"A team used a laser-powered quantum computer to play a theoretical game that exploits quantum entanglement, showcasing how even today’s small-scale devices can outperform classical computers under the right conditions. Credit: SciTechDaily.com" (ScitechDaily, Quantum Telepathy Goes Real: How Lasers and Ions Outsmarted Logic)
Quantum entanglement, or quantum teleportation (or, quantum telepathy) is one of the most promising, secure, and difficult communication methods. The logic of quantum teleportation is introduced in quantum games. The game looks a little bit like a chess or oak game. Two players are sitting in different rooms and they try to impact two buttons with each other. The problem with those players is that those buttons can sit on billions of levels.
There are billions of vertical and horizontal positions where those buttons can be. The players can make rules for the game before they start to play. The players can make deals. The beginner will try to hit the button. That is in the square b4. The problem is that the layer or square b4 has an imaginary part. That means the b4 square is like a tower with multiple vertical levels.
Or when we think about the precise position of the particles in certain energy levels those particles can send different wavelength wave movements than it is calculated. That means that the b4-tower is like Pisa's leaning tower. The sender must send the information precisely into the targeted layer and targeted point. The difference between those quantum towers is that they wobble all the time.
If there are no beginning adjustments we can imagine a situation where those gamers try to put ones and zeros to the papers. And they try to get matching forms. Those numbers should be precisely at certain points. On the paper. In quantum simulations, those players must use imaginary- or complex numbers. Those numbers might have even thousands of imaginary parts or dimensions.
When we think about quantum entanglements we can think that we try to make the entanglements between two peans or sand bites on the floors between two Pisa leaning towers. We don't know the precise floor. We don't know which of those soundbites is identical to the transmitting particle.
We even don't know what the receiving and transmitting particles look like. We must find the right sand bite on the tower and then transmit data to it. And those tower's positions change all the time.
The quantum entanglement must be made using the instructions that the players gave before that experiment.
Those levels are the energy levels of the particle. The horizontal level means the wavelength that the particle sends. The problem is that the gamers must give precise information about the energy level, the position, and the wavelength of waves that the particle sends so that they can put particles in a superposition between each other. The problem with theory and reality is that the system cannot precisely control the beginning position of the particles.
Those gamers can use the messenger to help each other to adjust the position of the button. The big problem is that information can turn old if the messenger is slow. The receiver can tell the position of the receiving particle to the sender by sending a messenger to tell it. However, the position of the receiving particle is changed before the messenger travels to the transmitter.
The system must put those buttons or particles in superposition and quantum entanglement before they can send information through the quantum channel. If there is some other particle, energy field, or some kind of radio burst or even gravity wave hits that channel the quantum entanglement aims information in the wrong direction. In that kind of system, information travels in the quantum string. That quantum string is the weakest part of the quantum computers. When something hits in it, that thing cuts the information flow.
When the quantum computer plays that game it uses ions and photons that it manipulates with laser beams. That kind of system is one of the most powerful systems in the world. The fact is that in the race between quantum and binary computers, the binary computers beat quantum systems in simple calculations. But then there is the limit of the complexity and after that limit, the quantum computer beats the binary system. The problem with quantum computers is simple. It must form the quantum entanglement before the data transmission can begin.
https://scitechdaily.com/quantum-telepathy-goes-real-how-lasers-and-ions-outsmarted-logic/
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