Connecting a device to Earth's electrostatic charge

How are electromagnetic charges to be activated, or transmitted and received? Nikola Tesla found that power of Earth’s atmosphere is high voltage. His theory is best describe in Quara by William Beaty:  Wardenclyffe Tower was a type of spark transmitter, operating in groundwave mode in the ELF frequency band.

ELF frequency band

An Extremely Low Frequency (ELF) band refers to electromagnetic radiation (radio waves) with frequencies ranging from 3 to 30 Hz, as designated by the International Telecommunication Union (ITU). In atmospheric science, the range extends from 3 Hz to 3,000 Hz. ELF waves have corresponding wavelengths of 100,000 to 10,000 kilometers, respectively. The extremely low frequencies are generated by Earth’s magnetosphere, and from Earth’s electrostatic fields, the fields generate lightening. In addition to nature, ELF frequency bands are used for underwater communication. These extremely low frequencies are also seen in Schumann Resonances.

Where is the correlation between Earth’s radiating electrostatic field and the ability for a Cavity Structures Effect (CSE) to interact with it? A CSE is always active. Its void holds a negative charge. Earth’s electrostatic field and its magnetosphere are also always active. Most of the lightening charges are negative, positive charged lightening is more powerful. 

From the blogpost Extending CSE research: The Cavity Structures Effect (CSE) is caused by the interaction between de Broglie waves and biological systems. Cavities within the solid body are de Broglie wave resonators; they are a source of standing de Broglie waves (longitudinal waves). The rhythmical location of cavities leads to a reinforcement of the effect.

From the blogpost: Levitation, solve for a+b; Thus far, studies show that levitation is an accumulation of electrons’ frequency vibration. From the past few articles about levitation, it becomes clear that research needs to go back to the work of Viktor Grebennikov’s Cavity Structures Effect (CSE).

With this, a platform built with compressed CSEs, has the potential to interact with Earth’s negative electrostatic atmospheric charge. Viktor Grebennikov’s platform had control “blinds”. This is a first step.

How a cell phone interacts with Earth’s electromagnetic field

Asking questions of how to connect Earth’s electrostatic field to CSEs to provide levitation for a transportation device, there might be a correlation in asking another question. How does a cell phone work? A cell phone works by using radio waves to transmit and receive signals, allowing for wireless communication. Here’s a simplified explanation of the process:

1. Microphone and Speaker: A microphone inside the phone interprets the voice and converts it into electrical signals. These signals are then sent to the speaker, which converts them back into audible sound waves.
2. Radio Transceiver: The electrical signals are transmitted and received via radio waves through an antenna.
3. Cell Towers: The radio waves travel through the air and are picked up by nearby cell towers. These towers are strategically placed to create a network of coverage, dividing the area into smaller sections called cells. Each cell has an antenna that receives cell phone signals.
4. Signal Transmission and Reception: The cell tower’s antenna transmits the signals to a base station, which is connected to the larger cellular network. The network then routes the call or message to its destination, whether it’s another cell phone or a landline. When the recipient’s phone receives the signal, their radio transceiver converts the radio waves back into electrical signals, which are then sent to the speaker to be heard.
5. Roaming: If you’re outside of your cellular network’s coverage area or if the nearest cell site’s signal is too weak, your phone may automatically connect to a different network through a process called roaming. This allows you to continue making and receiving calls even when you’re not in your usual coverage area.

In summary, a cell phone works by converting your voice into electrical signals, transmitting those signals as radio waves to nearby cell towers, and then routing the signals through the cellular network to reach their destination. The process is reversed for incoming calls and messages.

How is data transmitted over a cellular network different from voice transmission?

Data transmission over a cellular network differs from voice transmission in several ways. While both use radio waves to transmit signals to and from cell towers, the way the signals are processed and handled by the network can vary.

1. Signal Type: Voice transmission involves converting your voice into electrical signals, which are then converted into radio waves. Data transmission, on the other hand, deals with digital information, such as emails, web browsing, and app usage. This digital information is converted into a series of 1s and 0s, which are then encoded into radio waves for transmission.
2. Transmission Protocols: Voice transmission typically uses older analog technologies, such as 2G (GSM, CDMA) and some parts of 3G (UMTS), while data transmission relies on more advanced digital technologies, such as 3G (HSPA), 4G (LTE), and 5G. These newer technologies offer faster data speeds and more efficient use of network resources.
3. Network Prioritization: In most cases, cellular networks prioritize voice traffic over data traffic. This means that during periods of network congestion, voice calls are less likely to be affected by slower data speeds or dropped connections.
4. Frequency Bands: Cellular networks use different frequency bands for voice and data transmission. For example, in some networks, voice calls may use lower frequency bands (e.g., 850 MHz or 900 MHz) for better building penetration and wider coverage, while data transmission may use higher frequency bands (e.g., 1800 MHz, 2100 MHz, or 2600 MHz) for higher data speeds.
5. Charging and Billing: Charging and billing for voice and data services can also differ. In some cases, carriers may charge separately for voice and data usage, while others may offer bundled plans that include a certain amount of voice and data. The pricing and billing structure can vary depending on the carrier and the specific plan.

In summary, data transmission over a cellular network differs from voice transmission in terms of signal type, transmission protocols, network prioritization, frequency bands, and charging and billing structures. While both rely on radio waves for signal transmission, the underlying technologies and network handling can differ significantly.

(AI-generated answer)

Interacting with Earth’s electrostatic field

Looking into the details at the presents of Earth’s electromagnetic field is the question. This is associated with De Broglie waves.

De Broglie postulated that an object (Earth’s electromagnetic field) can be both a particle and a wave. He derived a relationship between one of the wave-like properties of matter and one of its properties as a particle, which is called duality. The de Broglie waves can be identified as the unified path of particle mass. In a new theory for gravity, it explains: This new theory for gravity postulates that gravity is angular momentum in the path of particle motion in accordance with Einstein's theory of relativity. His explanation of relativity being energy equal to mass times the speed of light squared shows perception of relativity: is traveling at the speed of light.

The cell phone uses a battery to power its transceiver to send and receive signals. Viktor Grebennikov’s levitating device utilized compressed CSEs to enact a negative force to interact with Earth’s electrostatic field. It manipulates the field via pivoting fans attached to an axis of the “blinds”. This seems to be the answer.

One of the greatest lectures regarding Earth’s electric potential gradient of the atmosphere is from the California Institute of Technology: The Feynman Lectures on Physics, Electricity in the Atmosphere:

Although the electric current-density in the air is only a few micromicroamperes per square meter, there are very many square meters on the earth’s surface. The total electric current reaching the earth’s surface at any time is very nearly constant at 1800 amperes. This current, of course, is “positive”—it carries plus charges to the earth. So we have a voltage supply of 400,000 volts with a current of 1800 amperes—a power of 700 megawatts!

Feynman’s lecture goes into great detail, and an exquisite explanation on lightening.

The point of this blogpost is to point out that Earth holds a negative charge. Grebennikov’s device, with the CSE’s held a negative charge. Earth’s atmosphere consists of both positive and negative charges. Grebennikov’s negatively charged device would repel Earth’s negative charge. The pivoting fans would manipulate a negative repelling action. 

Again, first step in the answer.