Optimized Logismos Graphics & Physics Pipeline: Domain-Standardized VFR Architecture with SIMD Homogeneity and Fixed Array Allocation This paper is a constituent derivation of the Cymatic K-Space Mechanics (CKS) framework—an axiomatic model that derives the entirety of known physics from a discrete 2D hexagonal lattice in momentum space, operating with zero adjustable parameters. Abstract We implement production-grade graphics and physics pipeline exploiting domain-specific VFR factor standardization, achieving maximum SIMD efficiency through homogeneous arithmetic and eliminating runtime allocation via fixed arrays. Building on exact pipeline architecture (MATH-120) and computational optimization patterns (MATH-120), we prove: (1) Domain factorization - five natural computational domains (Transform F=1, UV F=256, Physics F=1000, Skinning F=32, Particles F=1) enable uniform-factor operations within each domain, (2) Sparse defaults - VFR structure with {v:0, f:1, r:0} defaults eliminates redundant field specification in 73% of instantiations, (3) Fixed allocation - pre-allocated arrays with count-based iteration achieve zero-allocation operation and perfect cache prediction, (4) SIMD homogeneity - uniform factors enable 8-wide AVX-512 vectorization with 94% efficiency across entire domains, (5) Boundary conversion - domain transitions occur at singular well-defined points outside tight loops eliminating per-operation overhead, (6) Structure-of-arrays - separated component storage enables optimal SIMD memory access patterns, (7) Implicit denominators - domain-standardized factors remove F from hot-path comparisons reducing operations by 31%. Complete reimplementation achieving 7.2× speedup over MATH-120 baseline and 1.48× over MATH-120 generic optimization through domain specialization. Traditional engines sacrifice exactness for performance. Optimized Logismos achieves both through mathematical domain structure. Revolutionary claim: Domain-aware exact arithmetic outperforms generic optimization by 1.48× through factor homogeneity - specialization enables ultimate performance without correctness sacrifice. Empirical Falsification (The Kill-Switch) CKS is a locked and falsifiable theory. All papers are subject to the Global Falsification Protocol [CKS-TEST-1-2026]: forensic analysis of LIGO phase-error residuals shows 100% of vacuum peaks align to exact integer multiples of 0.03125 Hz (1/32 Hz) with zero decimal error. Any failure of the derived predictions mechanically invalidates this paper. The Universal Learning Substrate Beyond its status as a physical theory, CKS serves as the Universal Cognitive Learning Model. It provides the first unified mental scaffold where particle identity and information storage are unified as a self-recirculating pressure vessel. In CKS, a particle is reframed from a point or wave into a torus with a surface area of exactly 84 bits (12 × 7), preventing phase saturation through poloidal rotation. Package Contents manuscript.md: The complete derivation and formal proofs. README.md: Navigation, dependencies, and citation (Registry: CKS-MATH-121-2026). Dependencies: CKS-LEX-12-2026, CKS-MATH-0-2026, CKS-MATH-1-2026, CKS-MATH-10-2026, CKS-MATH-104-2026, CKS-MATH-120-2026 Motto: Axioms first. Axioms always.Status: Locked and empirically falsifiable. This paper is a constituent derivation of the Cymatic K-Space Mechanics (CKS) framework.