I understand impedance is resistance. A smaller impedance means less resistance and thus requires more power ( in watts) to drive it. and allows this power in due to the lower resistance
using the hose analogy (more water).
I think you've got the idea. In the stricter sense impedance generally implies it is a complex number consisting of components more than just resistance. It may contain a combination of resistive, inductive and capacitive reactance. Yes the lower value it is, the more current it would allow to pass through the circuit but it does not mean more power will be developed. For example, you could have a very low impedance that is made up of almost pure inductive reactance. In that case you get high reactive power (unit in VA) but almost zero real power (unit in watts). Again, if you ignore the technical terms I think you got the concept.
Now here is where the questions start. I read if you hook up two speakers to an amp that has inputs for two speakers then they will be set up in 'parallel' and thus the impedance half's?
That is only true if you hook up two speakers to the same amp channel. If you hook up one speaker to each of the two channel than each amp channel will still see the full impedance of the speaker, NOT half.
Now from the various responses on here I gather that Nominal is the impedance listed when a speaker only lists one value and is essentially the average impedance however minimum impedance is very important as it requires more flow of current at that level and if they amp cannot provide this then ...your screwed.
I would not say nominal necessarily mean average. You need to ask the individual manufactuer. I am not aware of an univerally accepted/adopted definition of "nominal impedance". As to whether you are screwed it depends on other factors. If the minimum impedance occurs at a higher and narrow frequency range and where the phase angles between the current and voltage phasors (or commonly referred to as vectors, a term that a high school science student would be familiar with) are small, say less than 30 degrees, then it most likely won't be an issue for most amps. That is unless it is really low, like 3 ohms or less. Conversely, even 5 to 6 ohms could be tough for many amps if such values occur over a wider and lower frequency range; and coincides with where the phase angles are large, say >45 degrees.
Now if we consider amp and speaker matching. I have listed some specs of the amp I purchased the other day below. Essentially considering you dont want a distortion of 10%.
Agree, to me anything more than 0.1% is not good, except for tube amps.
Therefore when looking at the amp data you look at the 4ohm specs. i.e. as below ( 2x48W) into 4 ohms at 0.1% THD.
In many cases yes, but the amp you listed outputs only 27W into 8 ohms, at 0.1% THD. So in this case I would consider it a 27W per channel amp, at the very maximum.
Then finally consider the min impedance. 4 ohms per speaker = 2 ohms per channel when running in parallel fashion. Now although this amp isn't rated for 2ohms, it wont have to run this all the time and should be powerful enough to handle it if not overdriven.
Again, if you connect one speaker to each of the two amp channels, the amp will not see a halved impedance.
(I understand all the impedence varies with the frequency curves and thus all speakers are going to make the amp provide power at lower impedence levels at times that they may not be rated for.
It does not seem to make much sense in a strict sense but again I think you understand the principle so I am not going to be critical on its lack of accuracy in terms of proper engineering language.
Save you Googling, use the following formula to calculate equivalent resistance:
1/Req=1/R1+1/R2+.........+1/Rn
Example: if you have two 8 ohm resistors in parallel,
1/Req=1/8+1/8=1/4 therefore Req = 4 ohms
or one 8 ohm and one 2 ohm in parallel,
1/Req=1/8+1/2 = 5/8, therefore Req = 1.6 ohms
Now people just don't parallel two disimilar speakers so the second example is just for illustrating how to calculate the equivalent resistance. For impedance it gets more complicated but if you are interested I am sure you know how to google or where the libraries are.
