- Joined
- Jul 8, 2010
- Messages
- 473
My point was that the timing capacitor node is not an internal emitter follower output providing a stiff voltage source.
It is better analyzed as a current source through a diode which just happens to have an emitter as cathode.
The current domain is the thing.
When two channel's detectors are coupled at the Ct pin the currents sum into a single capacitor.
It appears to be a diode OR - and structurally is in the voltage domain - but what is happening is current summation through diodes.
JR is correct in that the output of the "RMS" detector is really not true RMS. I think this is where we began to disagree some time ago.
The final square root and antilog mathematical operations to make it be RMS-responding occur in the VCA control scale and law when the RMS detector is paired with a VCA.
The square root is due to the scale factor of the VCA being twice that of the "RMS" detector. (√ is /2 in log domain)
The antilog operation occurs due to the VCA's exponential control law.
If one wanted a linear DC representation of true RMS for measurement the way to get it would be to use a feed-forward topology and (1) put a reference DC voltage into the VCA's input pin, (2) control its' Ec with a "RMS" detector and (3) read the final VCA-IV converter output.
As to the merits of true RMS versus averaging I recently measured some UPS outputs. On the APC the averaging responding meter read about 93V but the true RMS read 120V. The Belkin read about 85V avg and 110V true RMS. Not sure how this relates to music other than both are complex waveforms.
