Resonance processors also have a great operating stability. Our brain works in space and under earth gravity and is to a certain extend immune to electromagnetic fields. This is because the transmitter resonators always change together with the receiver resonators and therefore resonance is still achieved.
Resonator chains provide instant recognition of exact images as well as recognition of sequential signals like speech without sampling or time comparisons. If a spoken word is channeled through a resonator chain it will be recognized regardless how loud it is spoken, how fast it is spoken (even if speed changes in the middle of the word) and even if it is distorted to a certain extend.
With resonator chains we can compare millions images in a very short time. We only need to produce a number of oscillations before resonance sets in. The recognition signal can pass through a resonator chain using an electrical process like ion channeling or using a photoelectric process.
The most valuable advantage of resonance processing is that not only the sensor input is available to all parallel processing centers, but that each intermediate result of each parallel processes is also available to all processes. This leads to a controlled avalanche effect that swamps the brain with useful recognition results. The chapter 'Neuron Networks' explains how such a system can find the best match.
In computers we mostly aim for a perfect match. In nature however it is more important to get a similar match. There is fundamental difference between natures way and our way of building sensors. To increase the accuracy of the sensors nature just needs to increase the number of different resonators. This means that accuracy is automatically increased when nature produces resonators as randomly as possible. If some of the resonators are identical it does not matter. To increase accuracy of our instruments they get more complex, are harder to reproduce and get less reliable.
Nature might use resonance chains to control forms and more important use resonance for immune system identification. A resonator chain (fingerprint) of the enemy species is attached to a killer cell which forces the the chain to oscillate. Cells in resonance will draw more energy from the transmitter than others and can be killed. It is not necessary to know what the resonator chain actually does. There will be no side effects like with pharmaceuticals which cripple 'good' and 'bad' bacteria populations to restrict one enemy.
New : Last year read an articel in New Scientist that the US military considers to use electronic warning detectors to detect biologicla weapons. It has been found that bacteria have characteristic spectra that can be picked up by mobile phone receivers.
