Oscillatory Framework of Information: A Physically Grounded Resolution to the Black Hole Information Paradox

This work proposes a novel, independently developed, physically grounded framework that reconstructs aspects of modern physics—quantum mechanics, thermodynamics, and relativity—from first principles rooted in information dynamics. Unlike traditional information-theoretic approaches dependent on holography, entanglement, or observer-centric models, this framework derives from logic-based axioms informed by signal behavior and coherence. It emphasizes physical consistency and empirical compatibility without reliance on speculative constructs such as postulated fields or hidden variables. Oscillation is proposed as the fundamental, irreducible structure capable of preserving and transmitting information through high-entropy environments, including black holes. Observation is modeled as an emergent phenomenon resulting from structured information exchange. Key physical constants, identity, and time are treated as derived from coherent informational processes. This framework uses only physically defined quantities (e.g., work in N·m, temperature in Kelvin) and does not aim to replace empirical physics but to offer a logically rigorous view of information persistence under gravitational and thermodynamic extremes. All conclusions align with known physical laws and derive from logical inference based on accepted thermodynamic and quantum principles.