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Abstract
Modern computational disciplines, including cryptography and machine learning, necessitate efficient methods for processing discrete probability distributions and large-scale combinatorial data. This paper presents the Combinatorial Geometric Series (CGS) as a methodological framework for deriving the Negative Binomial Theorem and its associated generating functions. By utilizing iterative summations of the basic geometric series, this approach provides closed-form expressions that map directly onto algorithmic loops, optimizing efficiency in cybersecurity and error-correction codes. This framework bridges the gap between pure combinatorial theory and applied computational science, offering a scalable foundation for high-dimensional data modeling.
