I think there is some confusion (maybe only on my part
) about the term compression.
I think of compression as the limits to a loudspeaker's ability to produce louder sound with signals of increasing power. Imagine if we had a "perfect" amplifier that produced unlimited power with no distortion, and a "real world" loudspeaker. As power increases, the speaker gets louder in a predictable (linear or log-linear) fashion. At some power level, the speaker can't continue doing that – increased power no longer results in increased loudness. The speaker's response is said to be compressed. Sometimes I hear people refer to this as a speaker's "dynamic range".
I thought you understood right, except the Rane article referred to the low frequency signal started clipping, then compression starts but the high frequency components has not reached the clipping point and since people could not hear low frequency distortions (due to clipping) very well so they tend to crank the volume up to compensate and so the high frequency components would continue to climb until they reached the clipping point and perhaps only then people could hear the distortion and therefore stopped turning the volume up. The tweeter would have blown from thermal and/or excessive cone excursion long
before the amp has reached the point where it would begin to clip the high frequencies as well.
After reading the Rane article, I think it says "clipping" is what an amplifier does as it is over driven, and "compression" is what a speaker does when over driven. They're related, but not the same thing.
Exactly, but once the low frequency components reached the clipping point, as Rane said, it would start to compress because the amp could not go further, the waveform would get flattened, and that is truly compression by definitions (including yours) that's what I said to Rich too in post#2 and he agreed in his post#3.
The article's main point was that woofers and tweeters don't necessarily have the same upper limits of response as power increases, nor do they have the same thermal failure range. A power level that leads to amplifier clipping at a woofer frequency can at the same time over drive a tweeter. The woofer produces sound from the clipped signal without failure, and the tweeter compresses and ultimately fails, without necessarily producing a clipped signal from the amp.
That's where you might be slightly off, just a little. The article did not say the tweeter would fail on compression, he said the woofer did, and that would happen before the high frequencies reached the clipping point. The problem is that the tweeter would have been overdriven already well before the amp begins to clip the high frequencies because the power handling capability of tweeters are much lower. So when he said compression is the real cause he referred to the low frequencies compression.
To summarize, the failure sequences would seem to be: Amp clipped LF components, user increases volume, Amp compresses LF after clipping point is reached, user continue to increase volume for louder music, LF continues to compress, HF volume goes up dB by dB and then fail on thermal and/or voice coil over excursion before Amp reaches clipping point for the HF). More detailed account as below:
1) The person crank the volume up for louder sound and/or more bass.
2) If the amp is not powerful enough for the user, the person would therefore crank it up too high such that the amp would clip the low frequencies but not yet the high frequencies because typical music contents have much lower high frequency energies.
3) At that point the owner could not hear the LF distortion too well so he kept on increasing the volume.
4) Now the amp would have no choice but compresses because it could not increase the LF component voltage further.
5) Again, the amp would not be clipping the higher frequencies so if the amp is rated 100W, the amp would have reach its voltage limit for the low frequencies but not the high frequencies until the HF components also reach say the 100W mark (whatever voltage needed at that point).
6) So the user would continue to increase the volume until he could no longer stand the audible distortion (say by the distorted high frequencies from clipping), but before that point is reached, the amp's output voltage would have put too much energy into the tweeter and cause it to fail, that is, the tweeter is just overdriven by an unclipped or mostly unclipped signal.
In other words, he does believe it is overpowering that kills tweeters, not underpowering and he recognize why people were led to believe it was the other way round. He also believes more powerful amps tend to not damaging tweeters as often because more powerful amp would have lesser chance to cause compression in woofers, so users would get the loudness they want, without having to crank to volume up under the misconception that the SPL would increase proportionally when in fact only the high frequencies would increase in SPL while the low frequencies SPL would remain flat, hence compressing.
