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NEWSCIENCENEWSCIENCENEWSCIENCE the device to sense the infolded AC electro- simply by processing the return image with __ reflections and disturbances in: magnetic wave information hidden inside the the Charged Barrier device for high-resolu- (i) sonar reflections, rectified DC voltage—sensed as a disruption tion CRTs and LCD panels. (ii) the Earth's magnetic field (and, in fact, to the internal DC electromagnetic field of Systems could also be improved for faster _ in the electric field between the surface of the the Charged Barrier device. targeting and return echo due to the optical _ Earth and the electrosphere), and I have since repeated the test with a better speed of the Charged Barrier device switch- (iii) in the ocean, in the overall subsurface build-up to eliminate the very weak signal ing. By utilising the ‘internal’ information, it — static potential formed by the conglomerate residues, and have found the effects are real should be possible to develop improved _ potentials of the hydrogen bonding, ionisa- and replicable. Use of the infolded EM imaging for sonar applications so there will _ tions, etc. waves in an ELF carrier for video frequency __ be no gaps in the frequency spectrum. These pinna signals are broadcast through signalling is real. The ability to get at and detect the hidden the surrounding normal fields/potentials of A novel effect uncovered in the Huntsville internal EM information of an object from its the Earth, including underneath the ocean, tests was that, by adjusting the gain control of _ surface reflection is an innate capability of although they are many dB below the normal the receiving box containing the Charged the Charged Barrier device that needs to be _ field fluctuations whose gradients are detect- Barrier device, the focused field of view of explored. It is already well known that the ed by normal sensors. By detecting this the fixed image could be varied, even though _ entire interior of a dielectric participates in _ ‘internal’ information, Charged Barrier detec- no adjustment at all was made in the video _ the reflection of light from it, and that the tors would be able to detect these hidden camera's stationary focusing. This showed information on the interior of the reflecting _ pinna signals and dramatically increase the that the ‘internal information’ in an image object is in the reflected image, but in the _ information available to the sensor system. actually contains everything needed to scan a __ form of hidden EM variables. Terrain-following cruise missiles, for fixed volume of space, forward and backward example, could be detected, tracked and iden- in radial distance, in a focused manner. Radar & Sonar Imaging Application tified by this means, as could submarines, The internal information seems to contain A new type of 'volume-viewing' radar sys- floating subsurface mines, etc. Field camou- information on the entire volume of view of tem can be constructed with the Charged _ flage and decoying would be essentially use- the camera. And it is possible to scan that Barrier technology, that can scan the inner _ less against such sensors. volume from a seemingly 'fixed' image, | EM signal image produced over a given area where much of the image is out of the cam- or volume and sense disruptions within the A New Revolution in Electronics era-focused field of view. The implications Earth's magnetic field. The Charged Barrier technology is an for photo analysis are obvious and profound. The movement through that volume of an innovation which calls for using the energy object (such as a low-flying aircraft made of _ flow in circuits that is already Charged Barrier Device Applications metal or epoxy resin skin design) can be (i) extracted from the vacuum flux, and Existing radar technology can be refined _ detected and tracked, regardless of electronic (ii) freely provided to the external circuit and improved with the Charged Barrier countermeasures and atmospheric disruptions _ by the source dipoles. device. One of the most complex problems (such as tornadoes, hurricanes, or windshear It utilises an extended electromagnetics in the industry is the noise content in signal due to microbursts), without the need for tar- _ that includes a higher topology and a new, processing. The Charged Barrier device can get echo return capability. The Charged inner, ‘hidden variable’ EM. This ‘inner EM! be used as a front-end, low-noise amplifier Barrier device can sense and amplify very _ has been in the literature for nearly a hundred and can increase the sensitivity of the target small disruptions to the internal electromag- _ years—but ignored. The use of the Charged signature scan capability. netic fields and create an image for identifi- | Barrier technology will expose many of the Radar imaging could be greatly improved cation. The volume can be scanned, in focus, _ present shortcomings in EM theory and mod- back and forth in dis- els, but it should also lead to a corrected, tance. highly extended electromagnetics. For sound direction Now that you know the theory behind how and distance sensing, _ this technology works, be aware that you still the pinna (small need the exact design parameters and compo- er > folds) of the outer ear _ nent tolerances in order to duplicate the tech- Ne use phase reflection nology. — f/ GE information more Let us hope that the Charged Barrier tech- A than 40 decibels nology can receive the full scientific atten- LiF —_ A below the primary _ tion, testing and theoretical modelling that it f evr sound signal that deserves. With that attention and examina- Sl §F strikes the eardrum. tion, I believe this technology will usher in a 2 : - a : SSS CL Y Ys ww . Any target Snon- new revolution in electronics. simply by processing the return image with the Charged Barrier device for high-resolu- tion CRTs and LCD panels. Systems could also be improved for faster targeting and return echo due to the optical speed of the Charged Barrier device switch- ing. By utilising the ‘internal’ information, it should be possible to develop improved imaging for sonar applications so there will be no gaps in the frequency spectrum. The ability to get at and detect the hidden internal EM information of an object from its surface reflection is an innate capability of the Charged Barrier device that needs to be explored. It is already well known that the entire interior of a dielectric participates in the reflection of light from it, and that the information on the interior of the reflecting object is in the reflected image, but in the form of hidden EM variables. reflections and disturbances in: (i) sonar reflections, (ii) the Earth's magnetic field (and, in fact, in the electric field between the surface of the Earth and the electrosphere), and (iii) in the ocean, in the overall subsurface static potential formed by the conglomerate potentials of the hydrogen bonding, ionisa- tions, etc. These pinna signals are broadcast through the surrounding normal fields/potentials of the Earth, including underneath the ocean, although they are many dB below the normal field fluctuations whose gradients are detect- ed by normal sensors. By detecting this ‘internal’ information, Charged Barrier detec- tors would be able to detect these hidden pinna signals and dramatically increase the information available to the sensor system. Terrain-following cruise missiles, for example, could be detected, tracked and iden- tified by this means, as could submarines, floating subsurface mines, etc. Field camou- flage and decoying would be essentially use- less against such sensors. Charged Barrier Device Applications Existing radar technology can be refined and improved with the Charged Barrier device. One of the most complex problems in the industry is the noise content in signal processing. The Charged Barrier device can be used as a front-end, low-noise amplifier and can increase the sensitivity of the target signature scan capability. Radar imaging could be greatly improved For further information, contact: Bill Fogal Charged Barrier Technology http://www.eskimo.com/~ghawk/ fogal_device/ 56 * NEXUS AUGUST - SEPTEMBER 1997