Sparse M\"untz--Sz\'asz Recovery for Boundary-Anchored Velocity Profiles: A Short-Record Roughness Diagnostic in Turbulence
Abstract
We present a sparse convex-relaxation framework for estimating effective local scaling exponents from short boundary-anchored velocity-increment profiles (N≈40). The detector solves an 1-regularized regression in a mixed M\"untz--Sz\'asz/Jacobi dictionary and is interpreted throughout as a finite-scale, directional roughness diagnostic rather than a pointwise H\"older exponent. On isotropic datasets from the Johns Hopkins Turbulence Database, an internal subsampling benchmark against N=200 detector labels gives F1≈0.93 across nine unweighted reruns, and a balanced synthetic control gives balanced accuracy 0.928 at N=40, indicating useful short-record self-consistency without constituting an external calibration. Across Reλ≈433--1300, the fixed-window sharp fraction remains of order 30--50\%, but a scale-normalized control does not isolate a clean Reynolds-number trend. The recovered α is only weakly associated with dissipation, whereas higher vorticity is consistently associated with smaller detected roughness exponents in conditioned samples. Directional controls on 60 high-vorticity centers further show a positive vorticity-aligned contrast α (mean 0.093, bootstrap 95\% CI [0.028,0.158]), stronger on the true vorticity axis than on fake axes, together with a statistically detectable low-order quadrupolar component in a joint Legendre fit. A seeded scale-transfer scan shows positive α at both the smallest and largest tested radii, supporting finite-range persistence without a strong theorem-level nonlocal claim. The method is therefore best viewed as a finite-scale geometric diagnostic complementary to energetic observables, capable of resolving directional structure and low-order anisotropic organization in high-vorticity regions.
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