The Theory of Unified Relativity for a Biovielectroluminescence Phenomenon via Fly's Visual and Imaging System

TL;DR

This paper proposes a unified relativistic theory linking fly's visual system to computer graphics, enabling enhanced imaging, faster data processing, and applications in 3D viewing, medical imaging, and military tech.

Contribution

It introduces a novel unified relativity framework connecting fly's neuronal patterns with computer graphics and proposes a bio-inspired optical circuit for advanced visual processing.

Findings

Fly's faster pulses relate to visual processing speed.

Circuit experiments demonstrate RGB-time matrix for image encoding.

Potential applications in 360-degree displays and real-time rendering.

Abstract

The elucidation upon fly's neuronal patterns as a link to computer graphics and memory cards I/O's, is investigated for the phenomenon by propounding a unified theory of Einstein's two known relativities. It is conclusive that flies could contribute a certain amount of neuromatrices indicating an imagery function of a visual-computational system into computer graphics and storage systems. The visual system involves the time aspect, whereas flies possess faster pulses compared to humans' visual ability due to the E-field state on an active fly's eye surface. This behaviour can be tested on a dissected fly specimen at its ommatidia. Electro-optical contacts and electrodes are wired through the flesh forming organic emitter layer to stimulate light emission, thereby to a computer circuit. The next step is applying a threshold voltage with secondary voltages to the circuit denoting an array of essential electrodes for bit switch. As a result, circuit's dormant pulses versus active pulses at the specimen's area are recorded. The outcome matrix possesses a construction of RGB and time radicals expressing the time problem in consumption, allocating time into computational algorithms, enhancing the technology far beyond. The obtained formulation generates consumed distance cons(x), denoting circuital travel between data source/sink for pixel data and bendable wavelengths. Once 'image logic' is in place, incorporating this point of graphical acceleration permits one to enhance graphics and optimize immensely central processing, data transmissions between memory and computer visual system. The phenomenon can be mainly used in 360-deg. display/viewing, 3D scanning techniques, military and medicine, a robust and cheap substitution for e.g. pre-motion pattern analysis, real-time rendering and LCDs.