The Hodge Conjecture, a Millennium Prize Problem, 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. In this paper, we propose a revolutionary solution via Rough Operator Algebra (ROA). We redefine Hodge classes not as smooth differential forms, but as elements of a Rough Current Space D'_α (X) with a roughness index α. We define algebraic cycles not as static intersections of polynomials, but as the unique 'topological condensates' formed when the roughness of space transitions from quantum stochasticity (α = 1/2) to classical smoothness (α = 1). This proves that the algebraic structure of the universe is an inevitable consequence of Roughness Symmetry Breaking. By introducing the Sunggil Criterion, we show that the integrality of the Lelong number is akin to a quantization effect stabilizing the geometry against roughness fluctuations. This work completes the "Grand Unified Mathematics, " demonstrating that geometry, information, and matter are different phases of the same Roughness Spectrum.
Lee Sung-gil (Fri,) studied this question.