5G – WTF? so, ok I know I used 5G with out definition so I thought I might/should illustrate why I’m so concerned about its application. Here goes.
This is a frequency band change from centimeters to millimeters. One centimeter equals 10 millimeters, the wave from crest to crest is way shorter. So, really what is happening with 5G is the use of a shorter version of the same thing – like reducing a photo – it all stays in proportion – it just gets smaller. There are many ways to manipulate the wave form, you can pack it inside of another wave, you can diffraction grate it to tune its frequency:
Further information: Interference (wave propagation) Interferometry makes use of the principle of superposition to combine waves in a way that will cause the result of their combination to have some meaningful property that is diagnostic of the original state of the waves. This works because when two waves with the same frequency combine, the resulting intensity pattern is determined by the phase difference between the two waves—waves that are in phase will undergo constructive interference while waves that are out of phase will undergo destructive interference. Waves which are not completely in phase nor completely out of phase will have an intermediate intensity pattern, which can be used to determine their relative phase difference. Most interferometers use light or some other form of electromagnetic wave.
you can shoot multiples all at once:
Beamforming or spatial filtering is a signal processing technique used in sensor arrays for directional signal transmission or reception. This is achieved by combining elements in an antenna array in such a way that signals at particular angles experience constructive interference while others experience destructive interference. Beamforming can be used at both the transmitting and receiving ends in order to achieve spatial selectivity. The improvement compared with omnidirectional reception/transmission is known as the directivity of the array.
Beamforming can be used for radio or sound waves. It has found numerous applications in radar, sonar, seismology, wireless communications, radio astronomy, acoustics and biomedicine. Adaptive beamforming is used to detect and estimate the signal-of-interest at the output of a sensor array by means of optimal (e.g. least-squares) spatial filtering and interference rejection
The beamforming technique involves sending the pulse from each projector at slightly different times (the projector closest to the ship last), so that every pulse hits the ship at exactly the same time, producing the effect of a single strong pulse from a single powerful projector. The same thing can be carried out in air using loudspeakers, or in radar/radio using antennas.
conventional (fixed or switched beam) beam formers
adaptive beam formers or phased array
Desired signal maximization mode
Interference signal minimization or cancellation mode
you can sort it – the choices and the current technology are endless.
The millimeter-wave region of the electromagnetic spectrum is usually considered to be the range of wavelengths from 10 millimeters (0.4 inches) to 1 millimeter (0.04 inches). This means millimeter waves are longer than infrared waves or x-rays, for example, but shorter than radio waves or microwaves. The millimeter-wave region of the electromagnetic spectrum corresponds to radio band frequencies of 30 GHz to 300 GHz and is sometimes called the Extremely High Frequency (EHF) range. The high frequency of millimeters waves as well as their propagation characteristics (that is, the ways they change or interact with the atmosphere as they travel) make them useful for a variety of applications including transmitting large amounts of computer data, cellular communications, and radar.
One of the greatest and most important uses of millimeter waves is in transmitting large amounts of data. Every kind of wireless communication, such as the radio, cell phone, or satellite, uses specific range of wavelengths or frequencies. Each application provider (such as a local television or radio broadcaster) has a unique “channel” assignment, so that they can all communicate at the same time without interfering with each other. These channels have “bandwidths” (also measured in either wavelength or frequency) that must be large enough to pass the information from the broadcaster’s transmitter to the user. For example, a telephone conversation requires only about 6 kHz of bandwidth, while a TV broadcast, which carries much larger amounts of information, requires about 6 MHz (A kilohertz, is one thousand cycles per second; a megahertz is one million cycles per second). Increases in the amount of information transmitted require the use of higher frequencies. This is where millimeter waves come in. Their high frequency makes them a very efficient way of sending large amounts of data such as computer data, or many simultaneous television or voice channels.
Radar is another important use of millimeter waves, which takes advantage of another important property of millimeter wave propagation called beam width. Beam width is a measure of how a transmitted beam spreads out as it gets farther from its point of origin. In radar, it is desirable to have a beam that stays narrow, rather than fanning out. Small beam widths are good in radar because they allow the radar to “see” small distant objects, much like a telescope. A carefully designed antenna allows microwaves to be focused into a narrow beam, just like a magnifying glass focuses sunlight
Today’s wireless networks have run into a problem: More people and devices are consuming more data than ever before, but it remains crammed on the same bands of the radio-frequency spectrum that mobile providers have always used. That means less bandwidth for everyone, causing slower service and more dropped connections.
One way to get around that problem is to simply transmit signals on a whole new swath of the spectrum, one that’s never been used for mobile service before. That’s why providers are experimenting with broadcasting on millimeter waves, which use higher frequencies than the radio waves that have long been used for mobile phones.
- Millimeter waves
- 30-300 gigahertz
- Absorbed by plants and precipitation
- 1mm = o.o4 in
- 1 gig = 1 bil. cycles/sec.
- 1 kilohertz = 1,000 cycles per second.
- Used on satellites and RADAR
- Radar changes dna
Millimeter waves are broadcast at frequencies between 30 and 300 gigahertz, compared to the bands below 6 GHz that were used for mobile devices in the past. They are called millimeter waves because they vary in length from 1 to 10 mm, compared to the radio waves that serve today’s smartphones, which measure tens of centimeters in length.
Until now, only operators of satellites and radar systems used millimeter waves for real-world applications. Now, some cellular providers have begun to use them to send data between stationary points, such as two base stations. But using millimeter waves to connect mobile users with a nearby base station is an entirely new approach.
There is one major drawback to millimeter waves, though—they can’t easily travel through buildings or obstacles and they can be absorbed by foliage and rain. That’s why 5G networks will likely augment traditional cellular towers with another new technology, called small cells.
Small cells are low-powered cellular radio access nodes that operate in licensed and unlicensed spectrum that have a range of 10 meters to a few kilometers
So, what are the dangers to the human structure, function and DNA?
Digital and wireless devices have provided many benefits, however, we are now realizing that the rapid adoption of this novel technology has not been accompanied by adequate regulation, monitoring or safety precautions.
Widespread use of digital media and near constant exposure to wireless devices has caused increasing concern among scientists, health care professionals, psychologists, educators and the public who are now considering this is not only a public health issue but a looming public health crisis. (11,108) It appears that we are at the same point of emerging science similar to early recognition of health impacts associated with tobacco, asbestos, coal dust and lead. (119) These concerns are amplified by industry proposals for a massive expansion of wireless infrastructure and connectivity.
Through both science and observation, we are learning that there are significant adverse health, psychosocial, environmental, privacy and security issues associated with the use of this modern technology. This raises many challenges and questions for physicians and other health care professionals, patients and our society regarding the development and use of this technology. To date digital technology has not been addressed in the U.S. from a public health, individual health or environmental perspective.
The abundance of peer reviewed science showing harm coupled with obsolete radiofrequency safety guidelines that fail to address long term health effects and non-thermal biological effects indicate that a precautionary approach is essential to reduce potential harm to the public and the environment. (11, 14, 20) Relevant factors which are also not considered in exposure standards include critical windows of development, genetic variability/predisposition, age, individual health status, combined toxic exposures and simultaneous exposure to multiple frequencies. Several countries and cities around the world have recently adopted policies which reduce exposure, limit advertising of digital devices to children and increase transparency regarding measurements of electromagnetic radiation (EMR) and documented health effects. (119)
Biochemical Mechanisms of Harm from Microwave Radiofrequency EMR
At least one underlying biochemical mechanism of toxicity of radiofrequency electromagnetic radiation (RF EMR) has been observed to be in many instances similar to common toxins such as pesticides, industrial chemicals and heavy metals. Effects include oxidative damage, altered intracellular signaling, membrane effects, direct effects on proteins, and free radical production. (11, 73, 74, 88, 89, 100)
Oxidation-Disruptions of normal cellular processes are caused by the overproduction of reactive oxygen species, causing oxidation of biomolecules leading to DNA damage, mitochondrial disruption, altered differentiation and proliferation. This is well known to contribute to a number of pathologic diseases such as cancer, neurologic harm, metabolic harm and reproductive harm (80, 114, 115). Measurements of reactive oxygen species in different tissues are now used in biomedical research as a biomarker for inflammation, toxic exposure and disease. (17, 70, 71, 116, 117, 118)
Voltage Gated Calcium Channels- Experimental evidence in basic science research supports a plausible biochemical mechanism of EMR effects to be related to alterations of cellular voltage gated calcium channels and cellular nitrous oxide production. (81-84) All cells in living organisms have an electrical voltage across their membrane which is generated by unequal distributions of ions such as potassium (K), Sodium (Na) , Chloride (Cl) and Calcium (Ca). An active transport system for each keeps the cell membrane in electrochemical balance. Miniscule electric fields can alter this balance and thus biological processes. (85)
Calcium-The Ultimate Signaling Molecule-Studies show electromagnetic exposure has biological effects on critical cellular calcium channels. (81-85) Calcium has been called the “ultimate signaling molecule for organisms … [and]…mediates processes as diverse as synaptic transmission, muscle contraction, insulin secretion, fertilization, and gene expression”. (93) These cellular alterations on calcium channels could have significant effects on diverse physiological and developmental events without breaking any chemical bonds. (84, 86, 93-96)
DNA Damage by Ionizing Radiation-Ionizing radiation is known to cause direct double stranded DNA breaks and this is an established mechanism for chromosomal damage. (110, 121,129, 130 ) It is also known that late post-radiation effects from ionizing radiation are due to an indirect mechanism, reactive oxygen species (ROS), that cause mitochondrial DNA damage that can be heritable when mitochondria replicate. (134) ROS cause epigenetic changes, in one mechanism, through an alteration of enzymes known as methyltransferases which control nuclear DNA and thus the central control mechanism of the cell
DNA Damage by Radiofrequency Non-ionizing radiation-Research has demonstrated that low intensity long term exposure to non-ionizing microwave radiation can cause single strand breaks as well as double strand DNA breaks through an indirect mechanism. Lai and Singh in 1995 were one of the first to identify single-strand breaks in rat brain cells with low-intensity microwave radiation. (136) A year later they published further research showing not only single but also more damaging double-stranded DNA breaks with low intensity RF EMR. (137) The following year they repeated the studies but added a group of rats given melatonin, a potent free radical scavenger, before and after RF exposure. They found that melatonin blocked the adverse effects of the microwave radiation. (138) These results are especially meaningful as Dr. Lai and his group produced important research developing an industry standard variation of the comet assay which is still used today to test for qualitative and quantitative DNA damage to cells. (139, 140, 141) His work was confirmed by Paulrai and Behari in 2006. (142) Ghandi in 2005 looked at the blood lymphocytes of 24 cell phone users who used their phones for a variable time frame of 1.5 to 9 hours a day. He found a direct dose response curve of chromosomal aberrations and length of exposure to cell phone frequency microwave radiation. (143)
The BioInitiative Report, the Reflex Project in Europe and others have compiled a myriad of studies which demonstrate genetic damage from non-thermal radiofrequency radiation exposure. (11, 145, 146)
Epigenetics: Indirect Alteration of DNA Functions
The science of epigenetics is a popular topic among scientists and physicians alike. Research is extensive in this field and crosses many disciplines. Epigenetics investigates inherited and non-inherited changes in gene expression that occur without a change in DNA nucleotide sequencing. Epigenetic mechanisms include changes in cell nuclear structures that broadly affect cell regulation. These include DNA methylation, histone modifications, and microRNA (miRNA) expression.
Methylation (adding a CH3 molecule) of DNA nucleotides is a frequently used epigenetic signaling tool used to turn genes in the “off” position. This is done by DNA methyltransferases which are pivotal to normal development and healthy cell functioning. Disruption of this system can lead to human disease. Researchers are investigating methylation defects and congenital abnormalities as well as cancer promotion whereby tumor suppression genes are shut off by environmental factors. (133-135) Micro RNA consists of non-coded RNA with about 20 nucleotides which function to regulate gene expression, controlling diverse cellular and metabolic pathways, including acting as a gene silencing mechanism. (149)
Toxins cause epigenetic changes. A variety of environmental toxicants are known to cause detrimental epigenetic changes. These include alcohol, asbestos, benzene, endocrine disruptors, nanomaterials, metals and ionizing radiation. This constitutes another indirect mechanism whereby toxicants can cause a heritable change in DNA that can alter function. (123-128) From <https://mdsafetech.org/featured-page-one/join-mdsafetech-org/>
This is huge and very excellent paper with all the research sources at the end. I encourage you to go read it.
All of the above is about our 4G centimeter size wave. The smaller you get in wave size, the closer you get to a size that can affect the human (nanometer size) cellular, endocrine, nervous and various other systems, 5G will be a dimensional jump smaller. Smaller than nano you are looking at the frequency of DNA and quantum particles and photons!
When you understand that all life is a wave form and that wave form is energy, then you begin to see the potential for both the good and the bad in learning how to utilize, recreate and measure in all life, the frequencies in their respective octaves.
Consider this; resonance – when something is just the same in the octave above or below it, like middle C on the piano and high C above it and low C below it, it will resonate and create an effect even if the frequency used is not in the native octave.
Now, hook this to HAARP that works in the ionosphere, CERN that works with the magnetosphere all the satellites that work in the radio and microwave frequencies and then the nanotech in chemtrails: and the entire range of frequency in the living spectrum of the earth is now, at this point being altered and experimented on mostly to our detriment and without our consent!
Remember the madness???
PS. in doing the research for this article I found this interesting tid bit: This is what it sounds like to have wifi translated into sound and to walk around in it. The article is cool too.