Quantity-Dependent Bulk-to-Wall Observability of Surface Loading in Rarefied Hypersonic Flow over Triangular Protrusions

Abstract

Localized protrusions on hypersonic vehicles generate pressure, heat-transfer, and shear loads whose rarefied response can depend on gas beyond the immediate wall neighborhood. This work quantifies that bulk-to-wall dependence for triangular protrusions and tests whether coordinate-conditioned surrogates preserve it. Geometry-consistent surrogates are trained for direct simulation Monte Carlo (DSMC) velocity, temperature, pressure, and wall-load profiles over Mach numbers 4--8, Knudsen numbers (Kn) 0.1--0.8, and three protrusion orientations. The central analysis is performed on raw DSMC fields. Around each wall point, circular neighborhoods of increasing radius are summarized by weighted statistics, extrema, nearest-point values, and tangent-normal gradients of velocity, temperature, and pressure. A fixed region-to-point diagnostic predicts the pressure coefficient (Cp), heat-transfer coefficient (Cq), and shear-stress magnitude (|τ|). We define R95 as the smallest tested radius whose complete wall-profile error lies within 5\% of the full-domain descriptor error. The principal physical result is that rarefied surface loading has no single information length. Full-domain descriptors reduce errors from 45.5\% to 13.8\% for Cp and from 72.6\% to 12.9\% for Cq, whereas shear improves only from 49.1\% to 31.9\%. Heat transfer exhibits the clearest order-hs nonlocal support, where hs is the protrusion-base length. Pressure is frequently right-censored beyond 3hs, and shear saturates at shorter radii but remains least identifiable. Ridge-regression and threshold controls preserve this hierarchy, while a closed-loop audit shows partial surrogate preservation, with the largest degradation in forward-facing heat transfer and shear.