Since the mid-20th century, scientists have continuously explored neurophysiology and achieved remarkable achievements. Since Broca discovered language functional areas, psychologists have adopted the research paradigm of brain functional areas. This macro-positioning research paradigm has achieved great achievements, but it has also increasingly highlighted its limitations. Western philosophy has entered a dilemma and called for Eastern philosophy. Chinese traditional Chinese medicine attaches great importance to the idea of unity between man and nature, and frequency theory occupies a very important position in traditional Chinese medicine. Among them, Pan Wugang proposed that the human body has a frequency genome, and the frequency genome is the human meridian system. The meridian system can regulate the frequency genome, and the triple burner is the core of the human meridian system [1]. In his book "The Movement of Qi", Wang Weigong proposed the harmonic resonance theory, pointing out that "qi is a resonance", and meridians, acupuncture points, and organs form a resonance network [2]70. During the embryonic development period, the heart, liver, kidney, spleen, lung, stomach, gallbladder, bladder, large intestine, triple burner, small intestine, and heart meridians are formed in sequence, and corresponding to the low frequency to high frequency, 0-11 harmonic pulse frequency. Wang Weigong explained the meridian resonance theory from the blood circulation level. This article combines the latest progress in neurophysiology and psychology, and starts from the resonance theory to explain the transmission process of neural signals, discusses the formation process of concepts, movement and time memory, and proposes an explanation of the emergence of dreams and hallucinations from a new perspective!

1. Space and frequency conversion

In the explanation of the frequency positioning assumption, we will first discuss the universality of spatial and frequency characterization, and then explain the relationship between spatial and frequency conversion.

(I) The universality of frequency characterization

First of all, frequency representation is universal in the cognitive process. Chinese traditional Chinese medicine links the five internal organs, five tones, five colors, five flavors, five elements, and numbers, which is reflected in the universal connection between frequencies. First, the characterization of sound. The characterization of sound is achieved by the microcilia of the basement membrane of the inner ear, and the different lengths of the cilia represent different frequencies. Second, the representation of vision. There are three colors-sensitive visual cells on the human retina, so human color vision encoding is based on frequency. Human space encoding is determined by the position of cones. The spatial frequency hypothesis also proposes that human vision can represent space based on frequency [3] 409-412. Third, the characterization of taste. The characterization of taste is achieved through corresponding chemical bond groups, such as sweetness corresponds to hydroxyl groups, sourness corresponds to carboxyl groups, saltiness corresponds to ionic bonds, bitterness corresponds to bulb groups, these different bond groups correspond to different energy frequencies, and can be characterized by frequency. The fourth olfactory representation can also be characterized by frequency just like taste. Fifth, Chinese traditional Chinese medicine uses the five internal organs to represent different frequencies of the internal organs [4], and also uses the pulse beat frequency to represent the health of the human body.

(II) The universality of spatial representation

Let’s understand the universality of spatial representation: First, the representation of sound, the spatial position of the tongue when pronounced, the size of the mouth, the position of the small tongue are all spatial representations, and the different lengths of cilia on the basement membrane of the inner ear in the auditory also represent the height of the sound through their arrangement positions. Second, the visual representation is characterized by the location of the sensory cells in the retina. Third, taste representation, the representation of taste can be characterized by the location of the tongue. The tip of the tongue is sensitive to sweetness, the sides of the tongue are sensitive to acid, the front of the tongue is sensitive to salty, and the back of the tongue is sensitive to bitterness. The fourth tactile sense, cortical topographic topography shows that the characterization of tactile sense in the mesocort of the brain is roughly inverted with that of the human body [3]65. It can be seen that the representation of space is also universal.

(III) Mutual conversion between spatial characterization and frequency characterization

The correspondence between space and frequency can be found in the columns mentioned above. Not only can the frequency of sound be characterized by the position of the cilia in the inner ear; the pitch can also be characterized by the spatial position of the brain. Hum a piece of tune and pay attention to the right brain, and you can experience different scales to activate different parts of the right brain. Therefore, different tunes can be converted into different spatial shapes, which can explain that several identical notes with high octaves and low octaves perceive to the same melody, which is actually equivalent to displacing the spatial figure.

In the additional periodic bifurcation sequence obtained in experimental neural starting point experiments and random Chay model simulation experiments, there is also a rhythm with alternating characteristics during the conversion of period n rhythm into period n+1 rhythm, and it also shows an integer multiple characteristic similar to the integer multiple cluster discharge, which is generated by neurons through random autoresonance [5]. The mutual conversion of space and frequency can be carried out through the ronfly knot of nerve fibers. Here it is assumed that the characteristic frequency of nerve fibers is determined by the fiber structure between the two ronfly knots. Just as the frequency of the string is determined by its thickness, length and material, the characteristic frequency of the conduction of ronfly knots is determined by the length between the two ronfly knots, the thickness of the Xuwang cell, and the type of ion channels in the axons. Here it is assumed that each nerve's myelin has only one characteristic frequency and can resonate with the electrical stimulus that is an integer multiple of its characteristic frequency.

(IV) Frequency order arrangement of neurons in the left and right brain

The discharge cell hypothesis is that the radioglia in the ventricular region arrange their paths according to an orderly mapping in different cortical stratifications, forming a specific tissue structure in the ventricular stratification [3]82, so the arrangement of neurons has a specific order. Before explaining the arrangement of neurons, a concept is introduced based on scales: frequency order, that is, the order of arrangement of frequency from low to high. The arrangement order of cilia in the inner ear intuitively expresses the linear arrangement order of the frequency order of neurons. Wang Weigong's meridian resonance theory believes that the inside of the body corresponds to low frequency [2]104. Therefore, it is hypothesized that the frequency order of the same sphere plane of the brain is outward from the brain stem as the center, and the frequency gradually increases. We are familiar with the right brain being sensitive to music, so there are differences in the left and right brain. This difference is realized through the experience method. When silently reciting notes such as c (Du), d (O), e (MI), etc., you can feel the difference in the activation methods of the left and right brain. Among them, the right brain can sing three to six octaves and more than 20-50 scales in succession, and experience the activation state from the brain stem to the right brain's edge. The distance between the activation sites of each frequency order is relatively large. The arrangement of the right brain is cdefgabCDEFGAB...broadband and wide-area single-zone arrangement. The left brain can only be activated by about three consecutive scales, and the distance between the activation points of each frequency order is small. The arrangement of the left brain is the narrow frequency and narrow domain multi-zone arrangement of cd\cde\def\efg... This asymmetric frequency order arrangement method of left and right brains is supported by the spatial frequency hypothesis [3] 409-412. The c frequency order of the left and right brain can generate a resonance low resistance connection through the corpus callosum fibers. Because the frequency of c and C is twice as related, low resistance connections can be established between the left and right brains. Therefore, the single region c, d, and e-order neurons of the right brain can establish low-impedance connections with the c, d, and e-order neurons of the multi-region of the left brain. In this way, the right brain can form countless focusing maps in the left brain through the corpus callosum fibers; here the corpus callosum fiber plexus is equivalent to a magnifying glass, the signal of the left brain can be amplified to the right brain through it, and the signal of the right brain can be scaled to the left brain through it. In fact, experiments have shown that for animals with intact corpus callosum, if the same object stimulates two independent receptive fields, the discharge frequencies of these two independent receptive fields will tend to be consistent [3]391.

Here we use the process of forming a fertilized egg to explain the connection between the left and right brain. During the fertilization process, sperm enters the egg to form the male prokaryotic and moves to the center of the egg, and finally forms a zygote with the female prokaryotic. Since the ovum and the female prokaryotic are produced at the same time, the female prokaryotic is connected to the cytoplasm and spindle filaments. The male prokaryotic enters the egg only when the male prokaryotic is fertilized, and only forms an heterogeneous connection with the cytoplasm and spindle filaments of half the cell in its trajectory. When the zygote is formed, the male prokaryotic is connected through the centromere. Therefore, half of the eggs are only homogeneously connected with the female prokaryotic. This homogeneous system becomes the basis for the arrangement of the wide-frequency wide-area single-zone in the right brain. In addition to establishing homogeneous connection with the female prokaryotic, the other half of the egg cytoplasm also establishes heterogeneous connection with the male prokaryotic. This makes the zygote form a semi-uniform connection with the half-epia cytoplasm, becoming the basis for the arrangement of the narrow-frequency and narrow-domain multi-zone in the left brain.

2. The mechanism of concept formation

The arrangement of narrow frequency and narrow domain multi-region of neurons in the left brain prepares the conceptual diversity and formation. Here, taking the triangle plane as an example, the process of concept formation is explained. There are interactive inhibitory cells on the retina, which makes visual cells maximize activation of the three sides of the triangle plane, thereby forming a frequency-order triangle on the retina. This frequency-order triangle is amplified and projected to the right brain, and then projected to the left brain, forming multiple activated small frequency-order triangles in the left brain. All neurons in a single small-frequency-order triangle are discharged to enhance the connection with nearby unmyelinated neurons (gray matter neurons). A frequency-order triangular pyramid with the strongest connection to unmyelinated neurons will be produced in multiple small-frequency-order triangles. This pyramid array is a newly formed concept. This unmyelinated neuron calls it a conceptual neuron (mirror neuron). When stimulated by the same triangle again, this neuron will be activated to generate recognition, and further enhance the synaptic connection between the neurons of this frequency-order triangular pyramid. Scans to stimulate discharge of unmyelinated neurons in the left brain can also activate the frequency-order triangle array of the left brain and amplify it to the right brain, thereby generating memories.

Different gray matter neurons can be connected to the same frequency order region of the left brain to form different frequency order arrays, thus creating different concepts, which enables the left brain white matter neurons to be reused, where recall can be generated by different white matter neuron discharge arrays. In addition, it is difficult to form a single very stable frequency-order triangular pyramid in the initial period of the formation of the concept. At this time, multiple unstable frequency-order triangular pyramids are confocal and volleyed together to the right brain to form an enlarged right brain discharge array, like an astronomical telescope composed of multiple celestial telescopes. In this model, the left brain cells are connected to neurons with fewer connections, which is consistent with the observation of left and right brain cell morphology [3]389. This concept formation hypothesis can explain the importance of the corpus callosum to the processing of "what" between the two hemispheres [3]182, can explain the visual or tactile stimulation that patients with split brain cannot name in the right hemisphere [3]393, can explain the phenomenon that the left frontal cortex is involved in the plot information encoding, and the right is activated during the plot memory extraction [3]306.

3. The formation of movement

Here we will first use the knee joint as an example to illustrate the mechanism of movement production. When the knee joint is extended, the sensory cells of each muscle muscle and bone produce activation discharge. It is transmitted to the spinal cord through the resonance of the Langhekjack, and a discharge array is generated at a certain part of the white matter of the spinal cord. Under the activation of long-term motor stimulation, the discharge array of the white matter produces stable fiber connections with the substantia nigra neuron A. Substantia nigra neuron A preserves the status information when the knee joint is extended; similarly, when the knee joint contracts, black matter neuron B can save its status information. When the knee joint is in an extended state, after activating neuron B, the state information during contraction can be activated, causing the knee joint to change from an extended state to a contraction state, thereby generating contraction movement of the knee joint.

The state information of multiple kinematic tubes is transmitted into the cerebellar white matter through the resonance of the Langheck, and a discharge array is generated in the cerebellar white matter region. Through multiple movements, the discharge array in the equilibrium state is consolidated, and a discharge array pyramid is established in the gray matter neurons on the surface of the cerebellar surface. Different gray matter neurons on the surface of the cerebellar surface will be activated one after another, which will activate the corresponding state of each movement organ in the body, thereby maintaining the balance of the body.

4. Characterization of brain time

(I) Time and frequency order

The long-term memory neuron migration hypothesis believes that the cerebral cortex is formed by dividing neurons from the ventricle area and migrating to the surface of the brain. The new cortex constantly covers the old cortex. Just as archaeology can verify organisms that appear at different times by dividing soil samples at different depths of the Arctic, and the brain can characterize time through the depth of the cerebral cortex [6]. Therefore, the time frequency order of brain memory can be constructed, that is, a nerve fiber frequency order coordinate can be established on the cortical column from the ventricular area to the cerebral cortex. The frequency of the coordinate origin is the basic frequency of human electroencephalopathy, which is used to characterize the time moving average. The basic frequency thinking under the time moving average forms a summary of the individual and produces the individual's current state of mind. In this time coordinate, when you focus on the present or the upcoming minute and second, you can experience high-frequency discharge of the human brain, which creates tension, and when you recall early memories, the human brain discharges low-frequency discharge of the human brain, which creates relaxation. Experiments have proven that when embryonic cells in the ventricular area of a certain stage of pregnancy implant a longer-term pregnancy receptor, the implanted neurons will migrate to the layer where the recipient is in the same pregnancy period, rather than the layer where the receptor is implanted in the layer when the recipient is implanted in the pregnancy period [3]82. It is speculated that the characteristic frequency and location of neurons are determined by the number of splits. If the number of stem cells of neurons in the ventricular area increases, the characteristic frequency of migrated neurons continues to increase, and the location drives to the surface of the brain, the experimental results can well explain the longitudinal frequency order arrangement order of the brain. Here we return to the structure and function of the Langfei knot. The Langfei knot functions to make up for the shortcomings of the diameter of the nerve fibers, so that the nerve electric transmission will be further transmitted. Just like the strings, the thinner the fibers, the higher the frequency. So what can make nerve fibers thinner? Cell division can explain this problem well. With the increase of cell division, the cell plasmids and cytoplasm, and the function of the enzyme system continues to weaken, and the continuous shortening of telomerase leads to a decrease in the number of DNA replications, thus weakening the synthesis of various functional assembly components of nerve fibers per unit length.

The relationship between cell division time and frequency can not only explain the relationship between frequency and brain depth, but also explain the frequency order arrangement pattern of the same spherical cerebral cortex.

(II) Time assembly

When discussing the formation of the concept, the differences between the left and right brains were explained. Here we explain how it affects time encoding. In the occasionally distraction process, I suddenly realized that I could not form a coherent long-term memory chain, which led to the thinking of assembling long-term memory by short-term memory: I mentioned earlier that there is a magnifying glass between the left and right brains. The right brain completes the precise encoding of instant time information, but it has a certain time capacity. If it exceeds this capacity, the right brain needs to refresh it once. In this way, the right brain cannot encode a long time chain. With the help of the corpus callosum (maybe the hippocampus area, which needs to be verified), this full-load short-term chain of the right brain can focus on a small area of the left brain, so that the right brain constantly swipes the screen, and the left brain connects the right brain's screen-sweeping time information into film to encode the time information of the time script. This hypothesis can explain the lateralization of two types of causal reasoning in patients with split brains, that is, the right brain is good at dealing with causal perception, and the left brain is good at being causal inference. Here, causal perception is immediate fine time processing, and causal inference is coherent and continuous time processing [3] 401.

5. Dream mirror, hallucinations and addiction

(1) Dream Mirror

Wang Weigong corresponds to the twelve meridians with the twelve harmonics. Traditional Chinese medicine Ziwu Liuzhu theory divides a day into twelve hours, and each hour has a meridian running. Now physiology regards the pineal gland as the center of human biological rhythm control. The rhythm of the pineal gland is mainly determined by melatonin produced by light stimulation. Therefore, the human body senses changes in seasons and hours and produces different resonant fundamental frequencies at different times.

The previous explanation was made for the relationship between the discharge frequency of nerve cells and their position in the body. The more myelinated neurons go outward, the higher the frequency. This is consistent with the traditional Chinese medicine theory: spring grows in summer, autumn harvests in winter, winter storage theory believes that the blood flows outside in hot weather, and blood flows inside in cold weather; traditional Chinese medicine compares the four seasons of the day, qi and blood are in yang during the day, and qi and blood are in yin at night. Therefore, during the day, the high-frequency neuron discharges, the relative sensory cells and cerebral cortex discharges are active, and at night, the low-frequency neuron discharges are activated, and the high-frequency neuron discharges are blocked, which cuts off the high-frequency information income and interference outside the body. In this way, the free discharge of gray matter cells in the brain is detected by the human body, thus a dream occurs.

Conscious thinking and dreaming are two parallel thinking systems of the human body with high frequency and low frequency. Just like two parallel high frequency and low frequency sensory systems of cones and rods, the experience of using high frequency cones when low frequency rods work at night will make mistakes, and wetlands are often regarded as dry land. Therefore, dreams receive low-frequency sensory information and process it. In this way, when the lips touch the quilt, the input of low-frequency information is the same as that of kissing, so we dream of kissing. We also often have flying dreams and bicycle dreams. Physically, this is both a linear motion at a uniform speed and zero force, which is another experience as a static state of the body organ.

(II) Illusion

Hallucinations often occur after drinking or taking drugs. Judging from the components of alcohol and drugs, they are both lipophilic substances, with a small molecular weight and are easily passed through the blood-brain barrier. After entering the brain, they can dissolve the myelin of lipids, or combine with the myelin, change the thickness and chemical structure of the myelin, and ultimately change the characteristic frequency of the conduction of the hocks, causing the signal to be conducted and displaced, causing hallucinations. In addition, some substances that block the discharge of high-frequency neurons will also cause the free discharge of gray matter cells to be detected by the human body, creating hallucinations like dreams. When a person sits at a high level in meditation, before opening the eyes of heaven, it is often described seeing various colors and hearing various sounds. This is actually when a Buddhist disciple turns down the basic frequency of the human body while meditation, he perceives the dream consciously.

(III) Addiction

Familiar addictions are usually: alcohol addiction, cigarette addiction, drug addiction, gambling addiction, gaming addiction, etc. Here it is divided into two categories, which changes the frequency of Lang Hock and does not change the frequency of Lang Hock. The former: Alcohol, drugs, and nicotine can all change the frequency of Ron Hocks, which leads to a decrease in the accuracy of the brain's issuance of instructions, resulting in the behaviors that are prohibited under normal judgments are executed due to misconductance, and the execution is intended to increase the synaptic connections and experience pleasure. This continuously strengthens the behavior that should be prohibited, causing the patient to lose self-control, and constantly seeks the psychological experience state generated by the enhanced synaptic connection after the wrong discharge in the state of suction. The latter is that behaviors are easily feedback, and strengthen synaptic connections and strengthen behavior.

References:

[1] Pan Wugang, Pan Lili. Discussion on the human meridian system from molecular traditional Chinese medicine is a frequency genome regulation system [A]. Collection of Abstracts of the Second World Conference on Integration of Traditional Chinese and Western Medicine [C]. 2002

[2] Wang Weigong. The movement of Qi [M]. Beijing: Renmin University of China Press. 2006

[3][US] Michael S. Gazzaniga, Richard B.lvry, George R.Mangun. Cognitive Neuroscience——Biology of the mind [M]. Zhou Xiaolin, translated and noted by Gao Ding Guo. Beijing: China Light Industry Press, 2011:80

[4] Guo Rui; Chen Xianyou; Du Ping and other five internal organs: A study on the clinical detection of elderly male pneumoconiosis patients by traditional Chinese medicine listening and hearing the sound and distinguishing diseases [A]. Collection of Abstracts of the Third World Conference on Integrated Traditional Chinese and Western Medicine [C]. 2007

[5] Gu Huaguang, Li Li, Yang Minghao, Liu Zhiqiang, Ren Wei. Integer multiple cluster discharge rhythm generated by experimental nerve starting points. Acta Biophysics, 2003, 19(1): 68-72

[6] Qi Zhicai. Comparison of biology in Chinese and Japanese primary school science textbooks [D]. Fujian: Zhangzhou Normal University, 2012:71-72