Ohm's Law

This is a very important aspect of creating and building your speaker system and subwoofers in your car. Understanding it properly will help you to fully understand all of your systems most precious parts and how to put them together yourself.

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Ohm's law is the most basic and most useful electrical equation. Simply and quickly explained Ohm's law is:

E=I*R
This is best explained in that the E represent voltage measured in volts, I is current measure in amps and R is the resistance that is measured in ohms. You will want to memorize this equation because you'll use it a lot in dealing with car audio. For example, if you need to figure out the current (amps) moving through a 12 volt circuit and you know the resistance of the circuit is 4 ohms; the equation would look like this:
E = 12volts
I = unknown
R = 4 ohms
I = E/R or I = 12/4 which is I = 3 amps

Another useful equation to know is the power equation:

P = E*I (power equals voltage multiplied by current or watts = volts amps). From this we can substitute Ohm's law for any values we don't know. For instance if we need to know power but we only have amperage (I) and resistance (R) then we could substitute I*R in the power equation (because according to Ohm's law E=I*R) and get P = I*R*I.

Wiring
There are two ways that you can use to wire electrical components, which are in parallel or in series. Both of them are important to understand, especially when properly hooking up speakers to amplifiers.

Parallel Wiring

Parallel wiring is connecting components to a source so that they share the same voltage. To put that in a useful way, it would be connecting all of the speaker positive terminals to the positive terminal of the amplifier and connecting all of the speaker negative terminals to the negative terminal of the amplifier.






This increases the work load on the amplifier because more current will need to be supplied to this lower resistance (impedance). Parallel resistances (in this case 4 ohm speakers) will combine according to this equation:

1/Rt = 1/R1 + 1/R2 + 1/R3

Where Rt is the total resistance and R1-R3 are the individual resistances. For our example Rt will be the resistance at the amplifier's speaker outputs and R1-R3 will be the resistances of the individual speakers. If we connect (2) four ohm speakers (R1 and R2) in parallel to an amplifier the total resistance will be:

1/Rt = 1/R1 + 1/R2 or 1/Rt = 1/4 + 1/4 or 1/Rt = 1/2
Inverting the equation we get Rt = 2 ohms.

Similarly if we connect (3) four ohm speakers (R1, R2, and R3) we will get:
1/Rt = 1/R1 + 1/R2 + 1/R3 or 1/Rt = 1/4 + 1/4 + 1/4 or 1/Rt = 3/4
Inverting the equation we get Rt = 4/3 or 1.33 ohms.

Series Wiring
Series wiring is connecting components to a source so that they share the same current. To put that in a useful way, it would be connecting the amplifier's positive terminal to the positive terminal of the first speaker and then connecting the negative terminal of the first speaker to the positive terminal of the second speaker and so on. The final speaker in the chain will have its negative terminal connected to the negative terminal of the amplifier.






This decreases the work load on the amplifier because less current will need to be supplied to this higher resistance (impedance). Series resistances (in this case 4 ohm speakers) will combine according to this equation:
Rt = R1 + R2 + R3.

Where Rt is the total resistance and R1-R3 are the individual resistances. For our example Rt will be the resistance at the amplifier's speaker outputs and R1-R3 will be the resistances of the individual speakers. If we connect (2) four ohm speakers (R1 and R2) in series to an amplifier the total resistance will be:

Rt = R1 + R2 or Rt = 4 + 4 or Rt = 8 ohms

at the same time if we connect (3) four ohm speakers (R1, R2, and R3) we will get:

Rt = R1 + R2 + R3 or Rt = 4 + 4 + 4 or Rt = 12 ohms