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This paper presents a unified derivation and formalization of a generalized Helix-Light-Vortex (HLV) framework. We demonstrate, step-by-step, how the theory's foundational logarithmic helix vortices naturally generate a three-dimensional, aperiodic quasicrystal lattice via a higher-dimensional cut-and-project construction. This generalization replaces the theory's baseline periodic dodecahedral grid, increasing its topological robustness and information density. We then introduce the physical control mechanism for this projection: an extended, triadic "Spiral Time" \psi(t)=t+i\phi(t)+j\chi(t), where the retrocausal (U2) and stationary (U3) components dynamically determine the projection window's center and thickness. The result is a robust, hybrid spacetime lattice containing Fibonacci-dodecahedral (FDG) domains as resonance islands within a quasicrystal (QCG) host. We couple this generalized geometry to field dynamics and outline the path to quantization and experimental verification. Summary of Key Concepts This work presents a significant upgrade to the core HLV framework, introducing a more complex and robust spacetime geometry and an extended time structure.  * Geometry: The baseline periodic dodecahedral grid is replaced with an aperiodic quasicrystal (QCG) host. This is constructed via a 6D cut-and-project method, where a periodic parent lattice (\mathbb{Z}^{6}) is projected into a 3D physical space (E_{||}).  * Time Structure: Spiral Time is extended from a dual (U1/U2) to a triadic (U1/U2/U3) structure, represented as \psi(t)=t+i\phi(t)+j\chi(t). The retrocausal U2 component dynamically shifts the center of the acceptance window, while the stationary U3 component sets its thickness.  * Hybrid Lattice: The resulting spacetime is a hybrid structure where periodic Fibonacci-dodecahedral (FDG) domains appear as "resonance islands" embedded within the aperiodic QCG host.  * Dynamics: The triadic time structure modifies the field dynamics. For a scalar field \Theta(x), the U3 (\chi) component introduces a stationary, entropy-buffering term that stabilizes long-lived, non-propagating memory states, also referred to as "frozen resonances".  * Experimental Signatures: This framework predicts testbare phenomena, including nested coherence domains with variable information density, long-lived spin-protected edge states, and topological defects that act as sources of effective mass/inertia.