A Hybrid Zernike-Lyapunov Framework for Aberration-Based Statistical Wavefront Reconstruction of Chaotic Optical Surfaces

We present a comprehensive theoretical framework that unifies chaotic wavefront dynamics with classical aberration theory through a Statistical Wavefront Reconstruction Framework (SWRF) formalism. By establishing rigorous connections between ray trajectory deflections and wave-optical phase perturbations through the eikonal equation, we decompose chaotic wavefront perturbations into modified Zernike-Lyapunov hybrid expansions, establishing mathematical equivalences between Lyapunov exponents, fractal dimensions, and traditional aberration coefficients. This chaotic aberration theory enables systematic incorporation of non-integrable wavefront dynamics into deterministic design frameworks, providing a rigorous foundation for controlled chaos in optical systems. We derive analytical relationships connecting surface chaos parameters to optical performance metrics, demonstrate the framework's validity through phase space analysis, and establish convergence criteria for the chaotic expansion. The theory reveals how chaotic surface geometries can be intentionally designed to achieve specific optical functionalities, including beam homogenization, speckle reduction, and novel wavefront shaping capabilities, while maintaining mathematical rigor comparable to classical aberration analysis.