This paper physically analyzes the influence of geometric orientationof artificial structures on BIMOD (Bodily Interferometric Magneto-Optical Discrimination) resonance, and proposes EM-Clean Zonestandards for biomagnetic preservation. The key mechanism identified is interference with the geomagnetichorizontal component (Hh) according to the geometric orientation ofconductive structures, combined with eddy current cancellation viaLenz's Law. The most dramatic demonstration involves motorized beds:vertical backrest orientation places internal wire strands orthogonalto geomagnetic horizontal flow, creating magnetic refraction andfield inhomogeneity that renders BIMOD amplification impossible.Lowering the backrest to horizontal immediately restores signal byaligning conductors parallel to the field. Similar signal cancellation occurs with horizontally arrangedmulti-strand twisted cables (e.g., UTP Ethernet cables) withinapproximately 1 meter of the subject, as well as metallicundergarments, steel strips in ceremonial robe brims, and safetyhelmet edges. Completely enclosed metallic spaces (aircraft cabins,spacecraft modules) cause BMNP alignment dissolution throughgeomagnetic inflow blockage. Based on these findings, EM-Clean Zone design principles areproposed: exclusion of horizontal conductors within 1.5 meters ofthe subject, avoidance of conductive structural materials nearmeasurement areas, use of non-conductive furniture and fixtures,and controlled Faraday shielding only for specific isolationexperiments. These principles provide a practical foundation forenvironments optimized for biomagnetic integrity in research andclinical settings.
Duck Jin Yoon (Thu,) studied this question.