Home   |  Schematics |  Products |  Tutorials  |  Datasheets  |  Robotics   |   Download    |   Link Exchange

Direct Current
 Alternating Current
 Digital Electronics
 PC Architecture
Electronics Dictionary
Resources

 Experiment
 Calculator/Converters
 Radio
 Newsletter
Associations and Societies
 Component Manufacturers

1. AC resistor circuits

2. AC capacitor circuits

3. Series resistor-capacitor circuits

4. Parallel resistor-capacitor circuits

5. Capacitor quirks
 

Electronics Symentics
A B C D E
F G H I J
K L M N O
P Q R S T
U V W X Y
Z        

Back  Home   Chapter Index

 
 
 

AC resistor circuits

If we were to plot the current and voltage for a very simple AC circuit consisting of a source and a resistor, it would look something like this:

Because the resistor allows an amount of current directly proportional to the voltage across it at all periods of time, the waveform for the current is exactly in phase with the waveform for the voltage. We can look at any point in time along the horizontal axis of the plot and compare those values of current and voltage with each other (any "snapshot" look at the values of a wave are referred to as instantaneous values, meaning the values at that instant in time). When the instantaneous value for voltage is zero, the instantaneous current through the resistor is also zero. Likewise, at the moment in time where the voltage across the resistor is at its positive peak, the current through the resistor is also at its positive peak, and so on. At any given point in time along the waves, Ohm's Law holds true for the instantaneous values of voltage and current.

We can also calculate the power dissipated by this resistor, and plot those values on the same graph:

Note that the power is never a negative value. When the current is positive (above the line), the voltage is also positive, resulting in a power (p=ie) of a positive value. Conversely, when the current is negative (below the line), the voltage is also negative, which results in a positive value for power (a negative number multiplied by a negative number equals a positive number). This consistent "polarity" of power tells us that the resistor is always dissipating power, taking it from the source and releasing it in the form of heat energy. Whether the current is positive or negative, a resistor still dissipates energy.

 

 




Home  Products  Tutorials   Schematics   Robotics   Resources   Radio Stuff    Career    Download   Link Exchange

HTML Sitemap   XML Sitemap

Terms & Conditions  Privacy Policy and Disclaimer