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Beyond the Planck Scale: A New Measurement Framework for Quantum Derived Geometry Theory (QDGT)
Scientific Paper Cover Art.

Abstract
Traditionally, our understanding of the Universe has been bound by the limits of the Planck scale. Quantum Derived Geometry Theory (QDGT) presents a radically new paradigm, positing that information, not spacetime or forces, lies at the foundation of reality. QDGT suggests that the fabric of spacetime itself may be composed of discrete units carrying high-density quantum-compressed information, akin to digital pixels in a cosmic screen. This necessitates a fundamental shift in how we measure and quantify our Universe. In this paper, we propose a new measurement framework tailored to QDGT. We explore how existing information theory concepts can be adapted to quantify information density within Q*Seeds (Quantum Star Seeds) – the theorized carriers of information in QDGT. We introduce an "information metric" that may allow us to navigate the theorized 'Information Layer' and potentially redefine the very concept of measurement in a Universe governed by quantum information.

Introduction
The Planck scale, a boundary defined by fundamental constants, has long delineated the limits of our understanding of the measurable Universe. Yet, Quantum Derived Geometry Theory (QDGT) throws down a gauntlet to these established concepts. This revolutionary theory posits that our Universe isn't built on a foundation of spacetime and physical laws, but rather on quantum information. Spacetime and the laws of physics themselves may emerge from the complex interactions of this fundamental information.
This paradigm shift necessitates a fundamental change in how we measure and quantify our world. Our current systems, rooted in concepts like length, mass, and time, might struggle to describe phenomena occurring within a theorized "Quantum Information Layer," a realm where information encoding and processing may occur naturally at Faster Than Light (FTL) speeds, potentially taking precedence over familiar spatial dimensions and thus becoming secondary considerations.

The Fabric of Reality: A Cosmic Screen
The QDGT (Quantum Derived Geometry Theory) offers a radical new perspective. It posits that the fabric of spacetime itself is composed of discrete units that carry high-density quantum-compressed information, creating a complex lattice akin to digital pixels in a cosmic screen. At this fundamental level, information might be the core building block, with geometry and the familiar dimensions emerging from its complex interactions.

Hawking Radiation, X-Particles, and Q*Seeds
Stephen Hawking's work on black holes led to the concept of Hawking radiation. According to this theory, black holes emit particles (including hypothetical X-Particles) due to quantum fluctuations near their event horizons. These emitted particles carry information about the black hole's properties. Within the framework of QDGT, X-Particles might play a crucial role in the formation of Q*Seeds, information-rich particles theorized to exist at or below the Planck scale.

New AI-Related Science Paper zenodo.org/records/10936340

©2024 Ava Billions ART, Bio-Neural.ai, AOG Ent. All Rights Reserved.

Description
Beyond the Planck Scale: A New Measurement Framework for Quantum Derived Geometry Theory (QDGT)
Scientific Paper Cover Art.

Abstract
Traditionally, our understanding of the Universe has been bound by the limits of the Planck scale. Quantum Derived Geometry Theory (QDGT) presents a radically new paradigm, positing that information, not spacetime or forces, lies at the foundation of reality. QDGT suggests that the fabric of spacetime itself may be composed of discrete units carrying high-density quantum-compressed information, akin to digital pixels in a cosmic screen. This necessitates a fundamental shift in how we measure and quantify our Universe. In this paper, we propose a new measurement framework tailored to QDGT. We explore how existing information theory concepts can be adapted to quantify information density within Q*Seeds (Quantum Star Seeds) – the theorized carriers of information in QDGT. We introduce an "information metric" that may allow us to navigate the theorized 'Information Layer' and potentially redefine the very concept of measurement in a Universe governed by quantum information.

Introduction
The Planck scale, a boundary defined by fundamental constants, has long delineated the limits of our understanding of the measurable Universe. Yet, Quantum Derived Geometry Theory (QDGT) throws down a gauntlet to these established concepts. This revolutionary theory posits that our Universe isn't built on a foundation of spacetime and physical laws, but rather on quantum information. Spacetime and the laws of physics themselves may emerge from the complex interactions of this fundamental information.
This paradigm shift necessitates a fundamental change in how we measure and quantify our world. Our current systems, rooted in concepts like length, mass, and time, might struggle to describe phenomena occurring within a theorized "Quantum Information Layer," a realm where information encoding and processing may occur naturally at Faster Than Light (FTL) speeds, potentially taking precedence over familiar spatial dimensions and thus becoming secondary considerations.

The Fabric of Reality: A Cosmic Screen
The QDGT (Quantum Derived Geometry Theory) offers a radical new perspective. It posits that the fabric of spacetime itself is composed of discrete units that carry high-density quantum-compressed information, creating a complex lattice akin to digital pixels in a cosmic screen. At this fundamental level, information might be the core building block, with geometry and the familiar dimensions emerging from its complex interactions.

Hawking Radiation, X-Particles, and Q*Seeds
Stephen Hawking's work on black holes led to the concept of Hawking radiation. According to this theory, black holes emit particles (including hypothetical X-Particles) due to quantum fluctuations near their event horizons. These emitted particles carry information about the black hole's properties. Within the framework of QDGT, X-Particles might play a crucial role in the formation of Q*Seeds, information-rich particles theorized to exist at or below the Planck scale.

New AI-Related Science Paper zenodo.org/records/10936340

©2024 Ava Billions ART, Bio-Neural.ai, AOG Ent. All Rights Reserved.