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It is convenient to divide the process of understanding pickups into two parts:
1. the waveform that it produces,
2. the perceived sound of the waveform when it is processed in an appropriate manner.
The first is in principle entirely explainable by science, although in practice you would not expect it to be possible to describe the waveform sufficiently accurately through measurements to explain everything that can be heard. The second is only partially understandable through science, although many measured properties do have a perceived equivalent. For example, we know roughly what increasing the high frequency content of a signal sounds like.
The first part is explainable through science because electricity and magnetism is very well understand. The relevant laws were discovered in the nineteenth century, and since that time they have been integrated into physics in a way that any problem with the accuracy of the E&M laws (Maxwell's equations) would result in many inconsistencies. For example, Einstein discovered the laws of special relativity by looking for consistency with Maxwell's equations. Special relativity has been verified countless times, even through the operation of fairly normal devices. For example, the klystrons for our 430 MHz radar at Arecibo have a beam of electrons that is relativistic, meaning that the electrons move at a significant fraction of the speed of light, requiring Einstein rather Newton in order to describe the physics. These klystrons could not work as they do if there is a problem with the consistent laws of special relativity and E&M.
Part two is not well understood through science because the operation of the brain is not well understood. It might never be; even whether it can be understood is not known.
Scientism as it is used here is an attempt to use science to explain what it cannot or does not. For example, consider the idea that the law of magnetic induction and associated laws describing electrical circuits are sufficient to explain the waveform produced by any pickup. This is within the realm of science because these laws are fully understood. Therefore it is not scientism. On the other hand, it is scientism to say that every detail of the perceived sound of a pickup is understood through science. For example, it is reasonable to say that if you increase the high frequencies in a pickup, you expect it to sound brighter. It is not reasonable to say "This new pickup is brighter than the old one; therefore it has more high frequencies." You had better measure it. There could be other reasons why a pickup could be perceived as brighter.
The more subtle the properties of a perceived sound, the less likely it is that you can explain it entirely by science. But that is no reason not to use science where you can. It is certainly wrong to say that because you use science, you do not listen.
1. the waveform that it produces,
2. the perceived sound of the waveform when it is processed in an appropriate manner.
The first is in principle entirely explainable by science, although in practice you would not expect it to be possible to describe the waveform sufficiently accurately through measurements to explain everything that can be heard. The second is only partially understandable through science, although many measured properties do have a perceived equivalent. For example, we know roughly what increasing the high frequency content of a signal sounds like.
The first part is explainable through science because electricity and magnetism is very well understand. The relevant laws were discovered in the nineteenth century, and since that time they have been integrated into physics in a way that any problem with the accuracy of the E&M laws (Maxwell's equations) would result in many inconsistencies. For example, Einstein discovered the laws of special relativity by looking for consistency with Maxwell's equations. Special relativity has been verified countless times, even through the operation of fairly normal devices. For example, the klystrons for our 430 MHz radar at Arecibo have a beam of electrons that is relativistic, meaning that the electrons move at a significant fraction of the speed of light, requiring Einstein rather Newton in order to describe the physics. These klystrons could not work as they do if there is a problem with the consistent laws of special relativity and E&M.
Part two is not well understood through science because the operation of the brain is not well understood. It might never be; even whether it can be understood is not known.
Scientism as it is used here is an attempt to use science to explain what it cannot or does not. For example, consider the idea that the law of magnetic induction and associated laws describing electrical circuits are sufficient to explain the waveform produced by any pickup. This is within the realm of science because these laws are fully understood. Therefore it is not scientism. On the other hand, it is scientism to say that every detail of the perceived sound of a pickup is understood through science. For example, it is reasonable to say that if you increase the high frequencies in a pickup, you expect it to sound brighter. It is not reasonable to say "This new pickup is brighter than the old one; therefore it has more high frequencies." You had better measure it. There could be other reasons why a pickup could be perceived as brighter.
The more subtle the properties of a perceived sound, the less likely it is that you can explain it entirely by science. But that is no reason not to use science where you can. It is certainly wrong to say that because you use science, you do not listen.
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