Wednesday, March 12, 2014

Tomorrow's problem set

I will redo these in the new Unified Field Theory. I have to simplify the curl operation, then rewrite in sampled data, including quantization levels. We will get the rate of change of B with respect to Pauli, and the rate of change to E with respect to Pauli. Let's see, the cross thing points to the direction of change, the line of 'sight' if you will. Both those fields should be rotating a bit, we might just correct this. We will compute the result at the wave from, then show it is valid along the moving wave when limited to Pauli rate. And, of course, the result will refers to fields of any order. 
Step one, we will make the electro field have phase offset zero, and show  how a phase offset in the magnetic causes wave motion. Then we will add quantization to the magnetic and show it causes a bit of wobble, we can name that the quantization wobble.  Then we show that the real effect is phase difference, relate that to frequency. Then we can add a third field, and make it curve a bit, like Einstein said. The we can look at the rate of curvature that causes mass quantization, and discover a bit more about that. Then, finally, by looking at wobble in gravity we can guess about whether tour system has gravitrons, and maybe how dense.

If the N,N+2 quantization does not match, then maybe the Pauli rate is too fast, and the universe is not one whole.  It would mean that Pauli is too slow to keep just behind Nyquist, and Nyquist would phase stabilize disconnected portions of the universe, and disconnect them.That would be interesting!

One catch. Magnetism is not everywhere quantized to magnetrons in most regions. Its wavelengths will be longer, the two orders, electron and magnetron, together are not complete.  We will study both the compacted case and the sparse case. In regions where the electron and magnetic fields are fairly dens, an EM wave in a strong gravity field would shower electrons and regenerate long wave radio emission.  That might explain the weird radio waves coming from a nearby magnetron star. Speaking of which, the astromoners are puzzled:
Yet it does seem to be moving – and fast: its apparent sideways velocity is four times the speed of light. Such apparent "superluminal" motion has been seen before in high-speed jets of material squirted out by some black holes. The stuff in these jets is moving towards us at a slight angle and travelling at a fair fraction of the speed of light, and the effects of relativity produce a kind of optical illusion that makes the motion appear superluminal.
The answer, of course, is the thing has sparse magnetrons, against a dense electron layer. So the field is reversed from what they normally expect.  That stable field is curving the light and fooling the astronomers.  But this is the case I am talking about.  The star is mostly likely requantizing electrons from the EM wave entering a local dens gravity field, which would be near light speed, and re emit long wave radio with the angle changing from day to day.  This will take more than a day to sort out.

But that's tomorrow.

If I am up to it, we can also  look more closely at planetary motion. 

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