SX-Chaos: Full Lyapunov Spectrum Computation via SIMD Vectorization on Modern Hardware

The future of complex dynamic modeling and real-time computation lies at the edge, yet high-dimensional continuous systems have traditionally required costly, power-hungry HPC (High-Performance Computing) or datacenter infrastructure. Now, the SX-Chaos engine challenges this structural limitation. This repository demonstrates a fundamental algorithmic breakthrough: collapsing the traditional O (N²) computational bottleneck down to O (N). By coupling this architectural restructuring with aggressive, edge-native SIMD vectorization, we unlock dormant processing power in standard consumer hardware. The Result: Sub-second execution of 40-dimensional chaotic spectrums (processing 50, 000 integration steps) on a single consumer-grade mobile core. This achieves a performance-per-watt ratio that fundamentally disrupts traditional scaling models, making the marginal cost of this compute power almost free compared to renting datacenter instances. Market Implications: This establishes the viability of running complex, high-dimensional simulations directly on edge devices (smartphones, IoT arrays, autonomous systems, sensor networks) entirely offline. By eliminating recurring cloud compute costs and communication latency, real-time advanced modeling is now available anywhere. Explore the potential: Read the PiroloSXChaosPirolo₂026. pdf manuscript for comprehensive benchmarks, methodology, and empirical proof of the performance leap. Review the PiroloSXChaosL96Release. zip package for technical validation. Note: This public release is strictly governed by the PolyForm Noncommercial License 1. 0. 0. Industrial application, hardware synthesis (FPGA/ASIC), enterprise AI training, or commercial deployment requires a separate licensing agreement with the author.