What evidence supports the claim that humans have a built-in communication receiver?  What about a transmitter too?  Most modern civilizations hooked on the internet know of, or have heard of a MODEM which stands for modulator-demodulator.  Modulation is a term used by communication specialists to send and receive information using the carrying waves in the electromagnetic spectrum (EMS) as the messengers.  If our modern society is able to use the EMS to send and receive data, certainly the Anunnaki were able to do so as well, but probably more directly.

Consider the possibility that the Anunnaki used the human structure or re-designed it such that it could be used as a biological communications device, susceptible to their commands as slave masters.  First a brief primer on the evolution of the human brain is presented.

Our brains comprise three distinct structures, representing three evolutionary periods. The oldest, deepest, and smallest area is the reptilian brain [90]. The reptilian brain controls the heart, lungs, and other vital organs. It enables aggression, mating, and reaction to immediate danger.

Mammals evolved the limbic system. This is the middle layer of our brains, surrounding the reptilian brain. The physiological features unique to mammals are in the limbic brain, e.g., the hypothalamus system for keeping us warm.

The limbic brain also produces emotions. Emotions facilitate relationships. Mammals, unlike reptiles, care for their young. Mammals evolved brains hardwired for mother-child and other relationships.

The most common reaction a reptile has to its young is indifference; it lays its eggs and walks (or slithers) away. Mammals form close-knit, mutually nurturing social groups-families-in which members spend time touching and caring for one another. Parents nourish and safeguard their young, and each other, from the hostile world outside their group. A mammal will risk and sometimes lose its life to protect a child or mate from attack. A garter snake or salamander watches the death of its kin with an unblinking eye [92].

The cerebral cortex (or neocortex) is the newest, outermost area of our brains. The oldest mammals, e.g., opossums, have only a thin layer of cerebral cortex. Rabbits have a little more, cats a bit more. Monkeys have a substantial cerebral cortex. Humans—and only humans—have an enormous cerebral cortex.

The human reptilian brain and limbic system is similar in size and structure to other animals. Our ancestors evolved a huge cerebral cortex, while the older brain areas didn't change.

The cerebral cortex learns new things. Animals with little or no cerebral cortex act only as their genes program them to act. Animals with a cerebral cortex can find new foods, survive in new environments, or change their mating tactics to improve reproductive success.

The human cerebral cortex goes beyond learning new foods and survival skills. Our brains can think in abstractions. We communicate via symbols (e.g., language), consider the past and future, and sacrifice our personal interests not only for our families (as other mammals do) but also for ideas (e.g., honor and country).

Conflicts between brain areas lead to relationship difficulties. In a conflicted brain, the older area wins. In contrast, an individual with an integrated brain—e.g., who uses his or her whole brain—solves relationship problems.

Reticular Activating System

It is known that the primitive organ within the human brain that is responsible for attention is the Reticular Activating System [90].  It is a part of the primitive survival brain that, along with complementary nerve ganglia and networks within the human body.  The operation of the primitive brain is the source of intuition or gut-feelings, which provide the necessary control a primitive human being would need to survive in its environment sans the more evolved brain that involves reflective consciousness in the modern human being.

It is believed by contemporary scientists that the further evolution of the brain (over time or augmented by the Anunnaki?) added more complexity upon the existing primitive brain system that is still functional and operating simultaneously.  A question then arises, could the primitive brain, if properly stimulated, override the functions of the more evolved reflective consciousness brain?  Possible answers to this query involve the various factors that affect mental processes that result in focusing one’s attention.  Consider that what we are focused on may be influenced by marketing or something as invasive as a specific frequency communicating directly with the primitive brain via the reticular activating system.

Note that the Reticular Activating System (RAS) still controls awareness in modern humans. The RAS is essentially a direct sense experience computer with a primitive survival program always running in the background.  The event-filtering consciousness-directing ability the RAS exhibits in humans may be demonstrated directly [90].  One simple example is to touch someone someplace on their body that they are not expecting or witness visually.  This unseen tactile sensation is processed by the recipient, who suddenly becomes aware of the body part where the touch sensation was triggered.  This can also be done by verbally bringing someone’s awareness to the sensation of the feel of their wristwatch.  The differentiation between being generally aware conceptually that the spot exists “in the back of our minds” and the reality of our awareness being physically brought to the sensory impact point, demonstrates the function of the RAS.  The recipient was not really aware of body part area where the touch encounter took place until it happened.  The RAS cannot simultaneously bring awareness to more than one event at a time though it may have the appearance of being done in parallel, much like a computer system.  Imagine being in a crowd and having twenty people perform this experiment at the same time.  The RAS could not process which touch sensation to respond to first.  Thus, the RAS has the responsibility of bringing awareness to important prioritized events in our environment, especially those events that impact survival.  Figure 4 depicts the Reticular Activating Control Loop showing the separate channels for Auditory impulses near the primitive brainstem below the hypothalamus.

Figure 4:  Reticular Activating System

Brain Frequency

When two waveforms are mixed the resultant wave may produce increases or decreases in amplitude depending on whether the two waveform crests were aligned such that the superposition (adding peaks) resulted in a higher amplitude.  If a peak and a wave crest are aligned in time, then the result will be a decreased amplitude output.  See Figure 5.

Figure 5:  Superposition in Waves

Harmonics and Binaural Beats.

When a sound wave is produced it can produce lower amplitude copies of the original signal spaced either side of the fundamental frequency.  This normally looks like spikes of decreasing size as the spectrum increases or decreases either side of the fundamental frequency.  Suppose you mix two frequencies together and the difference between the frequencies is 10 Hz.  Then every Nx10 Hz there will be a harmonic or echo of the difference between the frequencies., N=1,2,3..) So, expect to find energy at 10 Hz, 20 Hz, 30 Hz, etc.  Some very interesting sounds can be created taking advantage of this fact.  When two frequencies are presented to the human auditory system, something very interesting happens.  The human ear does not hear either frequency independently, but rather hears the difference.  If the frequency difference falls within the brain wave frequency common in humans,  a phenomenon occurs called entrainment.  There are factors that affect the degree to which the human brain can change frequency to that of the differential between frequencies f1 and f2.  For example, suppose that one instrument produces frequency f1 at 150Hz and the second source produces frequency f2 at 152 Hz.  Then in this case, the human auditory system, specifically the reticular activating system, will hear and possibly synchronize (entrain) to the 2 Hz binaural beat, F2-F1.    Using an electroencephalograph, human brain waves have been categorized as shown in Table 4 below.  The 2 Hz beat falls within the brain wave state termed Delta, characterized by Yogic states and deep sleep.