http://science.howstuffworks.com/environmental/energy/question501.htm http://hyperphysics.phy-­‐astr.gsu.edu/hbase/electric/watcir.html http://chemwiki.ucdavis.edu/Analytical_Chemistry/Electrochemistry/Voltage,_Am
perage_and_Resistance_Basics http://www.circuit-­‐magic.com/voltage_current_resistance.htm http://www.circuit-­‐magic.com/ohms_law.htm http://www.pbslearningmedia.org/asset/hew06_int_ohmslaw/ In an electric circuit, electric charges continuously travel though a closed loop. This flow of charges is
known as electric current. A basic battery-powered electric circuit uses a battery to drive the current
through a loop of wire.
The battery provides a difference in electrical potential energy, or a voltage difference, often simply
referred to as voltage. You can think of it as a difference in pressure: high pressure at one end of the battery
and low pressure at the other. In the same way that a difference in water pressure pushes water through a
pipe, creating a flow of water, a difference in voltage pushes electric charge through the wire, creating a
flow of current through the circuit. The greater the voltage, the greater the current.
When electric current flows through a material, it is likely to encounter resistance. Instead of traveling a
direct path through the closed loop, charges may be scattered as they collide with the atoms of the material.
Electrical resistance is a measure of how much the flow of electric charge is opposed in this way. The
greater the resistance, the more difficult it is for current to flow.
In the nineteenth century, German physicist Georg Simon Ohm realized that there was a mathematical
relationship between current, voltage, and resistance. He understood that electric current is directly
proportional to voltage and inversely proportional to resistance. This relationship can be described by a
simple equation, I= V/R, now known as Ohm's law. It is also commonly written as V = I x R, where:
V = voltage, the difference in electrical potential between the terminals of the voltage source (measured in
volts);
I = current, the rate of flow of electric charge (measured in amperes); and
R = resistance, the measure of opposition to the flow of electric charge (measured in ohms).
Materials that obey Ohm\'s law are said to be ohmic. Almost all electronics contain ohmic devices called
resistors, which are designed specifically to resist electric current. When designing electric circuits,
engineers use resistors to establish specific values for voltage and current. For example, the light-emitting
diode (LED) that is commonly found in electronics—such as that used to light up the numbers on some
digital clocks—can be damaged if too much current runs through it. To make sure that the current reaching
an LED is at a safe value, a resistor is connected in the circuit.