Biophilia Intruder Nonlinear (NLS) Theory of Medicine and Quantum Entropy Logic

Biophilia Intruder Nonlinear (NLS) Theory of Medicine and Quantum Entropy Logic

Biophilia Intruder's non-linear (NLS) medicine is based on the new physics of quantum entropy interactions - the theory of quantum entropy logic.

These are the main assumptions of the theory:

The fact that information is an important category is recognized. Previously existing physical theories that describe the interaction of information in the environment (Claude Shannon's information theory, Norbert Wiener's cybernetics) treat information as some kind of mathematical abstraction that describes the basic laws of information exchange, but does not reveal its physical nature. These theories do not explain the interaction of mass, energy and information, the main categories of matter, nor the emergence of basic information in scientific cognition.

Quantum entropy logic theory is the first to reveal the physical nature of information interaction and describe the interaction between mass, energy and information.

The conclusion of the logic theory of quantum entropy is as follows:

1. Any material object with biotic or abiotic properties increases its level of structural organization, i.e. becomes more complex and stable, as it absorbs information from the environment.

2. Any material object with biological or non-biological properties reduces its level of structural organization when it loses information, so it becomes the fundamental physics of NLS diagnostics V.I. Nesterov is more unstable and disorganized. For biological objects, the loss of structural organization (information) implies a deterioration in adaptive behavior, the development of disease, and ultimately the death of the organism.

3. There is always information noise around any corrupted object that loses information. The more intense the destruction of the biological object, the more severe the disease progression was recorded, and the higher the level of information noise around the object. Therefore, if we measure the level of information noise around a biological object, we will be able to judge how quickly that object is destroyed; if we measure the frequency characteristics of the noise background, we will understand which tissues in the organism are more destroyed and altered than others. Many, because each tissue in an organism has its own specific radiation spectrum that differs from other tissues.