Beyond the Continuum: Fractal Quantization as a Replacement for "R"
Beyond the Continuum: Fractal Quantization as a Replacement for "R"
This paper presents a novel alternative to the classical real number continuum. Based on a cyclic and fractally quantized number space defined over the interval [0,11], the proposed model replaces uncountable cardinality with a countable, resonance-based structure. It eliminates the need for the Continuum Hypothesis and provides a coherent, information-preserving framework that may serve as a foundation for both mathematical and physical theories. The approach is fully deterministic, computable, and structured through prime-based difference sequences. The work is conceptually connected to the author’s earlier work on number space quantization through prime-difference sequences (“A New Perspective on Infinite Number Spaces through Prime Number Distances and Quantization” – DOI: 10.5281/zenodo.14853309), but it stands as an independent framework focused on black hole topology and symmetry dynamics.
continuum hypothesis, mathematical continuum critique, non-cantorian set theory, fractal quantization, cyclic number space, resonance-based topology, mathematical foundations, countable infinty, structured mathematics, computational number theory, discrete resonance, alternative numbersystems, prime number structure, real number replacement, quantized geometry
continuum hypothesis, mathematical continuum critique, non-cantorian set theory, fractal quantization, cyclic number space, resonance-based topology, mathematical foundations, countable infinty, structured mathematics, computational number theory, discrete resonance, alternative numbersystems, prime number structure, real number replacement, quantized geometry
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