I've taken an interest in the past year or so of trying to understand the exact origins of this idea . . . that is, that Global Negative Feedback is a Bad Thing. I think that there are three opening points here that can be accepted as fact:
- The ubiquitous negative view of global NFB in high-end audio is not found in other analog electronic engineering disciplines
- There were many decades between the first patents of the electronic feedback amplifier, and when it started to achieve a pariah status in high-end audio
- It is extremely rare to find a discussion of global NFB in an audio forum or publication where it isn't linked with the promotion of some accompianying viewpoint regarding components or topology . . . i.e. a proxy for a tubes-vs-transistors discussion.
From what I have found, this idea of Global NFB being Bad really came into being in the very early 1970s, in Audio Engineering Society papers written by mainly by Matti Otala, sometimes in association with John Curl. This is the origin of the TIM acronym, meaning Transient Intermodulation Distortion. These days, TIM is more accurately described as slew-limiting distortion, and has been very, very throughly investigated and discussed within AES, including standardized measurement methods.
Matti Otala and others did put forth the viewpoint that global NFB was at least part of the root cause of slew-induced distortion, and in his papers proposed some topologies with greatly reduced open-loop gain (hence less global NFB) as a solution. But while the association of TIM and global NFB somehow remained, Otala's suggested circuit topologies remain obscure. The reason for this is that while slew-induced distortion is indeed affected by circuit choices that also affect the amount of global NFB . . . slew-induced distortion isn't CAUSED by feedback.
The other source of this Bad Feedback idea seems to be a article written by Peter Baxandall for Wireless World, from December 1978. This article contains a graph where Baxandall plots the amplitude of the second through the sixth distortion harmonics (Y-axis) as a function of the feedback ratio (X-axis). Here, at a glance that increasing the feedback up to about 20dB causes an increase in the fourth, fifth, and sixth harmonics while it reduces the amplitude of the second. Continuing to increase the amount of feedback further then reduces all the harmonics in a linear fashion.
This is the ONLY well-documented scholarly paper I have found from which I can imagine comes this idea of global NFB decreasing the amount of lower harmonics, at the cost of increasing the energy in the upper harmonics. But this article is just one in a series of six on power-amplifier design, and if you actually READ them and not just glance at the pretty graphs, it's obvious that this is NOT Baxandall's conclusion from this experiment.
Rather, Peter Baxandall unambiguously states his conclusion from this experiment is that global NFB needs to be INCREASED to reduce all the harmonics to a negligible level, rather than avoided so that the second harmonic can completely dominate the distortion signature. He also specifically emphasizes that "even FETs used without feedback generate high-order harmonics - and therefore . . . high-order intermodulation products".
It's rather unfortunate that in discussions of negative feedback on the internet, the seminal papers from which most of these ideas stem remain largely ignored. This is of course because they're copyrighted, and one simply cannot pop up a link to them. But if anybody's truly interested, the Otala papers (and responses to them) can be obtained from the Audio Engineering Society http://www.aes.org, and the Baxandall series has been re-printed by Jan Didden at http://www.linearaudio.net
- Due to a varying impedance-vs-frequency characteristic, the response of a loudspeaker will be affected by the output impedance of the amplifier, thus . . .
- If the amplifier's output impedance differs significantly from that which the speaker designer used for evaluation, then the response of the speaker will be different from what the designer intended, and . . .
- Although there are no specific standards, *most* loudspeakers are designed with low-output-impedance amplifiers in mind, and . . .
- The use of global or local Negative Feedback is the (almost universally applied) method of acheiving a low output impedance in an amplifier.
- The ubiquitous negative view of global NFB in high-end audio is not found in other analog electronic engineering disciplines
- There were many decades between the first patents of the electronic feedback amplifier, and when it started to achieve a pariah status in high-end audio
- It is extremely rare to find a discussion of global NFB in an audio forum or publication where it isn't linked with the promotion of some accompianying viewpoint regarding components or topology . . . i.e. a proxy for a tubes-vs-transistors discussion.
From what I have found, this idea of Global NFB being Bad really came into being in the very early 1970s, in Audio Engineering Society papers written by mainly by Matti Otala, sometimes in association with John Curl. This is the origin of the TIM acronym, meaning Transient Intermodulation Distortion. These days, TIM is more accurately described as slew-limiting distortion, and has been very, very throughly investigated and discussed within AES, including standardized measurement methods.
Matti Otala and others did put forth the viewpoint that global NFB was at least part of the root cause of slew-induced distortion, and in his papers proposed some topologies with greatly reduced open-loop gain (hence less global NFB) as a solution. But while the association of TIM and global NFB somehow remained, Otala's suggested circuit topologies remain obscure. The reason for this is that while slew-induced distortion is indeed affected by circuit choices that also affect the amount of global NFB . . . slew-induced distortion isn't CAUSED by feedback.
The other source of this Bad Feedback idea seems to be a article written by Peter Baxandall for Wireless World, from December 1978. This article contains a graph where Baxandall plots the amplitude of the second through the sixth distortion harmonics (Y-axis) as a function of the feedback ratio (X-axis). Here, at a glance that increasing the feedback up to about 20dB causes an increase in the fourth, fifth, and sixth harmonics while it reduces the amplitude of the second. Continuing to increase the amount of feedback further then reduces all the harmonics in a linear fashion.
This is the ONLY well-documented scholarly paper I have found from which I can imagine comes this idea of global NFB decreasing the amount of lower harmonics, at the cost of increasing the energy in the upper harmonics. But this article is just one in a series of six on power-amplifier design, and if you actually READ them and not just glance at the pretty graphs, it's obvious that this is NOT Baxandall's conclusion from this experiment.
Rather, Peter Baxandall unambiguously states his conclusion from this experiment is that global NFB needs to be INCREASED to reduce all the harmonics to a negligible level, rather than avoided so that the second harmonic can completely dominate the distortion signature. He also specifically emphasizes that "even FETs used without feedback generate high-order harmonics - and therefore . . . high-order intermodulation products".
It's rather unfortunate that in discussions of negative feedback on the internet, the seminal papers from which most of these ideas stem remain largely ignored. This is of course because they're copyrighted, and one simply cannot pop up a link to them. But if anybody's truly interested, the Otala papers (and responses to them) can be obtained from the Audio Engineering Society http://www.aes.org, and the Baxandall series has been re-printed by Jan Didden at http://www.linearaudio.net
it would appear that electrical matching concerns between an amp and speakers having fluctuating impedance stats as a function of frequency may be mitigated in whole or part by using NF.Here's what I think is the most precise response this question:
- Due to a varying impedance-vs-frequency characteristic, the response of a loudspeaker will be affected by the output impedance of the amplifier, thus . . .
- If the amplifier's output impedance differs significantly from that which the speaker designer used for evaluation, then the response of the speaker will be different from what the designer intended, and . . .
- Although there are no specific standards, *most* loudspeakers are designed with low-output-impedance amplifiers in mind, and . . .
- The use of global or local Negative Feedback is the (almost universally applied) method of acheiving a low output impedance in an amplifier.