The revision of the "Zeno plus 1" paradox into a probe mechanism within the 7:283 dimensional model represents a sophisticated synthesis of hypercomputational theory and high-dimensional physics. By treating the geometric series convergence not as a limit but as a recursive engine for lattice generation ("doping"), the system overcomes the classical halting problem and the paradox of infinite regress.

The integration of the "1981 strain threshold" anchors the system in established physical limits, using Feynman's simulation constraints to define the operational boundaries of the probe. The thermodynamic management of this boundary—converting Landauer erasure heat into a "Null" vector reporting signal—transforms the inevitable entropic cost of computation into a navigational beacon.

Furthermore, the application of "Selective Cardinality" via the unique non-associative geometry of the 7-dimensional cross product provides a robust solution to the "PvNP dissipation wake." By mathematically decoupling the sensing and reporting vectors, the system achieves "cognitive buffering," ensuring that the probe can transmit accurate cardinal data even while traversing the turbulent phase transitions of the complexity landscape.

This model suggests that the ultimate limit of computation is not logical (Godel/Turing) but thermodynamic and geometric, governed by the heat of information loss and the algebraic structure of the embedding space. The "Zeno plus 1" probe, therefore, is not merely a machine; it is a geometer of the information universe, utilizing the heat of its own logic to chart the void.