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Resonator Quality and Superconduction in Cells
Many animals have perception capability which are astounding. The rattlesnake is able to detect a difference of 0.01 degrees in location of prey. The whale is able to detect a difference in field strength of 1 x 10E -8 Volts/cm. It is now known that the organism is able to read ultrafine signals from out of the noise level. It does this in the following manner:- 1. The endogenous resonators have a high quality with low attenuation. Attenuation is used to mean a reduction in amplitude(strength) of an oscillation or wave caused by energy loss. Energy loss normally takes place through the transition fron one form of energy into another form of energy. This means that the endogenous resonators with low attenuation do not weaken or attenuate a received signal or only do so insignificantly and pass on the information received without a loss of energy. In addition, the organism reacts to ultrafine signals in fractions of a second. The resonators in the organism are essentially the cell membranes and cytoplasm where all biochemical interactions take place. Inanimate gels and cellular cytoplasm are known to self-oscillate (Miyano and Osada, 1991). Resonators in the organism have a very short tune-in-time, which is less than a second, and has the associated formula as:
tune-in-time = 1/band width of the resonator in Hz. The greater the bandwidth of the resonator, the shorter the settling time, but the poorer or more attenuating the resonator of the organism: resonator quality = 1/damping constant This would mean that although the resonators in the body have a very short tune-in-time, they have a low resonator quality. The organism compensates for this by arranging several resonators at the same frequency in parallel. There are many cells with the same structure in the organism. This results in a short settling time and simultaneous increase in resonator quality. - 2. The body uses a multi-channel, partly superconductive system for passing on signals. It conducts signals via the nerve path (digital), the perinural Schwann and Glial cells (analog), the Acupuncture meridians (D.C. current boosters), protein chains, nucleic acid supermolecules, membrane fluid mosaic components(fatty acids, triglycerides and phospholipids) and most importantly the cytoskeleton. The nerve paths are normal conductors with untuned frequency lines. In the nerve strand, there are several fibers connected in parallel into bundles. Parallel connection of this kind allows for faster analysis and passing-on of multi-signals. The parallel-connected bundles of the nerves are not channels which receive and pass on fundamental waves and harmonics but those which mutually support each other in signal recognition. This is termed "pattern recognition".
- 3. In our bodies, the superconductive chains of molecules(proteins and lipids) as the extracellular matrix, cell membranes and cytoskeleton are interconnected to the acupuncture meridians. Since noise disappears completely in superconduction, this gives living systems a finely tuned and highly discriminatory capability.
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