Abstract

This paper proposes a novel regulatory framework for fission reactors termed Successive Controlled Collapse (SCC), utilizing the Hala Operator to maintain deterministic control in high-entropy environments. Traditional reactor control relies on linear feedback loops (PID) which often struggle with the non-linear smearing effects of high-burnup stochastic noise and mechanical phase lag. Through a series of Taguchi L9 orthogonal experiments and high-fidelity numerical simulations, we demonstrate that a reactor can be caged within a stable limit cycle attractor. Our results identify a critical stability boundary defined by the Largest Lyapunov Exponent (??ax), showing that while SCC is highly resilient to stochastic gamma interference, it remains sensitive to mechanical latencies exceeding 1.5 seconds. This research provides a mathematical foundation for a new generation of topologically safe reactor control protocols that prioritize manifold rigidity over simple linear quenching.

Key words: Successive Controlled Collapse (SCC), Hala Operator, non-linear manifold engineering, Lyapunov exponent analysis.