So I tore into my RN3 and added one minor mod to the lid, took some measurements and observed the LPS under a few different loads.
I wanted to make that top cover grounding wire a quick disconnect (spade lug) connection, for easier access to the box.
I figured it would make opening the box up, just a touch less fiddly…
pic of RN3 grnd wire mod
Then I hooked up my scope and took some readings.
I took the 1st readings with the RN3 running normally on the new LPS.
Then I disconnected the LPS and then measured it again , then I added a small load (a 7.5KΩ resistor) and measured again.
But next, I’ll list the previous readings to re-establish a base line to compare all of these readings to.
And the direct comparison between the SMPS and the LPS readings, the 2 different sets of them, while operating the RN3, as in under normal load, will be where the rubber meets the road.
At least in this one example, anyway.
So here are the previous measurements of the RN3 being powered by the SMPS and the initial triple output LPS unit (the triple output unit).
And the noise as measured on the +5vdc is much lower than what I measured while running the SMPS.
Here are the measurements I made using the stock SMPS.
Stock SMPS
Pin # Voltage Average Normal Envelope
1 +5 11 mv 91 mv 106 mv
2 +5 83 mv 91 mv 106 mv
3 0 (grnd) 101 mv 91 mv 106 mv
Note these readings include 24µs spikes (≈42KHz).
And here are the readings using this LPS with a rated noise of 2mv
LPSx3
Pin # Voltage Average Normal Envelope
1&2 +5 1 mv 6.5 mv 25 mv
3 0 (grnd) 3mv 16mv 27 mv (68mv with spikes)
Note these ground measurements were made using the active circuit grounds (not just the chassis grounds as were used in the measurements made with the SMPS).
Which means these measurements were made with the noise generating circuits included so these numbers are worst case instead of just the chassis ground voltages.
It should be noted that the envelope does include the 15.9µs (≈63KHz spikes) where as the average and normal readings don’t.
These spikes are generated by the active digital circuit itself and not by the power supply.
So now I’m gunna list these latest measurements semi a$$backwards from the sequence I took them in, that way I’ll have the conclusion at the end with a build up to get there.
So when I ran the LPS under no load conditions, which is the worst case to measure any PSU*, and then a very, very small load (the 7.5KΩ resistor), these reading could be considered as a base line (in situ) with the digital load only connected to the LPS by the ground connection.
Then I’ll list the Normal Operating measurements.
*Note SMPS’s often won’t even function under No Load conditions.
The periods I could capture and measure were
0.12µs = 8.3MHz
1.0µs = 1MHz
1.35µs = 740KHz
And these frequencies were present under all of these measurement conditions.
NO LOAD Internal LPS
+5Vdc supply Voltage with added noise as measured.
Average Normal Envelope
1.0mv 3.0 to 6.3mv without/with spikes 5 to 14mv without/with spikes
SMALL LOAD Internal LPS
LPS measurements made with a 7.5KΩ resistor
+5Vdc supply Voltage with added noise as measured.
Average Normal Envelope
2.6 to 4.3mv without/with spikes 2.6 to 4.3mv without/with spikes 6 to 11mv without/with spikes
NORMAL (Digital) LOAD Internal LPS
LPS measurements made under normal operating conditions.
+5Vdc supply Voltage with added noise as measured.
Average Normal Envelope
1.9 to 3.9mv without/with spikes 14.5mv 14.8 to 19.5mv without/with spikes
And now for the moment you’ve all been waiting for…
A comparison of the noise between the SMPS and 2 different LPS units
The results please.
Average Normal Envelope
SMPS 83mv 91 mv 106 mv
LPS x3 1 mv 6.5 mv 25 mv
LPS int 1.9 to 3.9mv 14.5mv 14.8 to 19.5mv
What this tells me is any LPS should significantly reduce the noise on the +5Vdc rails vs. using an SMPS.
This is not really a surprise since this is well known.
But that the reduction of the magnitude of the noise should make such a noticeable change and improvement in SQ, especially while powering a fully and strictly digital device is an eyebrow raiser to me for sure.
And from a different perspective this is yet further confirmation of the benefits for a multi stage highly regulated power supply, especially for DAC’s and other gear that connects directly to analog gear.
Which has been a trend in current DAC designs now for a while.
Next up are the power utilization and ground noise measurements and comparison from this internal LPS vs the SMPS measurements.
JJ
ps oh and I measured the Telema transformer height .
The transformer alone is ≈ 38mm
The transformer with its mounting board is ≈ 42mm
The transformer with its mounting board on the standoffs is ≈ 48mm
