Spatiotemporal ϕ/π Scaling: A Framework for Gravitational, Quantum, and Causal Influence

This thesis introduces a framework for understanding the propagation of gravitational waves and the geometry of spacetime, grounded in the scaling behavior of spatiotemporal influences governed by the golden ratio ϕ and π. By integrating these fundamental constants into the fabric of gravitational and quantum fields, we propose a unified theory that links General Relativity, Quantum Mechanics, and causal feedback through a new interpretation of spatiotemporal influence zones, gravitationalholographs, and nonlinear wave propagation. Specifically, we investigate the role of ϕ in nonlinear causality and retrocausal feedback loops, and the function of π in harmonic oscillations and the scaling of spacetime curvature. The theoretical framework is supported by empirical data from gravitational wave observatories (e.g., GWOSC), where waveforms are analyzed for consistency with predicted scaling behaviors. We used GWOSC data to analyze gravitational waveforms, comparing observed signals with predicted patterns from CIT scaling framework. The consistency of observed waveforms with the expected nonlinear propagation and non-local feedback behaviors pointed as strong empirical evidence for the theory. Virgo’s data was used to further test the theoretical framework’s predictions on gravitational waves, by cross-referencing data from multiple observatories. Supplying a robust test of non-locality and retrocausality in the context of spacetime curvature and wave propagation. LIGO data allows us to check if the nonlinear oscillations predicted by the framework, as well as causal feedback loops, are consistent with real-world observations. The waveform fitting performed on LIGO data can be compared with the predictions from scaling to validate the thesis. We also explore novel experimental approaches that could further test and validate this theory, particularly in the context of non-local quantum gravitational signatures and holographic baryon asymmetry.