Well, do you have a practical example of such SMPS whose noise is not detectable with a receiver that has an MDS sensitivity of -145 dBm @ 500 Hz? (about 0.012 µVrms @ 500 Hz)
Well sure, we already have one in the thread: for
https://www.eevblog.com/forum/projects/shielding-boost-converter-for-rf-transceiver/?action=dlattach;attach=2365825;image above 500kHz, harmonics are dropping about as -80dB/dec(!), so probably by about 3MHz, it's below there. We can't
confirm that from the data given, but it seems likely to be true. (The peaks at 50 and 100MHz may be aberrations of acquisition, or interference in the setup -- commercial stations, perhaps, but they might also be faint oscillation, for which ferrite beads might suffice. We'd need a metal box, LISN, coaxial connections, and probably LNA, to have a better idea. The scope might also not have good dynamic range in those frequencies.)
If a transceiver is insensitive to these lower frequencies but not the higher ones, then that's that, there you have it.
If you contend that
there exists a receiver that's sensitive to any frequencies... well yeah I gotta say there are some pretty shit designs out there, that doesn't mean they should be used.
But even if so, these lower frequencies are easy to filter; it's hard to make a simple (as calculated) lowpass filter with more than, say, 2 or 3 decades of asymptotic performance, but evidently this supply only needs two decades worth of filtering; we might put in a two or three staged filter anyway (i.e., cutoffs of say 1kHz, 1MHz, 100MHz), just to be sure it's clean beyond that.
A capacitor multiplier might also be used, with or instead of an LDO. -100dB at 20kHz isn't a compact filter but it's also not wild, and a staged approach can achieve that easily.
Things are more difficult if such a clean isolation barrier is required, but that too can be mitigated mostly by stuffing either side of the isolation barrier inside a metal box to block its common mode voltage; the CM path might still emit, but what's inside the box(es) doesn't see it.
So too, if the transceiver is sensitive to ambient fields, not just conducted (supply) noise. Stuff them both in boxes and no one's the wiser.
To be clear, I do not exclude the possibility that such SMPS with so low noise can be created with modern cutting-edge technology, but I do not believe that they exist and are practically used.
And if you try to implement a DC/DC converter with noise below at least -120 dBm, I'm sure you'll end up using a linear regulator instead of an SMPS. Even if you add a good enough filter, you will still need to deal with leakage issues, such as magnetic coupling with inductor. That's the reality.
Curious, why "cutting edge"?
Is a 50/60Hz thyristor supply not "SMPS"? Is an iron-cored inverter (audio frequency, or maybe just above to avoid whine, as the above example) not an "SMPS"?
Is a low-harmonic class-C oscillator/amplifier, plus resonant tank and rectifier, not an "SMPS"? (It might not be as efficient as a switcher proper, but it's definitely more efficient than an equivalent transformerless linear supply for a high enough dropping ratio -- 70% efficiency should be feasible.)
Is a magnetron + rectenna not an "SMPS"?...okay, that's kind of out there, one would almost certainly not have to go to such lengths. But it leaves open a further possibility: why not crank "Fsw" up even further, use LEDs + solar panels? Total efficiency isn't going to be great (20% if you're lucky?), but that's still better than a linear supply of high enough dropping ratio.
Is an SMPS with linear postreg not an "SMPS"?
In short, we can put the tones and spurs wherever we want, and there exists a filtering strategy to deal with any of them -- given enough space or budget. The mains pulses of the thyristor rectifier, or say a saturable reactor-controlled rectifier, can be filtered with enough iron and copper, even if we don't allow a minor voltage drop for a linear postreg; the carrier and harmonics of a traditional hard-switched buck, or switching transients of the thyristor, can be filtered with iron or ferrite; and the upper harmonics of fast switchers or VHF+ oscillators can be filtered with ferrite or air-core inductors, or transmission line structures, absorbed in resistive materials, and blocked with shielding.
If what you were saying were completely true, that absolutely positively nothing can hide -- SIGINT would love to hear about it; however, there are such things as signals-approved equipment (various internal signals, adequate filtering and shielding to prevent their leakage), and even filters (mains filtering from some kHz up). Granted, those filters will have some standard minimum attenuation, not necessarily 150dB or more at any frequency, but as part of a system, easily more than 150dB from privileged sources to potential exterior points can be achieved.
Tim
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