4fun said:
Sure, but it is on the other hand often good to keep tha basic building blocks to a minimum and define the others as subcircuits made of from such basic building blocks. That's why we usually don't have both an ideal voltage source and a voltage source with an inner resistance, since we can "build" the latter from an ideal voltage source and a resistor.
Mike, since you think more or less everybody are wrong, including Walt Jung, it would be interesting to read an article signed by you in the subject.
I'm pretty satisfied with the theories Walt Jung and others have presented. I'm also satisfied with the results I have achieved so my point of view is that I think CFB is very suitable for audio.
I'm pretty satisfied with the theories Walt Jung and others have presented. I'm also satisfied with the results I have achieved so my point of view is that I think CFB is very suitable for audio.
It seems to me that there is no definitive answer to the original question. VFB and CFB or any combination (which EVERY implementation is in a real circuit) are ALL suitable for audio.
You choose the node impedance of your subtractor to optimise the sound quality based on the specific choice of parts and what you believe to be the drivers of sound quality. As this is a system problem there are endless combinations of parts to consider. To prove that a particular combination is always best is impossible.
So the better debate might be about what the tradeoffs are between different subtractor designs with specific parts, and to argue the problems or benefits of different summing node impedances using these parts.
You choose the node impedance of your subtractor to optimise the sound quality based on the specific choice of parts and what you believe to be the drivers of sound quality. As this is a system problem there are endless combinations of parts to consider. To prove that a particular combination is always best is impossible.
So the better debate might be about what the tradeoffs are between different subtractor designs with specific parts, and to argue the problems or benefits of different summing node impedances using these parts.
Re: Re: Current feedback settling time and thermal tails
I've noticed that some CFB amplifiers (AD811, AD846) have strange 2nd, and 3rd harmonic plots compared to VFA's (AD826, etc). I'm not sure though if this is just relates to the configurations measured in the datasheets.
If the relative 2nd and 3rd harmonic distortion changes with freqeuncy won't this change the sound of the amplifier ?
Does CFB have a "tube sound" ?
mikeks said:
I've noticed that some CFB amplifiers (AD811, AD846) have strange 2nd, and 3rd harmonic plots compared to VFA's (AD826, etc). I'm not sure though if this is just relates to the configurations measured in the datasheets.
If the relative 2nd and 3rd harmonic distortion changes with freqeuncy won't this change the sound of the amplifier ?
Does CFB have a "tube sound" ?
Re: Re: Re: Current feedback settling time and thermal tails
Distortion is usually extremely low, like < 0.001% and this will hardly create any tube sound.ash_dac said:
http://www.jmd.szm.sk/Audio/Measurement/CF_amp/THD_1kHz_log_scale.gif
http://www.diyaudio.com/forums/showthread.php?postid=784679#post784679
http://www.diyaudio.com/forums/showthread.php?s=&threadid=62809&highlight=
http://home.swipnet.se/~w-50719/hifi/qrv08
Check the distortion figures in the first link. The input stage is a diamond buffer.
http://www.diyaudio.com/forums/showthread.php?postid=784679#post784679
http://www.diyaudio.com/forums/showthread.php?s=&threadid=62809&highlight=
http://home.swipnet.se/~w-50719/hifi/qrv08
Check the distortion figures in the first link. The input stage is a diamond buffer.
Pers, I was unclear. I meant to ask about open loop distortion. Your diamond buffer appears to have a gain of 4 with NFB. Do you have the OL result?
What output voltage swing and load does your sim assume?
What output voltage swing and load does your sim assume?
Open loop distortion is rather uninteresting I think.
The measurement figures were not simulations, the real stuff, measured by a real good sound card.
The loads I have used can be found here:
http://www.sjostromaudio.com/hifi_files/qrv/qrv08_testreport/qrv08_testreport.html
The test setup isn't optimal because I'll get a hum pick up. The amp is abolutely silent and hum free when I use the headphones.
The result is that the amp is better than the sound card I have used.
The measurement figures were not simulations, the real stuff, measured by a real good sound card.
The loads I have used can be found here:
http://www.sjostromaudio.com/hifi_files/qrv/qrv08_testreport/qrv08_testreport.html
The test setup isn't optimal because I'll get a hum pick up. The amp is abolutely silent and hum free when I use the headphones.
The result is that the amp is better than the sound card I have used.
pinkmouse said:
PM...i protest...on the pedestrian grounds that this is a purely subjective view....😀
peranders said:
Not true...i don't think Cherry is wrong:
http://www.diyaudio.com/forums/showthread.php?postid=948831#post948831
I find it very interesting.
I noticed on your load tests with 100-ohm load that the THD+noise and IMD spectra appear to show distortion in the low to mid -80dBs and low frequency noise at -75dB (the hum you mentioned?). Distortion appears to be around -85dB rather than -100dB. I may be misunderstanding the graphs.
I can't resist.mikeks said:
Attached, Mr. Knowitall, you'll see a simplified schematic of an input stage of a so called CFB opamp .
You won't tell me that there is no unity gain buffer between the + and - input, do you?
I think Mr. Jung does know quite enough about opamp's even if he was not the designer of these AD products.
Enjoy, Tino
Attachments
Seriously...
...folks, get a-hold of this paper in a hurry, or send me mail:
Edward M Cherry, ‘Feedback amplifier configurations’, IEE Proceedings on Circuits, Devices and Systems, Vol 147, No 6, Dec 2000.
...folks, get a-hold of this paper in a hurry, or send me mail:
Edward M Cherry, ‘Feedback amplifier configurations’, IEE Proceedings on Circuits, Devices and Systems, Vol 147, No 6, Dec 2000.
zinsula said:
Now, i can't resist, it does exactly what an opamp is supposed to do, amplify the difference between + and - input. Your circuit will have identical collector currents for q2/q3 if both inputs have the same voltage... no unity gain, zero gain 🙄
Mike
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