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NEWSCIENCENEWSCIENCENEWSCIENCE Some Foreseeable Applications Prototype Charged Barrier devices have been tested in video equipment to process composite video images for a higher resolu- tion. The device has the ability to process and separate the wave pairs and define the polarisation of light from background objects. This ability can produce a high-definition image on a CRT, and a near-holographic image on liquid crystal display (LCD) panels. The clarity of LCD panels can be greatly improved by the switching speed of the Charged Barrier technology, with the visual improvement sometimes being startling. translating electrons in that region, even though they are potentialised. That is, elec- tron transport has been halted temporarily or dramatically reduced, while the Poynting flow continues apace. With most electrons not being translated longitudinally, there is no heat build-up in the device as there is with lattice vibration inter- actions with a normal electron current. This device can work as a charge coupled device with the ability to pass both voltage and Poynting current flow, S, rather than con- duction electron current flow, dq/dt. we may compare the electromagnetic actions to the actions of a special kind of engine cycling, as shown in Figure 7. Figure 7 shows four analogous actions involved in the Fogal Engine. Figure 7A shows the start of the 'down stroke’, so to speak, of the Fogal emitter piston, and the formation of the DC electromagnetic field. Figure 7B shows the signal injection into the cylinder from the injector base region as the emitter piston pulls the signal into the cham- ber. Figure 7C shows the compression of electron density and the formation of the amplified E-field due to the charge compres- sion, with a resulting expansion of the Poynting energy density flow. Figure 7D shows the point of discharge of the Poynting energy density flow, the resulting AC super- current, and the collapse of the DC electro- magnetic field of the emitter piston. Change of Energy State Tantalum is one of the elements that is used in the construction of the Charged Barrier device, as well as the parallel resistor element. Under certain conditions, when stimulated with a very small electric current to align the charge state, the excess bleed-off effect due to the parallel resistor can move the charge state on the capacitor and develop a very small electromagnetic field. Electrons are 'held' and 'pinned' within this field to reduce electron lattice interaction within the emitter junction. With the influence of the AC conduction electrons reacting with the pinned electrons within the charged field, a unique effect will start to happen: the clusters of bound elec- trons within the charged field are compressed to a point where there is a change of energy state within the compressed, bound electrons in the tantalum lattice. This will start the for- mation of the E-field due to the interaction of the compressed electron clusters with the influence of the AC conduction electrons. Remember the magnets, when their like- poles were brought within close proximity to each other? An analogous action will start the formation of the AC supercurrent and the Poynting energy flow within the device. Encryption & Transmission Capability A preliminary test was constructed in Huntsville, Alabama, in May 1996, to deter- mine if video information could be infolded within a DC voltage potential and transmitted across a wired medium. Live video information at 30 frames per second was processed and converted by full wave rectification into a DC potential at a voltage of 1.6 v DC and connected to a twist- ed-pair wire medium of 2,000 feet in length. As a voltage, the 5 MHz video information rectified to DC potential had no modulation or AC signal present that could be detected by sensitive signal-processing equipment. The analog oscilloscopes that were used to monitor the transmission could only see the DC voltage flat line, although the best digital storage scope could see very weak signal residues because of slightly less than 100% filtering. I later performed additional tests with increased filtering, so that the residues could not be seen. These tests were constructed to see if video information could be 'infolded’ into an audio carrier and transmitted across an ELF frequency transmission source for communication with submarines, or down a 2,000-foot twisted wire pair. The Charged Barrier device was able to process the hidden video, due to the ability of Device Wave Function Though not in conventional theory, signal waves actually travel in wave pairs, each pair containing the familiar wave and an associat- ed ‘hidden’ antiwave. The two waves of the pair have the same frequency. Current semiconductor technolo- gy cannot separate these wave pairs due to limitations in switching time. The Charged Barrier device can switch at a sufficiently fast rate to: (i) separate the wave pairs at the higher requencies, and (ii) define the polarisation of light waves to show background imaging and enhanced video resolution. A pre-recorded audio or video tape can be processed to reveal hidden sounds or back- ground imaging that standard electronic equipment will not process. The device has been shown to process frequencies in the range from 20 Hz to 5 GHz and higher, with no loss in frequency response due to the abili- ty of the device to separate and process wave pairs and also due to faster device-switching. Charged Barrier Fogal Engine Putting together all the actions discussed, NEXUS 55 AUGUST - SEPTEMBER 1997