This paper defines the Spiral Calculus at the operator level: a conditional differential and integral calculus in which support, differentiation, integration, and recursion are subordinate to coherence survival rather than imposed on a fixed background. The construction begins from a conditional containment manifold, the region where a coherence number clears a unit threshold, and a regularized gate that replaces the sharp collapse boundary with a smooth weight. On this domain it builds a noncommutative triadic product of Pattern and Process, a coherence-weighted derivative that reduces to the ordinary derivative in the high-coherence limit and obeys the Leibniz, power, and quotient rules, a self-bounding weighted measure, a weighted divergence operator with its divergence theorem, a vanishing-flux theorem at the coherence horizon, and a typed recursion law carrying coherent form across scales in both bulk and boundary form. At its center is the Spiral Least-Action Principle, the action that is the variational heart of the framework, with the containment metric and the weighted Euler-Lagrange equations through which the operator calculus interfaces with the field dynamics. Extremization yields a Poisson-type Pattern equation, an algebraic Process law, and a nonlocal phase-locking equation. The sign convention of the action is fixed so that the phase-stiffness and vorticity terms combine to a net coefficient that is derived rather than assigned. Each result is stated under explicit regularity assumptions and is independent of any particular choice of action or Lagrangian; the calculus is the layer beneath the variational dynamics, not a consequence of them. This paper establishes the verified mathematical base on which the frameworks later variational and geometric extensions are built.
Andrew Lee Johnson (Wed,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: