Usually the output capacitance and output transistor limits bandwidth at low loads so a faster error amplifier does not add much except for the need for more frequency compensation.
CMRR will not mean much without precision dividers. Offset will not matter unless you need absolute accuracy which again, requires precision dividers. Neither affect load or line regulation.
I am using 0.1% resistors for the differential amplifier. I wanted decent precision as I will be using 22-bit A/Ds and 5-digit displays for the current and voltage meters. I am hoping for <0.1% accuracy for the meters after calibration. If the drift is low I could compensate for offset and CMRR in software, but it would be nicer if I didn't have to do much calibration.
Worst case 0.1% resistor matching with a gain of 0.1 yields a CMRR of 49 dB so the operational amplifier CMRR will not be a limitation. Worst case 0.01% resistors would still only be 69 dB.
http://www.linear.com/docs/41248CMRR requirements are relaxed since the change in common mode voltage itself is low.
I have designed and built similar fixed power supplies with remote sense that had load and line regulation measured in microvolts or less. My favorite configuration is something like this:
http://circuitdiagram-schematic.com/high-stability-regulator-circuit-using-lm108/The AD8674 and OPA4227 are low noise but to take advantage of it, the impedances need to be below 10k. These amplifiers have input bias current compensation so there is no need to balance the inverting and non-inverting inputs and resistors like R16 and R25 do nothing useful. The FET input operational amplifiers do not need input balancing because they have such low input bias currents.
Operational amplifiers with high slew rates will recover faster when switching between voltage and current mode since there is no clamping of OP1.1 and OP1.3 depending on the external compensation. That gives an edge to the JFET operational amplifiers. Add some clamping and this would not be a consideration.
Thanks, I'll consider removing the input balancing resistors.
I am curious to know why impedance < 10k is needed? Is that because of the the current noise density?
Yes. It is only approximate but dividing the voltage noise by the current noise yields the source resistance necessary to double the voltage noise which is a reasonable place to start. Resistors noise is usually insignificant.
http://www.linear.com/docs/4345I have tried to figure out a way to clamp them but have not been able to find a good solution.
So I think AD8513 might be the best choice then.
I do not have any good examples to link. Diode or zener clamps across the feedback capacitor are common but there are other ways using transistors or maybe current switched diodes. The idea is to prevent the operational amplifier from charging the integration capacitor excessively when operating open loop and the other error amplifier has control.
Some operational amplifiers have special clamp pins or you can do it via an external compensation pin.
Minimizing the integration capacitance shortens the recovery time but clamping is still necessary for the fastest response.
What are Z1 and Z2 for? Are they just to protect the LEDs?
It is more like protecting the supply from future user stupidity (from me probably) 
. The LEDs will be indicators in the front panel, and usually I would not expect an indicator to be part of any important circuitry. So I was thinking that the supply should work without the LEDs and not lose regulation.
LEDs tend to fail short but I agree with the concept. Tektronix just put an LED (and diode) in series with the output of the current loop amplifier to indicate current limiting.
I was thinking it might be better to use a slightly higher voltage zener and a resistor in series with the LED. Then the bias current from the current source can be raised without affecting the LED.
I am not fond of low voltage zener diodes though and by themselves, zener diodes have an appalling tenancy to fail open. A slightly more complicated design would use a resistor divider to fix the base voltage of a bipolar transistor so the transistor replaces the zener. Oddly enough the transistor Vbe would compensate for the LED forward voltage drop for better LED current regulation.
I would look into operating at a higher drive current, lowering the impedance of the feedback networks for T7 and T8, and buffering the outputs of OP1.1 and OP1.3 with emitter followers. This would include replacing the BC series transistors with BC327s and BC337s or something better.
Some of the transistors might see a voltage of almost 50 volts, so I decided against BC327/337 for that reason and I wasn't able to find any higher voltage equivalents.
How much current do you think might be needed?
I could maybe increase it to 20mA or so. BC546/556 seems to be able to handle about 1W with a heat sink attached.
I was thinking 20 milliamps but as you point out, the voltage is marginal on the BC327/BC337 and I think 1 watt is optimistic for any TO-92 transistor although I have heat sinked them in the past.
I wish there was a modern equivalent to the old 1+ watt TO-39 transistors.
Yep, I noticed how hard it was to find good fast transistors in the "a few watts" power range. And those TO-39 parts are easy to keep cool.
There are lots of surface mount options but I have been slowly compiling a list of suitable TO-126 transistors:
2SA1507/2SC3902 160V 1.5A 1.5W 120MHz
2SB1143/2SD1683 50V 4A 1.5W 150MHz
BD139/BD140 100V 1.5A 1.25W 190MHz(?)
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