FUNDAMENTAL STRUCTURE
The T.B.M. is composed of multiple stacked disks, rotating and interacting to generate evolving data.
Each disk encodes information through rotation and orientation.
Towers interact via bridges that modify information based on context.
The system is fractal, capable of evolving by integrating new layers and dimensions.
Binary becomes dynamic, where each bit exists in multiple simultaneous states.
DETAILED ARCHITECTURE
A T.B.M. consists of multiple interconnected information layers.
Physical Structure
1D: A simple disk, classical binary.
2D: A tower made of stacked disks.
3D: Multiple towers interconnected via bridges.
4D: A time-evolving tower, changing states based on clock cycles or user input.
5D: Fractal, self-generation, and dynamic rule modification.
Information Encoding
0 and 1 are represented by O and O + an inclined bar.
The angle of the bar encodes additional information (e.g., 45° for metadata, 90° for a secondary state).
Colors and textures add extra layers of interpretation.
Speed and direction of rotation influence data significance.
Superposition and Reading
Disks are not read linearly but based on their alignment.
Some messages remain hidden unless specific conditions are met.
A single disk may produce different results based on the sensor used (optical, magnetic, thermal).
INTERCONNECTION OF TOWERS
A single T.B.M. is an isolated system, but when multiple towers are connected, they create a fractal interactive matrix.
Bridges and Links
Fixed bridges: Stable transmission of information.
Encrypted bridges: Require the correct decryption key.
Fractal bridges: Automatically generate new connections.
Each bridge influences how towers exchange and mutate information.
Fractal Network
A network of multiple T.B.M.s creates an adaptive coding universe.
Each tower can affect its neighbors and modify its internal structure.
Information becomes superimposed and multidimensional, similar to a quantum system.
EVOLUTIONARY ALGORITHM
The T.B.M. is not static; it learns and reconfigures itself based on interactions.
Evolutionary rules allow the system to modify itself over time.
Towers can merge, split, or mutate depending on events.
Some connections may disappear or appear autonomously.
The system becomes a living algorithmic organism, capable of self-regulation and learning.
APPLICATIONS OF THE FRACTAL BINARY CODEX
Ultra-secure cryptography
Messages can be hidden under multiple layers of data.
Quantum memory and storage
Massive information compression through multiple dimensions.
Self-evolving artificial intelligence
AI that adjusts its connections based on experience.
Universal communication interface
A language adaptable to all forms of life or artificial intelligence.
T.B.M. – A FRACTAL CODEX FOR SELF-EVOLVING SYSTEMS
With the T.B.M., we open the door to a new era of coding.
While the ideas and concepts shared here are innovative and exciting, they remain theoretical and untested. We strongly encourage creativity and experimentation; however, any attempt to recreate or implement these systems should be done with **extreme caution**.
BioZnum and its affiliates cannot be held responsible for any outcomes, damages, or accidents that may occur if you decide to experiment at home. **We highly recommend conducting thorough research and small-scale tests** before attempting to build or install any larger system.
In short, these ideas are meant to inspire, but they must be carefully tested and verified on a small scale before moving forward. **Safety should always be a top priority**, and we encourage consulting professionals when necessary.