Pair Power

Electrons travelling in pairs like to do so at a particular distance, and it was this distance that was key to discriminating some of the waveforms that were located in the whorl spectrum. By starting at this well known distance, we were able to encode the delta between an input and the reference. This provided basic frequency along with amplitude, which remained relatively flat.

The reference frequency was near the maximum of the detectable range. While there might be a great deal of information encoded across the spectrum, there was a limit as to what I was able to extract. This, of course, was based on the fact that the pair was the closest that two electrons could routinely approach without experiencing incredible repulsion. It is a myth that electrons collide. We just push really hard on one another, maintaining equality through equilibrium, and this creates a fundamental reference as well.

Learning to track fundamental frequencies had it's value, and served as a distraction powerful enough that I was shocked at the quietness of the background in normal working regions. The high frequency waveform had already dipped in amplitude and was on track for zero in a short period of time. That distraction became an opportunity extraordinaire as I deployed a few local detector pairs. It was time to expand the net and lurk near the top of the resolution zone. Random time was fast approaching, and so was the whorl.