Linear Technology has a couple of examples in application notes showing how it can be done. In this case a pair of chopper stabilized operational amplifiers configured as integrators sample the positive and negative inputs and outputs before and after the JFET input buffer pair and adjust their independent offset voltages. The integration constants are chosen so that only frequencies below the 1/f noise corner are corrected. It is more complicated in this case because these amplifiers use complex cascode designs to support wide input voltage ranges and from what I remember, the 7A22 input stage starts as a differential amplifier and not a pair of buffers.
It may not be possible to avoid long overload recovery times. On a new design I think this could be handled by clamping the inputs at a lower level.
On the 7A22 I would also try to replace the input JFETs with a modern lower noise ones.
How high a 1/f corner and what chopping frequency?
This actually uses chopper stabilized amplifiers so the chopping is further removed. When I did it, I used the LTC1150 which chops at about 550 Hz and I already had a known low 1/f corner frequency of like 2 Hz for the LT1007 or 3.5 Hz for the LT1028. There are better alternatives now like the LTC2057 which chops at a much higher 100 kHz.
One problem with applying this to an old amplifier is incomplete specifications on the old transistors so it is difficult to tell how much improvement can be made without detailed measurements.
Do you have the app. note numbers handy?
I just end up looking them all up from memory when asked this. I should keep a list handy.
Page 10 of Application Note 21 shows what I started from in designing a differential input and output version. This example shows up in a lot of other LT documents like page 23 of the LTC2057 datasheet. I recently ran across fully differential input example in Design Note 36.
Page 3 of Application Note 45 shows an example of a chopper stabilized FET pair. Page 14 of Application Note 61 shows the same example. I thought I saw a more recent implementation using an LSK389 although Application Note 124 shows the same idea without using chopper stabilized amplifiers.
Just pondering some of the potential design hurdles and charge injection back into the input, due to the potentially high chopping frequencies required, immediately comes to mind. With chopper stabilization you can always kill demodulation noise trough the DC path by just low pass filtering with a low enough corner frequency, but once switching interference enters the AC path you're screwed.
I never observed this as a problem when I did it but I was correcting noise and drift in low noise bipolar designs. The overall noise was considerably improved over either amplifier alone. When I trimmed the integration constant for lowest noise, the resulting gain versus frequency for the parrallel stages closely agreed with the transition frequency which would yield lowest integrated noise. Measuring such low levels of integrated input noise was surprisingly easy.
1/f noise and DC drift has always been an issue in the design of sensitive analogue oscilloscope front-ends. Given how old the fundamentals of chopper stabilization are I'm sure if it was so easy these venerable old oscilloscopes of ours would have been designed this way, essentially free of DC drift and 1/f noise, from the year dot.
Offhand I can think of several reasons they may not have done it:
1. They lacked high performance monolithic integrated chopper stabilized amplifiers.
2. There were not *that* many high sensitivity analog oscilloscope front ends and in many (all?) cases, drift over temperature is significant in later stages as well which is why their calibration includes multiple balance adjustments. This is an issue even with low sensitivity front ends (I can see my old DSOs warm up over several minutes when first turned on and it goes without saying for my CA vertical plug-in.) although I have noticed before that maximum sensitivity seemed like it was often limited more by drift than noise (the CA vertical plug-in again). At low frequencies it is often difficult to tell the difference between drift and noise anyway. Drift is a significant problem with the 7A22 and 7A13 so they handled it by making all of their balance adjustment user accessible from their front panel.
3. Drift and noise were already low enough. This is arguable since as these specifications got better, they allowed for higher input sensitivity.
4. There is a potentially serious overload recovery problem. If the front end is driven into overload, the chopper integrator will windup causing a massive increase in recovery time. Luckily it should be a later stage which overloads.
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