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I think if there is room for reductionism in pickup design, it would go like this: The pickup can be thought of as two "filters", with the output of one fed into the input of the second, and the output of the second driving your amp.
A spatial filter made out of the geometry of the strings, magnets, and other ferromagnetic parts of the pickup. (This is Rick's "3-D density", a highly complex non-linear filter that can select some overtones, cancel others, and even create new ones that weren't in the string vibration.)
An electrical filter made of coil inductances, resistances, eddy current losses, and self-capacitances.
Now, something like using different kinds of wire is easy. Assuming that the geometry of the coil stays the same, then the spatial filter should be unchanged and only the electrical one should be affected, in a way that you can easily predict from the physics of resonant circuits.
But the problem is that many of the physical changes you can make in pickup design affect both filters. For instance, changing the magnet in a humbucker. Unlike a single-coil, the magnet is down at the bottom, far from the strings, so it shouldn't affect the shape of the field at the pole pieces.
But does it? It's not really that far. What if the magnet's own field gets up there directly, as well as travelling through the pole pieces? What if a stronger magnet saturates the pole pieces a little more and changes their permeability, changing the shape of the fringing fields up at the string ends? So maybe messing with the magnet changes the spatial filter, even if the new magnet is the same shape and size as the old one.
It also changes the electrical filter in the naive way that the magnet strength multiplies the gain. But the magnet will have complex permeability, leading to both a change in inductance and frequency-dependent eddy current losses. The pole pieces will also have complex permeability. I discussed changes in the real part above, but maybe the imaginary part changes with field strength too.
Finally, with our talk of resonant peak and Q, maybe we have the assumption that the electrical filter is a simple second-order lowpass. It could be more than that. There is no single capacitance, it's distributed amongst the coil. And humbuckers have two coils each with its own self-capacitance, not to mention both electric and magnetic coupling between them, the latter depending on the permeability of the magnet. They could have a fourth-order electrical filter, several resonances, ripples, notches, you name it.
I've heard it said that any "science" with more than seven variables is actually an art. I think I hinted at about 25 there.
Also, ears are great, but they're easily fooled. The research done into audio compression algorithms spells out exactly how to fool them. My own form of reductionism is that I refuse to spend time thinking about any mechanism in music electronics, unless I can prove to myself that it would make 3dB or more of a difference to the audio. I think any of the mechanisms I mentioned above would be good for a couple of dB at some frequency or other: I wouldn't have mentioned them otherwise. (I allow for the possibility that some of you might have "Golden ears" calibrated to 1.5dB.
)
Oh, and Rick, you need to stick a dodecahedron on top.
A spatial filter made out of the geometry of the strings, magnets, and other ferromagnetic parts of the pickup. (This is Rick's "3-D density", a highly complex non-linear filter that can select some overtones, cancel others, and even create new ones that weren't in the string vibration.)
An electrical filter made of coil inductances, resistances, eddy current losses, and self-capacitances.
Now, something like using different kinds of wire is easy. Assuming that the geometry of the coil stays the same, then the spatial filter should be unchanged and only the electrical one should be affected, in a way that you can easily predict from the physics of resonant circuits.
But the problem is that many of the physical changes you can make in pickup design affect both filters. For instance, changing the magnet in a humbucker. Unlike a single-coil, the magnet is down at the bottom, far from the strings, so it shouldn't affect the shape of the field at the pole pieces.
But does it? It's not really that far. What if the magnet's own field gets up there directly, as well as travelling through the pole pieces? What if a stronger magnet saturates the pole pieces a little more and changes their permeability, changing the shape of the fringing fields up at the string ends? So maybe messing with the magnet changes the spatial filter, even if the new magnet is the same shape and size as the old one.
It also changes the electrical filter in the naive way that the magnet strength multiplies the gain. But the magnet will have complex permeability, leading to both a change in inductance and frequency-dependent eddy current losses. The pole pieces will also have complex permeability. I discussed changes in the real part above, but maybe the imaginary part changes with field strength too.
Finally, with our talk of resonant peak and Q, maybe we have the assumption that the electrical filter is a simple second-order lowpass. It could be more than that. There is no single capacitance, it's distributed amongst the coil. And humbuckers have two coils each with its own self-capacitance, not to mention both electric and magnetic coupling between them, the latter depending on the permeability of the magnet. They could have a fourth-order electrical filter, several resonances, ripples, notches, you name it.
I've heard it said that any "science" with more than seven variables is actually an art. I think I hinted at about 25 there.
Also, ears are great, but they're easily fooled. The research done into audio compression algorithms spells out exactly how to fool them. My own form of reductionism is that I refuse to spend time thinking about any mechanism in music electronics, unless I can prove to myself that it would make 3dB or more of a difference to the audio. I think any of the mechanisms I mentioned above would be good for a couple of dB at some frequency or other: I wouldn't have mentioned them otherwise. (I allow for the possibility that some of you might have "Golden ears" calibrated to 1.5dB.
)Oh, and Rick, you need to stick a dodecahedron on top.
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