Abstract
Human cerebral systems are immersed in the earth’s magnetic field. To be consistent with the results of several correlational studies, we found that the most accurate detection of information at 50 m occurred when the geomagnetic activity was ~5 nT. The corresponding magnetic energy within the cerebral volume is equivalent to approximately 3 million bits of Landauer Limit quantum which is equivalent to low resolution photographs. Non-linear analyses indicated that the induced electric fields from the typical time variation of geomagnetic intensity converged with the Adey voltages for the threshold for background entropy. The relevance of signal/noise ratios and the recent evidence indicate that imagery and cognition may actually reflect fields of biophotons within a fixed volume, which indicates that a natural processing system may be occurring under very specific conditions that involves detection of recondite information at a distance.
Highlights
Of the myriad of physical events that penetrate cerebral space per second only an extremely small subset appear to evoke intracerebral changes that result in measureable responses [1]
Non-linear analyses indicated that the induced electric fields from the typical time variation of geomagnetic intensity converged with the Adey voltages for the threshold for background entropy
The quantitative changes represented by these cerebral cortical indicators are in the same order of magnitude as the energy density within the cerebral volume associated with geomagnetic activity [3,4] which is within the range of tens of nanoTeslas
Summary
Of the myriad of physical events that penetrate cerebral space per second only an extremely small subset appear to evoke intracerebral changes that result in measureable responses [1]. That the human brain under specific conditions could discern the spatial and emotional information within distal stimuli was investigated from the engineering perspective of signal and information processing by Puthoff and Targ [9] at Stanford Research Institute during the 1970s Over several years they found that some subjects could draw distant objects of which the experients were unaware and that these drawings. Persinger and Krippner [11], employing the concept of signal/noise ratios for qualitative information processing found that the accuracy for the detection of distal stimuli was most conspicuous during days or nights when the global geomagnetic was most quiet at the time of the experience In this instance the strongest congruence between the drawings or descriptions and the actual stimuli occurred when the global geomagnetic activity, as inferred by the aa (average antipodal) index, was less than ~10 nT and more likely within about the 5 nT range. As a component of our study of global, natural information systems, we present quantitative evidence by calculation and experimental evidence that the human brain has the capacity to detect information at a distance and that the process is most accurate when there is a narrow band of geomagnetic activity that matches the physical chemical restraints [13] that define the boundaries of brain activity
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