METHOD AND SYSTEM OF A MACROSCOPIC PERIMETER SCANNING BEAM LOCATING UP TO SIX DIFFERENT DISTINGUISHABLE MATERIAL STRUCTURES
The modifications mentioned below relate
to method and application in an autonomous energy development, system form
portable lightweight macroscopically distance of more than
With the modifications described in this document to identify the specific material structure is scanned each time by electromagnetic waves emitted by an appropriate pulse detection system material structures, it is now feasible to the operator not only to timely demonstration of the exact direction of the position of by antennas of the device (86) and moving the handle of the direction this show, but from the indications given special light type LED (79) and a special compass (110) placed in the upper part of the device ( 2). The LED lamp receives data from the microprocessor which separates including the returned signals from the physical structure and is built into the digital electronic circuit generator (84).
The research material structure can be assisted by information provided in appropriate digital liquid crystal display (88) and provided by special design and manufacture electronic spectrometer analysis of electromagnetic wave, which is treated with a suitable electronic circuit elements taken returned from electromagnetic waves, when a node between the magnetic material and device structure. In this digital screen the user can see the name of the physical structure and investigates how strong the magnetic field creates interacting but his device.
The improved these modifications system - visual device perimeter beam scanning to identify discrete material structures can now also works with specially designed digital pulse (84), unlike the original that worked with analog pulse, exploiting all the advantages of modern digital logic design. By applying the digital encoder is possible presets than six discrete material structures for tracking. This can be done by placing in the upper part of the device (1) special keyboard (80) with the use of which can be inserted very large number of frequencies that are already preset, one for each distinct physical structure, using special keys (87). In the above case is not required to have manual scale (9) for the activation of each of the six modules (7).
A final modification is the use of a further antenna (71), which is encapsulated in a special cylindrical (78) transducer, which in turn fits within the handle (72) of the device (1). This antenna is a straightener electromagnetic spectrum and its role is both to collect the transmitted signals from the encoder (19) to the objective (physical structure), not allowing them to diffuse in the opposite direction and also the concentration of the returned the physical structure of electromagnetic signals (20) and their direction to the receiving antennas of the device. The guide is creating unique oscillating magnetic field (101) which is coordinated with the magnetic field (97) that generates the operator of the device (102), interacting with the earth's magnetic field (103), also known as the phenomenon of
Another magnetic (96) field (horizontal (22)) is generated by the horizontal movement of the antenna (15) of the device (1) and that they interact with the magnetic field of the earth, in the same manner as above. The latter magnetic field is perpendicular to the other two previous fields, and the magnetic field of the earth (103). These magnetic fields depend on the distance of the system 'device - user - material structure' from the equator of the earth (or the magnetic poles, depending on the chosen as a reference point) which is the center of the magnetic field. This distance is known to vary considerably the speed of photons is responsible for the creation of magnetic fields, which are generated in turn due to the motion of the electrons of the elements involved in the above system. As a natural consequence, therefore the distance of the system 'device - user - material structure' of the equator and the magnetic poles of the earth (ie whatever benchmark you put it) inevitably lead to significant differences in the above-generated magnetic fields and various interactions. The resulting problem is solved by the in-situ adjust the output volume of the emitted electromagnetic waves from the pulser device, made as described by the mechanical selector (11) the change in the intensity of the transmitted signal output of the device.
The resultant force of the two magnetic fields, that of the human (97) and that the guide (101), in relation to the corresponding component (93) of the magnetic field (96) caused by the movement of the three horizontal antennas (86) interacts the component of the particular magnetic field (98) which causes the 'bombardment' of the electromagnetic waves emitted by the device (1) to identify the physical structure (18), creating the phenomenon of magnetic resonance. According to this phenomenon is the single human system (102) - director (71) - master antenna (15) of the device behaves like a magnetic pole thinkable an invisible magnet. The magnetic field (98) formed around the material structure (18) due to the creation of photons as a result of the change in kinetic energy of the electrons of the same material structure of the continuous collision photons coming from exogenous factors and particularly by the electromagnetic waves incident to the physical structure emitted continuously from the pulser device behaves like other conceivable magnetic pole, an invisible magnet. As a result, the whole system - model: man - machine - physical structure, it behaves like a single magnet, the long axis of which lies on the imaginary straight (22), having dynamic magnetic lines (106) and forcing the central antenna (15 ) of the device to always follow the strongest (105) field lines this peculiar field - model thus generated magnetic junction (Figure 17), the field lines which constantly pull the main dish (15) of the device, directing this species compass continuously to the material structure (18) as long as the 'bombardment' of material structure with photons that are continuously conveyed from the electromagnetic spectrum that causes the encoder of the device.
This composite model of the five magnetic
fields involved in the creation and playback of that experiment are shown in
plain magnet species in Figure 18. Obviously, the direction of the long axis
(22) of the magnetic field (106) formed in sensed physical structure (18) with
the 'bombardment' of the electromagnetic waves of the device is not constant
and depends on the texture, the kinetics position, shape, position each time in
space to the emitting device and data peculiar magnetic field of the earth
The above described changes described above are designed to optimize the performance of both the method and the device and actually improved the range and accuracy. Recently identified physical structure near the equator of the earth from a distance of more than eight kilometers.
In conclusion, the improvement of the method 'to identify six different discrete material structures using macroscopic perimeter beam scanning' is both the addition of the directional antenna (71) and the creation of an additional magnetic field (101) that acts, as stated above, 'auxiliary 'the strengthening of an invisible magnetic pole junction between material structure and the human - device, and use digital encoder which gives the method theoretically can detect infinite number of discrete material structures.
Correspondingly improved device (1) developed as an application of the above method consists in adding the directional antenna (71), in a digital encoder (84), a special type indicator LED (79), specific compass (110), keyboard (80 ) for introducing very large number of preset frequencies (discrete material structures), using improved special electronic circuit has a digital microprocessor capability, including analysis of the returned signals from the physical structure and their representation in a digital liquid crystal display (88) . All these integratable device (1) add this feature, theoretically forever, tracking not only six but theoretically infinite number of discrete material structures. The detection device material structures developed by applying the above described improved process incorporated in a portable, lightweight device (1) which handle a comfortable and effortlessly, holding with one hand on the chest of, differing with respect to originally planned for the device architecture:
1. In a digital encoder (digital frequency generator) (84).
2. In addition directional antenna (71), which is encapsulated in a special chamber (78) present in the handle (72) of the device (1).
3. In addition improved electronic circuitry now has digital microprocessor (84).
4. In addition keypad (80) for introducing theoretically infinite number of preset frequencies. In each frequency corresponds exactly a discrete physical structure.
5. In addition special LED type LED (79), and a special compass (110) constantly focused on physical structure once it is identified, following the lines of force of the magnetic field coordination.
6. In addition subsystem data representation using a digital liquid crystal display (88), in which the operator reads the data from the device emitted electromagnetic spectrum of the returned data from the physical structure electromagnetic spectrum, the type of material structure investigating each and any other supporting information environment.
In each case the operation of the apparatus does not differ much from the originally designed device. The following describes the changes in the invention, both brief and detailed explanation of the accompanying drawings, by way of examples.
Briefly Figures 1 to 6 illustrate the subsystem of directional antenna and providing encapsulation of the handle of the portable device, while the corresponding 8 to 12 illustrate other modifications to the device. Figures 13 and 14 illustrate how the device with the addition of the collimator, while in Figures 15 to 18 describes the creation of magnetic fields and the magnetic node.
In detail in Figures 1 and 2 shows the antenna - straightener (71) electromagnetic spectrum. Distinguished by the head (66), the shank of (67), the points of support of the upper (68) and lower (69) portion of the casing of the device (1) with the corresponding upper (85) and lower (70) washers adjustment.
In Figures 3 and 4 illustrating the handle (72) of the device with internal vacuum (73) of. In this gap (73) fits a peripheral (78) converter, into which fixed antenna (71) Collimating electromagnetic spectrum. Also distinguished by the head of the adaptive system (77) of the handle to the body of the device, the portion (76) adapted to the specific cylindrical (78) adapter, the fixedly mounted bearing (75) which gives the shell of the device the ability to move on the handle and thus on the horizontal axis and the four holes (74) on which are placed corresponding screws for adjustment of the shell of the device.
Figures 5 and 6 show in more detail the way of adjusting the collimator (71) within the specific cylindrical (78) of the handle adapter (72) and the type of mounting base (77) of the handle to the body of the device.
In Figure 7 there is the general plan of the plastic shell which encapsulates the device (1) with the raised portion (2) and its dimensions, length (82) approximately
Figure 8 details distinguished from the inside of the plastic shell which encapsulates the device (1). It appears the kit (84) encapsulating between other electronic circuits to the subsystems of the digital encoder (digital frequency generator) and an improved electronic circuit with digital microprocessor with the other subsystems as presented in the original device. Also distinguished upper the box , the bore (85) which passes from the straightener (71), the adaptive system (77) of the handle, the subsystem of the three antennae (86) and the specific type indicator LED (79) . Connection point on the handle there is a suitable cutoff filter cosmic rays. also distinguished the special options (17) ON - OFF and plastic knob (12) on and off the device, like the engineer selector (11) fluctuation of the intensity of the emitted signal output of the device.
Figure 9 find in the bottom of the plastic shell which encapsulates the device (1) to the base (77) of the handle and the three horizontal antennas (14, 15 and 16) of the device.
Figure 10 is a top view representation of the data subsystem, consisting of the keyboard (80) with twelve keys (87) to introduce theoretically infinite number of preset frequencies (discrete material structures) and digital LCD screen (88).
In figure 11 some details distinguished from the inside of the plastic shell which encapsulates the device (1), similar to the figure 8, with further details of the tray two rechargeable batteries (89) 9 Volt voltage each, the electronic control circuit charge ( 90) of the battery and its output (91) which fits in the charger.
Figure 12 find in some detail the apparatus, with the inside of the plastic shell which encapsulates the device (1) which are divided off from the details of Figures 8 and 11, the way to adapt the guide (71) within the specific cylindrical ( 78) of the handle adapter (72) and the type of mounting base (77) of the handle to the body of the device, adjusting the four screws (92). Most of the guide (71) distinguished the three horizontal antennas of the device, subsystem twins extreme metal antenna broad beam scanning, ie the left (14) and right (16) and the central antenna (15). It seems finally the keyboard (80), a digital liquid crystal display (88) and the special compass (110).
In Figure 13 is shown in side sectional view the device (1) by the subsystem of twins extreme metal antennas wide scanning beam (14) and (16) to emit electromagnetic waves (19) in horizontal direction (22) to which the user searches. Distinguish the component (93) of the long axis (22) of the horizontal magnetic field generated by the horizontal movement of the antennae and the long axis of the magnetic field (101) that generates the pulse straightener (66). The special LED type LED (79) is lit (92) because the range of the device has been detected to identify physical structure (18).
In Figure 14 find in plan a part of said transmitted signals from the device (19) emitted in (22) where the material structure (18). Once the returned signals from the physical structure (18) return the antenna system automatically and without user intervention directed (28) on the horizontal axis and moves in the direction (24) of material structure. The central antenna (15) is conducted to a new location (24) line in the direction of the material structure to detect and entraining the entire apparatus to move accordingly.
In figure 15 is shown the magnetic (96) field generated (97) by the horizontal movement of the antenna (15) of the device (1). Shown is the movement (95) of the arm (94) of the user to create the field.
Figure 16 depict the phenomenon of magnetic resonance. The guide (71) oscillate creating special magnetic field (101) which is coordinated (100) with the magnetic field (97) generated by the operator of the device (102), interacting with the magnetic field (103) of the earth (99), known as global HALL. Another horizontal (22) magnetic field (96), parallel to the horizontal plane of the earth (104) is created by the horizontal movement of the antenna (15) of the device (1) and that they interact with the magnetic field of the earth, with same manner as above. The latter magnetic field is perpendicular to the other two, past fields and the magnetic field of the earth (103). The resultant of the two magnetic fields, human (97) and the guide (101), coordinated with the magnetic field (96) caused by the movement of the three horizontal antennas (15) and the entire system (consisting of) interacts with the special magnetic field (98) which causes the 'bombardment' of the electromagnetic waves emitted by the device (1) to identify the physical structure (18) creating the phenomenon of magnetic resonance.
The phenomenon of the magnetic node and magnetic resonance represented in a simple form of a magnet in Figure 17. The single human system (102) - director (1) - master antenna (15) of the device creates an invisible magnetic pole (108) while the physical structure (18) another imaginary magnetic pole (109), an invisible magnet. The long axis lies on the imaginary straight (22), forming a powerful magnetic field lines (106) and forcing the central antenna (15) of the device always follow the strongest (105) field lines of this peculiar field, which pulls constantly directing the central antenna (15) of the device types compass always to the physical structure (18) as long as the emission of electromagnetic waves from the pulser (bombardment with photons) of the device.
Finally the five magnetic fields interact and are involved in the creation of the magnetic hub (magnetic resonance) represented in plain magnet for each magnetic field, in Figure 18.
1. Method macroscopic perimeter beam scanning tracking up to six different
discrete material structures using electromagnetic waves emitted continuously
characteristics for specific, predetermined physical structure researched and
produced by electrical part of a broader microelectronic system, angle 360 ° horizontal earthly
level, scanning radius greater than
2. Independent energy device in which Method macroscopic perimeter beam scanning to identify six distinct different material structures, operating with common rechargeable batteries voltage 18 Volt (89), consisting of plastic casing (1) hexahedral shape with raised and sloped front section ( 2), of which is in contact with a plastic cylindrical axis, called 'rotating axis detection' (72) at the point of equilibrium of the axis plane of hexahedral situated towards the ground as the device is normally held by the user, having capability inertial motion in earth gravity environment or similar environment having the same features as the gravitational earth (99), at an angle of 360 degrees in the horizontal plane, showing minimal friction at the interface due to the existence of special design bearings (75). The plastic housing (1) housing types that encapsulate microelectronic real time system, which together with other quorum device gives this capability to detect and identify macroscopic distances of more than
METHOD AND SYSTEM OF A MACROSCOPIC PERIMETER SCANNING BEAM LOCATING UP TO SIX DIFFERENT DISTINGUISHABLE MATERIAL STRUCTURES
Improved method macroscopic perimeter beam scanning and tracking material structures with discrete electromagnetic spectrum emission characteristics that scans 360 degrees in a field in the earth horizontal plane, and beam scanning range of more than