value as R = V / I.
Calculate the power dissipated by the resistor using any of the power formulas.
Select a wattage rating for the resistor that will provide an adequate cushion between the actual power dissipation and the resistor’s power rating.
Ideally, the power dissipation in a resistor should never be more than 50% of its power rating.
ProblemProblem
Determine the required resistance and appropriate wattage rating of a carbon-film resistor to meet the following requirements. The resistor has a 54-V IR drop when its current is 20 mA. The resistors available have the following wattage ratings:
1/8 W, 1/4 W, 1/2 W, 1 W, and 2 W.
33--10: Choosing a Resistor10: Choosing a Resistor
for a Circuitfor a Circuit
Maximum Working Voltage Rating
A resistor’s maximum working voltage rating is the maximum voltage a resistor can withstand without internal arcing.
The higher the wattage rating of the resistor, the higher the maximum working voltage rating.
33--10: Choosing a Resistor10: Choosing a Resistor
for a Circuitfor a Circuit
Maximum Working Voltage Rating
With very large resistance values, the maximum working voltage rating may be exceeded before the power rating is exceeded.
For any resistor, the maximum voltage which produces the rated power dissipation is:
Vmax =
Exceeding Vmax causes the resistor’s power dissipation
to exceed its power rating
Prating × R
33--11: Electric Shock11: Electric Shock
When possible, work only on circuits that have the power shut off.
If the power must be on, use only one hand when making voltage measurements.
Keep yourself insulated from earth ground.
Hand-to-hand shocks can be very dangerous because current is likely to flow through the heart!
33--12: Open12: Open--Circuit and Circuit and
ShortShort--Circuit TroublesCircuit Troubles
An open circuit has zero current flow.
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.