The entanglement between local information interactions
VERN BENDER
HOW TRINITARIAN PHYSICS WORKS:
The laws of physics give birth to particles on the fundamental platform of physics. From there, they move to the quantum level. Finally, they appear on the classic status, and reality is born.
HOW TRINITARIAN PHYSICS WORKS:
The laws of physics give birth to particles on the fundamental platform of physics. From there, they move to the quantum level. Finally, they appear on the classic status, and reality is born.
THE PROCESS FOR THE CREATION OF A PARTICLE:
1ST: The fundamental level of physics produces the embryonic mix that births a particle.
2ND: It then moves to the middle level, the quantum mechanical level, where transformations occur, such as the quantization of gravity
3rd: Upon completion, it moves to the classic physics level to take it onto the reality stage.
The first level of physics is the fundamental level. Construction of the universe takes place here, and it is apart from the mechanical dynamic. A binary information system drives it. It runs the numbers, sets up the equations/predictions, and then sets up production. The union of quantum mechanics and general relativity.
Binary facts drive the input/output informational results that are transformed to the quantum level. Binary information performs the tasks at hand. The system functions as a computer and a copier. It breaks reality into functions. Evaluation of possibilities takes place, then a transformation occurs. The deciding point is now reached. They set the properties at this point. Probabilistic turns to deterministic. Quantum information is in a super information state. The entanglement between local information interaction occurs before separation. Entanglement between quantum systems arises upon particle interactions. There are four entanglement states and two shapes, round or square.
The basic unit of quantum information is a quantum version of the classic binary bit that operates within a two-state device. They start quantum information from the fundamental physics blueprint level. It then moves from the quantum to the classic level because all things are triune, with binary inter-actives.
The conservation of quantum information means that quantum information cannot be duplicated or destroyed. The two theorems of quantum mechanics are the no-cloning theorem and the no-deleting theorem. While In the classical world, data can be copied and deleted.
Quantum superposing occurs when two or more quantum states come together, resulting in another valid quantum state. Conversely, we can represent every quantum state as a sum of two or more other distinct states. Also, any linear combination of results will be another result.
There are connections between entanglement and thermodynamics.
A quantum system has repeated interactions between particles that create quantum correlations and entanglements. They then interact with the properties of macroscopic systems.
A quantum bipartite system comprises two distinct parts, and it spatially separates each quantum information system.
Quantum spatially separated parties perform local operations and exchange classical communications. Separable states cause these to be still quantum states. They are entangled and separable (or disentangled)
states.
Quantum entanglement systems differ by function performed.
Entanglement-thermodynamics duality produces reversible interactions, systems in mixed states, and mirror images.
