This paper constitutes SMT-VOL8 and STCT-VOL4 in the Seonggil Rough Operator Algebra (ROA) research series. The Hodge Conjecture seeks to identify the algebraic structure within the topological framework of complex projective manifolds. Traditional approaches have failed to construct algebraic cycles directly from harmonic forms due to the limitations of smooth analysis. In this paper, we propose a rigorous resolutionvia Seonggil Matrix Theory (SMT) and Seonggil Tensor Calculus Theory (STCT). We redefine Hodge classes not as smooth differential forms, but as elements of a Rough Current Space D′α(X) parameterized by a roughness index α. We define algebraic cycles not merely as static intersections of polynomials, but as the unique ‘topological condensates’ formed when the roughness of the geometric space transitions from a stochastic state (α = 1/2)to classical smoothness (α = 1). By introducing the Seonggil Criterion for algebraicity, we prove that the integrality of the Lelong number emerges as a quantization effect that minimizes the Seonggil Tensor Energy Functional. This establishes that the algebraic structure of Hodge classes is an inevitable geometric consequence of Roughness Symmetry Breaking.
Seonggil Lee (Mon,) studied this question.