The Theory of Entropicity (ToE) Dethrones the Observer and Demands that Two or More Observers Cannot Observe the Same Event at the Exact Same Moment, No Matter their Frames of Reference 

The Theory of Entropicity (ToE), as first formulated and further developed by John Onimisi Obidi proposes that entropy, not the observer, is the fundamental principle that governs reality, thus effectively "dethroning" the observer from a central role in physics. 

Instead of observers defining measurements and frames, the Theory of Entropicity posits that an entropic field pre-computes reality. The observer is a secondary subsystem embedded within this field, and their measurements are constrained by entropy's finite redistribution rates. This new framework suggests that phenomena like length contraction and time dilation are not just observational effects but are physical consequences of the entropic field, unified under a single principle where entropy flows at a finite maximum rate. 

The role of the observer in the Theory of Entropicity

• Observer as a secondary subsystem: In this theory, the observer is not a privileged entity. Instead, they are a local subsystem whose existence and perception are constrained by the universal entropic field.
• Observation as an entropic process: ToE proposes that every observation is an act of measurement that requires a finite transfer of entropy.
• Observer-dependent measurements: Because each measurement requires a finite entropy transfer, it means that the Theory of Entropicity (ToE) resolutely teaches us that two observers cannot observe the same event at the exact same moment. The first observer's measurement collapses the entropy first, creating a delay for any subsequent observer.
• Resolving quantum paradoxes: By framing measurement as a physical process constrained by entropy, ToE aims to resolve quantum paradoxes, such as the Schrödinger's Cat and Wigner's Friend scenarios, by reinterpreting them as physical constraints rather than logical or philosophical puzzles, or [strictly] observer-dependent relations. 

The observer in traditional physics versus ToE

Feature	Traditional Physics (Relativity and Quantum Mechanics)	Theory of Entropicity (ToE)
Role of Observer	Foundational role in defining frames, measurements, and wave function collapse.	Secondary and embedded within the entropic field.
Basis of Reality	Observer-dependent phenomena play a crucial role.	The entropic field pre-computes reality independently of any single observer.
Causality and Measurement	Observer's frame and measurements are central to understanding reality.	Reality is defined by the entropic field, making observer coordinates secondary.
Unification goal	To unify different aspects of physics, often with the observer at the center.	To unify physics under a single, entropy-centric principle, which places the observer in a subservient position.

Revolutionary Implications of the Theory of Entropicity (ToE)

• Relativity as emergent: The Theory of Entropicity (ToE) posits that Einstein's theory of relativity is not a fundamental theory but an emergent one, arising from the dynamics of the entropic field.
• Finite entropy redistribution: The core principle is that entropy cannot redistribute infinitely. This finite rate imposes constraints on the universe, leading to phenomena like length contraction and time dilation as physical consequences.
• Physical mechanism for mass increase: ToE provides a physical mechanism for mass increase, which is a direct result of the entropic field's finite budget being allocated to sustaining inertia at higher velocities.
• Connections to thermodynamics and information theory: The theory connects relativity with information theory and thermodynamics, providing a unified framework for these disciplines.