Regardless of its popularity, Heisenberg's Uncertainty Principle, based on a randomly-operating universe, has been rendered obsolete by our new understanding of pseudorandom resonant fields. The universe is not run by unexplained magic, but by precision field-flow patterns that can be deciphered just like an encrypted message by mapping their pattern sequences, as we have been learning. And make money doing it.

   Heisenberg claimed that all attempts at understanding what happens deep inside things was futile because he imagined those activities to be random, while only an accumulation of field activities through statistical averaging could define the precision mathematics scientists and engineers use every day to predict how things work.

   The problem is that things simply do not work that way. Take electromagnetic radiation (light, microwaves, radio waves and such) for example. The electromagnetic field repeats itself every wavelength. An FM radio station at 100 Mhz has a wavelength about 3 meters long. Its activities can be precisely mapped, and shown to follow a sine curve that varies with the music being played.

   According to Heisenberg's Uncertainty Principle, the energy isn't spread over each whole wavelength, but shows up all at once like a big spike at random times within each wavelength. Only over many wavelengths, does one accumulate the statistical average of a sine curve.

   The problem is that Heisenberg provided no mechanism for storing or averaging his random spikes through even one wavelength, let alone several. So, there simply doesn't exist anything for generating the so-called statistics of quantum mechanics.

   Logically, to be truly random, all of his spikes must be truly independent, and detectable as individuals using high bandwidth equipment, which of course did not exist back in the 1920s when he came up with it.

   An FM radio compares the length of each successive wavelength with the next. Those changes are then converted into sound. That's why high quality music is transmitted using FM.

   If Uncertainty were true, the timing between spikes would vary randomly between zero and two wavelengths. This would be heard as a very loud hissing sound called "white noise," because the instantaneous wavelength (distance between successive spikes) would be continuously changing at random.

   Note: I am not confusing macro effects with micro effects. The quantum limit of a radio wave is its wavelength. So anything smaller would be invisible according to Heisenberg. However, whatever happens there affects the macro result, and is thus measurable.

   Each full wavelength requires energy. So no wavelength could begin before its spike-full of energy arrived. Therefore, in order to have a stable, quiet frequency, his spikes would have to show up precisely timed, exactly one wavelength apart. But then, they would no longer be random. Would they?

   If Uncertainty were true, that FM station would splatter detectable energy from 6 meters all the way up to light! Such random spikes would also produce a very loud hissing noise in the FM detector rendering the music quite unpleasant to listen to.

   However, such direct evidence does support the Resonant Field Theory we have been learning about. So, just as an encoded FM signal can interact with an FM radio to produce high fidelity music, the encoding in the hydrogen atom can interact with the coding in the oxygen atom to produce water. It always gets it right, and it never forgets how to do it.

   Thus, the prospect of atomic mapping opens the door for a considerable amount of research, and with it… research funding. Think about it whenever you hear a radio, because someone forgot to tell Armstrong about the Uncertainty Principle. And as a result, he went ahead and invented FM radio anyway.

   FM Radio 1, Heisenberg 0.

   Now that's exciting, isn't it!