AI will revolutionize observation technology. Sam Altmann’s new startup researches the ability to use acoustic waves to read brains. This new type of Brain-computer interface, BCI, doesn’t need surgery or microchips. Just acoustic waves that read the mind. The system observes the behavior of the neurons, or maybe it sees the neurotransmitters using acoustic-optical inspection. The system uses highly accurate sonar signals to observe the brain shell.
The AI can analyze those functions and make it possible to create a system that reads minds, using acoustic waves. The system will transmit acoustic waves into the brain. The system analyzes the reflected waves. This makes it possible. To create a BCI system. That acts without knives and electromagnetic signals.
The point at which that system directs the observation signal is not specified. Researchers can use acoustic signals to observe blood vessels and tissues; however, the challenge lies in determining the optimal frequency and wavelengths. When an acoustic system creates a sound wave, or an acoustic wave, it must use a wavelength that is smaller than the observable target.
And this means that the system must have a transmitter that is smaller than the observable object. New materials. Like triangle-shaped graphene and fullerene are tools that can be used to make very sharp acoustic tools. In some models, the fullerene balls form so-called quantum lanterns. There is some atom in the fullerene ball, and then the system injects energy into that atom or molecule. Then that molecule sends an energy signal outside the system. The system can consist of two fullerene balls, or nano-lanterns. That makes them the nano-sized fullerene doppler system.
By using fullerene nanotubes and the linear atom chains, where atoms are in a straight line. Makes it possible to use this system. As the nano-sized LRAD system. Or “sound cannon”. Those very high-accurate signals can make it possible to see incredibly small structures. In a triangle-shaped graphene. The system focuses energy into one point. If there is some other material. Where that graphene structure injects energy. That makes another material oscillate. The biggest difference. Between acoustic and electromagnetic waves. Is the thing. that transmits energy. Acoustic waves are molecular and atomic movements.
And in electromagnetic waves. Electromagnetic fields are moving. An electromagnetic wave can transform into an acoustic wave. When a laser wave injects energy into the graphene structure, that structure starts to oscillate. We hear that oscillation as sound waves. In monoatomic structures, the energy impulse that hits the bottom of the structure creates phenomena called phonons.
A phonon is a so-called quantum acoustic wave. That allows for the transmission of energy into the structures with a very high accuracy. That kind of system can allow. An acoustic signal transmission from the triangle-shaped graphene to the larger graphene layer with one-atom accuracy, if the tip of that triangle is one atom in size.
There are tests that the small particles will be driven to the organs. And then the system puts them to oscillate. Those particles send oscillations as an acoustic wave through the structure. That makes acoustic waves that the system sees as the image. Denser points change the acoustic wave behavior. And that makes an image for the system. If an acoustic wave causes the cell’s proteins to oscillate. That makes it possible to observe those cells by analyzing those waves.
When the system pumps energy into the fullerene ball. That ball releases that energy into the wavelength that is the same as the fullerene ball. Fullerene is a monoatomic carbon structure. And can those atoms send separate waves, depending on the question, can those waves unite into one entirety? Anyway, those atoms form standing waves between them.
But if we put one carbon atom into our fullerene lantern and inject energy into that atom, the atom sends an energy impulse to the fullerene ball and makes its carbon atom structure oscillate. That oscillation forms standing waves in the chemical bonds. The point. The standing wave form determines whether it can destroy the structure. In the first case, most of those waves travel in empty space between atoms. But in the second case, the wave movement forms a standing wave in chemical bonds. And in that case, there is no need for a strong force to push atoms away. An energy impulse that travels in chemical bonds creates so-called solitons in those structures. Solitons are impacting waves. And then energy jumps back from that structure to the atom.
If standing waves form between those atoms in empty space. Those waves also oscillate. Or when the energy level in energy stress decreases. That decreases the size of those standing waves. In that case, this movement forms low-pressure energy around those waves, and they can pull energy out from their environment. This is why the standing wave that forms in empty space is less vulnerable than the standing wave in chemical bonds.
https://spj.science.org/doi/10.34133/research.0200
https://www.techlusive.in/artificial-intelligence/what-if-ai-could-hear-your-thoughts-sam-altman-is-building-a-device-that-can-read-your-thoughts-without-touching-your-brain-1613435/
https://www.voltaireweb.com/post/sam-altman-is-hedging-bets-on-startup-that-seeks-to-rewire-brain
https://en.wikipedia.org/wiki/Graphene
https://en.wikipedia.org/wiki/Phonon
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