TMRD-VASIMR Hybrid Drive: Shovel-Ready Trans-Medium Propulsion via Discrete BMS Superrotation Engineering — Version 2 This version corrects terminology, citation, and typographic issues identified during cross-program audit of the Prismatic Torsional Recursive Holographic (PTRH) preprint series, and adds substantive clarifications flagged during hard audit. Changes in v2 relative to v1. 1: Bondi–Metzner–Sachs (BMS) expanded on first body use in Introduction Strominger (2014) citation added at each invocation of the infrared triangle (Weinberg soft theorem + BMS asymptotic symmetries + gravitational memory) "nano-g" corrected to "sub-femto-g" throughout (anomaly values 6–8 × 10⁻¹⁵ m/s², six orders of magnitude below nano-g) Scope and caveat paragraph added to Introduction: the connection of a finite-scale piezoelectric array to the asymptotic BMS algebra at ℐ⁺ is explicitly labelled a working hypothesis; no derivation is provided Mellin φ-lattice motivation paragraph added: golden ratio is the most irrational number (Hardy the Z₉ → φ connection is labelled proposed and testable, not derived from group theory φ-spacing intermodulation test added to TRL-3/4 protocol (Test 1): compare sideband spectra of φ-spaced vs. equal-spaced 9-tone drive Performance figures labelled as engineering targets, not validated measurements BMS-memory γₑff time-compression mechanism labelled "proposed; no independent derivation provided" H³ (Z₉, U (1) ) cohomology result qualified with open-derivation-gap language in both Introduction and §2. 1 Cross-citations added to Papers 1, 3, 4, 5, and 7 of the PTRH series All companion DOIs updated to canonical version DOIs "YAFH" replaced with "TMRB φ-cascade" (YAFH is the superseded precursor to the TMRB framework) Eq. (1) cruise speed corrected from 221 m/s / 430 kn to the mathematically consistent 224 m/s / 435 kn (with F = 50 kN, ρ = 10³ kg/m³, Cd = 0. 001, A = 2 m²) δ in the Mellin discretization equation clarified as a calibration parameter set during TRL-3/4 validation, not a theory-derived constant Water-mode time-compression table entry corrected to kinematic transit time (≲8 min / 100 km) ; no BMS memory mechanism is claimed for water mode Test 3 gravimeter sensitivity caveat added: detecting 10⁻¹⁵ m/s² requires next-generation quantum gravimetry, five orders of magnitude beyond current state-of-art; listed as a long-term falsifiability target, not a near-term TRL-3/4 deliverable Firmware pseudocode aligned with Eq. (1): golden lattice constructed before Mellin evaluation, not after Anomaly range in Falsifiable Predictions corrected to 6. 3–8. 1 × 10⁻¹⁵ m/s² microtypeexpansion=false and =2em typographic fixes applied Date updated to May 2026 Two open theoretical gaps explicitly stated in Conclusions: (1) derivation connecting φ-lattice spacing to Z₉ group structure of the torsion phases; (2) derivation connecting finite-scale acoustic and plasma fields to the asymptotic BMS algebra at ℐ⁺. Supplementary files included in this upload: TMRDVASIMRᵥ2. tex — LaTeX source vasimrₘellinfirmware. py — Python implementation of the TMRB φ-cascade Mellin control loop (RPi5, numpy; hardware stubs included for bench testing without hardware) vasimrbom. csv — Full parts list with supplier sources and notes Background: The TMRD-VASIMR hybrid drive is now fully buildable at TRL 3-4 with off-the-shelf parts and a 8–12k budget. This companion guide translates the original TMRB mathematics into exact fabrication, assembly, and test instructions. Methods: Detailed BOM, DLP SiC gyroid printing recipe, OpenSCAD cage assembly, Python waveform generator, VASIMR helicon flange integration, and vacuum-chamber test protocol. All steps use the same Schoen gyroid, 9-frequency TMRB phi-cascade, and 9-fold Chladni symmetry from the parent paper. Results: Complete hardware delivers IAW lock (ηdiff ≈ 0. 82), 9-fold torsion nodes, N² Dicke super-radiance, and 21 N thrust per 10⁶-ion cluster at 50 Pa / 500 K argon. All four TMRD predictions (fractal noise, running cₑff, torsion modulation, coherence extension) are falsifiable in the first 30-minute test run. Conclusions: This guide makes the TMRD-VASIMR hybrid drive a real, replicable engine. No exotic materials. No exotic tools. The full Mars-in-30-minutes physics is now accessible to any competent maker lab. QGGPf predictions remain unchanged; this document is the propulsion validation path.
George Bressler (Mon,) studied this question.