Yes. One common name for the multisine signal is "periodic noise".

I dug a bit deeper into the impedance spectroscopy literature, and the multisine approach is the clear winner in that world. The reason is that the multisine approach doesn't waste any test signal energy on frequencies that will not be measured. They spend significant effort on choosing phases to minimize the crest factor of the resulting periodic noise sequence, the purpose being to preserve the dynamic range.

But it should be understood that they use very weak test signals, about 10 millivolts, to avoid various interfering electrochemical effects, and yet they achieve 50 and 60 db SNR. Low frequencies are a problem for them too. Their solution is to make the low-frequency sines stronger than the high-frequency sines, to compensate for the highr loss at low frequencies. But we can also use very strong test signals, and simply overpower the problem.

Back when I was looking for nonlinearities in pickups, specifically in the magnetic materials, I was driving the test pickup hard enough that there were 70 volts rms across the coil. It would take quite the guitar player to approach that. I'm not sure I want to meet such a player.

For multisines, five or ten frequencies per decade suffices in the electrochemical world. There are various rules, but one rule is to choose from the odd harmonics of 10.07 Hertz (don't yet know why). The chosen test frequencies can be logarithmically spaced. It may be possible to also arrange things so the test sines land cleanly in single FFT bins, without straddling.

I don't see any mention of the impedance spectroscopy folk using barker codes, but they did do something similar, but using a far longer pseudorandom sequence. A sequence of 105 elements will have sidelobes 20 log(105)= 40.4 db down, while they are looking for 60 db. This may be the reason.

So we are measuring drive coil current versus pickup coil output voltage.

The SNR may already be very high except at low frequencies, where the induced voltage is very low. This would explain the small advantage from added integration - it's already good enough (except at low frequencies).

As discussed in the thread now on impedance spectroscopy, one can counter this by pre-emphasis on the low frequencies. And by brute force.