There are essentially two types of input receptors. The first type is the variable input receptor.
The VIR, which accepts outside input, compares it to the negative side of the power source and expels free
electrons. It has an input and an output of the negative channel bridged in between by a filament sensitive to only
one type of stimulus. The second type of input receptor is depicted in figure 10. It is the established value
receptor. The EVR, (in other work refered to as the DIR or Dedicated Input Receptor) which accepts input stimulus
from a selected input source just like the VIR but compares the stimulus to an established value that represents
a ‘target' maximum for that stimulus.
Figure 10 shows an olfactory neuron in biological form. Figure 11 shows the EVR receptor with
a value established and held in a capacitor which is first compared to the input's value before sending the resulting
value on for processing. The result sent on is essentially a percentage of the maximum established value.
The VIR is used in vision as photons strike the filament adding particular sensitive stimuli to the
system. It is also used in pressure and temperature receptors, what we consider to be the sense of touch. The EVR
is used in the other input receptors. Hearing and smell and taste.
In the nose, ears and tongue receptors are ‘pre-programmed' so to speak (although there is no
programming in the digital instruction set sense of the word) to offer a maximum value. If an input stimuli is
placed to the receptor it will compare it to the established value and the result will be a variation of the maximum
value or the maximum value itself. The input stimuli activates the receptor where in the VIR the input stimuli
powers the receptor.
The nose contains the same essential variations of established values as the tongue. Acid, tart,
sweet and salty. In the nose, small hairs are receptors for the transmission of stimuli. In the tongue, taste buds act
as receptors for the stimuli. Both of which are compared to the maximum available standard for that given
assigned task and the result Is sent for computation without splitter circuit processing. This keeps the nose and
tongue free of additional and cumbersome neurons.
In the hearing process one input sensor (small hair) is tuned to ‘turn on' and accept intensity of
a particular frequency. It is able to pass on the maximum intensity of the permitted established value or any
variation less than maximum. Volume. The combinations of all variations in volume and all variations of intensity
encountered in frequencies in a complete sound result in the perception of timbre, harsh or soft, and overly intense
input results in pain and non stored values of sound.
In the quantum computational system the use of filaments made of thin piezo-electric material
suffices to replicate the small hairs.
To see a graphic depiction of the VIR receptor refer to figure 11 and consider the transistor and
the capacitor as not in the loop of signal. There is no positive side applied to the VIR where a positive side is
required to be applied to the EVR in order to propagate the transmission of free electrons.
