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1
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- Ohm’s Law, Power,
- and Energy
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2
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- Current in a resistive circuit
- Directly proportional to its applied voltage
- Inversely proportional to its resistance
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3
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- For a fixed resistance
- Doubling voltage doubles the current
- For a fixed voltage
- Doubling resistance halves the current
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4
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- Also expressed as E = IR and R = E/I
- Express all quantities in base units of volts, ohms, and amps or utilize
the relationship between prefixes
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5
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- Linear relationship between current and voltage
- y = mx
- y is the current
- x is the voltage
- m is the slope
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6
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- Slope (m) determined by resistor
conductance
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7
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8
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- Current can only exist where there is a conductive path
- Open circuit
- When there is no conductive path
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9
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- If I = 0
- Ohm’s Law gives R = E/I = E/0 ® infinity
- An open circuit has infinite resistance
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10
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- Voltage sources
- Voltage drops
- V = IR
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11
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- Polarity of voltage drops across resistors is important in circuit
analysis
- Drop is + to – in the direction of conventional current
- To show this, place plus sign at the tail of current arrow
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12
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13
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- Current usually proceeds out of the positive terminal of a voltage
source
- If the current is actually in this direction, it will be supplying power
to the circuit
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14
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- If the current is in the opposite direction (going into the positive
terminal), it will be absorbing power (like a resistor)
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15
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- See two representations of the same current on next slide
- Notice that a negative current actually proceeds in a direction opposite
to the current arrow
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16
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17
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- The greater the power rating of a light, the more light energy it can
produce each second
- The greater the power rating of a heater, the more heat energy it can
produce
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18
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- The greater the power rating of a motor, the more mechanical work it can
do per second
- Power is related to energy
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19
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- Power is the rate of doing work
- Power is measured in watts (W)
- Work and energy measured in joules (J)
- One watt =
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20
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- From V = W/Q and I = Q/t, we get
- P = VI
- From Ohm’s Law, we can also find that
- P = I2R and P = V2/R
- Power is always in watts
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21
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- We should be able to use any of the power equations to solve for V, I,
or R if P is given
- For example:
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22
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- Resistors must be able to safely dissipate their heat without damage
- Common power ratings of resistors are 1/8, 1/4, 1/2, 1, or 2 watts
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23
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- A safety margin of two times the expected power is customary
- An overheated resistor
- Often the symptom of a problem rather than its cause
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24
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- Energy =
- Units are joules
- Watt-seconds
- Watt-hours or kilowatt-hours
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25
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- Energy use is measured in kilowatt-hours by the power company
- For multiple loads
- Total energy is sum of the energy of
individual loads
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26
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- Cost =
- Energy × cost per unit or
- Cost =
- Power × time × cost per unit
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27
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- To find the cost of running a 2000-watt heater for 12 hours if electric
energy costs $0.08 per kilowatt-hour:
- Cost = 2kW × 12 hr × $0.08 Cost
= $1.92
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28
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- Energy can neither be created nor destroyed
- Converted from one form to another
- Examples:
- Electric energy into heat
- Mechanical energy into electric energy
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29
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- Energy conversions
- Some energy may be dissipated as heat, giving lower efficiency
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30
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- Poor efficiency in energy transfers results in wasted energy
- An inefficient piece of equipment generates more heat
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31
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- Efficiency (in %) is represented by η (Greek letter eta)
- Ratio of power out to power
- Heat removal requires fans and heat sinks
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32
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- Always less than or equal to 100%
- Efficiencies vary greatly:
- Power transformers may have efficiencies of up to 98%
- Some amplifiers have efficiencies below 50%
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33
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- To find the total efficiency of a system
- Obtain product of individual efficiencies of all subsystems:
- hTotal = h1 × h2 × h3 × ∙∙∙
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Notes