Spacetime as a discrete computational NavMesh: Deriving a 0.8723as universal r.r

TomerHaimovich1 pts0 comments

A Unified Digital Physics Framework: Deriving the Cosmic Refresh Rate, Relativistic Latency, and Quantum Superposition from Geometric Information Optimization | Zenodo

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Published July 9, 2026

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A Unified Digital Physics Framework: Deriving the Cosmic Refresh Rate, Relativistic Latency, and Quantum Superposition from Geometric Information Optimization

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Haimovich, Tomer1

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Independent Researcher, Israel

Description

This paper introduces a comprehensive mathematical framework within the domain of digital physics, conceptualizing the universe as a discrete, relational computational system. By enforcing an information-theoretic optimization constraint based on the asymmetric properties of the golden ratio (φ), we derive the precise fundamental processing interval of spacetime, termed the Server Tick (ℵc), calculated to be exactly ℵc ≈ 8.72322 × 10−19 seconds. Multiplying this temporal baseline by the speed of light (c) yields an explicit spatial batch-processing resolution of D ≈ 0.2615 nm, aligning precisely with the empirical characteristic scale of stable atomic structures. We formulate a Unified Rendering Equation (Rconso) that integrates global cosmological expansion and localized general relativistic phenomena (via Schwarzschild metrics) as algorithmic latencies within the execution loop. Finally, we provide two explicit, falsifiable empirical predictions designed to distinguish this model from continuous frameworks: (1) a distinct background spectral anomaly concentrated at 4.74 keV within the Cosmic X-ray Background (CXB) in deep-space environments, and (2) the rigid temporal quantization of electronic state transitions constrained to integer blocks of 0.8723 attoseconds.

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References

Wheeler, J. A. (1989). "Information, physics, quantum: The search for links." Proceedings of the 3rd International Symposium on Foundations of Quantum Mechanics, Tokyo, 354-368.

Bostrom, N. (2003). "Are you living in a computer simulation?" Philosophical Quarterly, 53(211), 243-255.

Fredkin, E. (2003). "An introduction to digital physics." International Journal of Theoretical Physics, 42(2), 189-247.

Krausz, F., & Ivanov, M. (2009). "Attosecond physics." Reviews of Modern Physics, 81(1), 163-234.

Rovelli, C. (2004). Quantum Gravity. Cambridge University Press.

Lorentz, H. A. (1904). "Electromagnetic phenomena in a system moving with any velocity smaller than that of light." Proceedings of the Royal Netherlands Academy of Arts and Sciences, 6, 809–831.

Mattingly, D. (2005). "Modern tests of Lorentz invariance." Living Reviews in Relativity, 8(1), 5.

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Keywords

Digital Physics

Quantum Gravity

Information Theory

General Relativity

Lorentz Invariance Violation

Spacetime Quantization

Golden Ratio

Cosmic X-ray Background

Cosmology

Attosecond Physics

Quantum Superposition

Measurement Problem

pecial Relativity

Time Dilation

Discrete Spacetime

Computational Physics

EuroSciVoc

Physical cosmology

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Information Theory

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DOI

10.5281/zenodo.21273378

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Resource type<br>Preprint

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Copyright (C) 2026 Tomer Haimovich

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July 9, 2026

Modified

July 9, 2026

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