Temporal Shelter Hypothesis: Planck-Calibrated Operational Frames and Observer-Relative Readout

Abstract

Temporal Shelter Hypothesis: Planck-Calibrated Operational Frames and Observer-Relative Readout This paper introduces the Temporal Shelter Hypothesis, an operational framework exploring how long-lived biological and civilization histories can emerge under observer-relative temporal conditions. Unlike conventional cosmological models, the hypothesis does not claim that life resides inside ordinary black holes. Instead, it proposes that local proper-time accumulation can remain coherent in domains where external readout is systematically distorted by gravitational or phase-density environments. Key elements include: 1. Operational Frame Ladder: Using the electron Compton wavelength and Planck scale as calibration, the paper defines a frame-index hierarchy that quantifies observer-relative readout without invoking absolute or mystical scales. 2. Phase-Capacity Race Protocol: A normalized two-channel scheme (external progress share and internal recurrence share ) governs internal cycle rates, producing a Lorentz-like slowdown factor for the calibrated electron-Compton frame. 3. Exploratory Observational Anchors: Candidate domains include Type Ia supernova light-curve variations, reported log-periodic redshift structures, and potential low-amplitude signals in CMB and gravitational-wave data. These are presented as testable frameworks rather than established evidence. 4. Toy-Model and Mock Analysis: The paper demonstrates that weak, structured readout residuals can be operationally parameterized and recovered in controlled mock datasets, connecting the framework to measurable quantities. 5. Constrained Research Program: The framework emphasizes falsifiability, highlighting minimal observational constraints and clearly defining failure modes. It aims to provide quantitative, operationally motivated predictions without asserting a completed cosmological model. Overall, the Temporal Shelter Hypothesis serves as a conservative, observer-centric program for exploring time-dilation effects on long-lived systems, offering a structured path from conceptual framework to measurable predictions.

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