RU2163419C1 - Data transmission system - Google Patents

Abstract

FIELD: communications engineering; wireless data transmission. SUBSTANCE: system has signal transmitter incorporating responding unit built up of spherical glass sensing elements rigidly fixed by means of adhesive to supporting member that also mounts spherical module made in the form of glass sphere wherein sensing elements in the form of identical crystal blocks are installed. Signal receiver is mounted at certain distance from transmitter and has responding unit and spherical module spaced apart from the latter. Both are similar to those of respective transmitter components. Spherical module is provided with beam-to-output-signal converter. Diameters of all sensing elements incorporated in either responding unit should differ, for example, gradually increase. During data transmission operator activates sensing elements of data transmitter. Then activated radiation is practically instantly reproduced in sensing elements of signal receiver and normalized by spherical-module sensing elements. Output normalized radiation is converted by means of sensor into electric signals and data transmitted is passed through processor to recording device. EFFECT: improved operating reliability and noise immunity of system. 6 cl, 4 dwg

Description

 The invention relates to the field of communication technology and can be used in information transmission systems that use wireless communication between a transmitter and a receiver of information, mainly when transmitting information over significant (thousands of kilometers) distances.

 Closest to the technical nature of the claimed one is an information transmission system comprising a transmitting unit including a support element on which signal transmitters are rigidly mounted, and a receiving unit remote from it, consisting of a support element with signal receivers and a radiation converting device rigidly fixed to it in the output signals (see RF patent N 2111617, CL H 04 B 10/00). In the known system, laser beams are used as communication channels between the transmitter and the receiver of signals. Each signal transmitter is made in the form of a laser generator with a laser beam modulation device with a data signal connected to a data signal source. Each signal receiver is made in the form of a photodetector and a device that converts the perceived laser modulated radiation into electrical data signals.

 A disadvantage of the known data transmission system is its low operational reliability due to the complexity of the system design, which includes a large number of complex signal transmitters and receivers with multifunctional communications and complex precision guidance systems with moving elements. In the known system, when transmitting information between a transmitter and a receiver located at significant distances from each other, for example, when transmitting information over thousands of kilometers using a spacecraft with a repeater, the delay in transmitting information can be tenths of a second. The known system does not have a sufficiently high noise immunity, since when there is any obstacle on the laser communication line, interference occurs in the operation of the system or a breakdown of the transmitted signals.

 The objective of the invention is to increase the operational reliability of the information transmission system while ensuring the transmission of information without delay and increasing the noise immunity of the system.

 The solution to this problem is provided by a new information transmission system consisting of a signal transmitter and a signal receiver remote from it, each of which contains a sensing unit made in the form of spherical sensitive elements having various diameters and rigidly fixed to the surface of the supporting element, and a spherical module, made in the form of a glass sphere in which senses distributed in one direction and offset in two mutually perpendicular planes are fixed The elements are made in the form of identical cubes made of crystal, the elements of the transmitter being similar to those of the signal receiver, the spherical module of the signal transmitter is located on the surface of the support element, the spherical module of the signal receiver is remote from its receiving unit and equipped with a device for converting radiation into output signals.

 In this case, it is preferable to evenly distribute spherical sensitive elements on the surface of the support element and place the centers of these elements in parallel planes, on the surface of the signal transmitter support element near each sensitive element of the spherical shape, perform the image of a certain letter of all letters of the alphabet or an image of a certain number of the whole series of natural numbers, or image of a certain symbol, spherical sensitive elements should be placed on the surface o of a porous element in the form of equal rows, spherical sensitive elements to be performed with gradually increasing diameters, the device for converting radiation into output signals to be performed in the form of a sensor connected by means of an optical fiber to a cube of a spherical module, which is farthest from the receiving unit of the radiation receiver, connect the sensor to the amplifier the output of which is connected to the processor.

 The present invention is based on the principle of similarity established by the author, which is based on the theory of wave synthesis developed by the author in combination with the general reality formula (see. The dissertation for the degree of Doctor of Physics and Mathematics, GP Grabovoi, "Research and analysis of fundamental definitions optical systems for predicting earthquakes and industrial disasters ", Moscow, Izd. RANS, 1999, pp. 9-19).

 In accordance with the theory of wave synthesis, reality can be considered as a periodic intersection of stationary regions with dynamic ones, while in the zones of intersection a synthesis of a dynamic wave with a stationary one arises. Any phenomenon of reality can be defined in the form of optical systems, and since human perception is carried out by images-elements of light containing information, when transmitting information at the first stage from a person who generates transmitted information to an information-sensing optical sensitive element of a person, it can be considered as a kind of transmitting optical system. The transmitted information generated by the thoughts of the human operator is perceived by the optical sensitive element to which the operator directs the generated thought.

 Various optical devices are known, for example, the Camera-3000 apparatus, which makes it possible to detect changes in the human aura (see Komkov V.N. “Biofield and Aura Sensors.” “Electronic Engineering, Series 3, Microelectronics”, 1999. issue 1 (153 ), p. 23). Since thought is part of the aura, it can also be transmitted as an element of a “weak” optical system. It is preferable to perceive the information sensitive element in the form of a sphere, since it is the spherical shape of the sensitive element that contributes to the maximum activation of the sensitive element due to internal reflection.

 The radiation of the activated sensing elements of a spherical shape is light, with each operator transmitting information will correspond to the individual characteristics of this radiation, which determines the high noise immunity of the claimed system. Ensuring the individual activation of sensitive elements of a spherical shape is achieved by using a set of such elements having different diameters, which determines the difference in radiation emitted by different elements. It is preferable to use a set of sensitive elements of a spherical shape, the diameters of which are gradually increasing. The number of sensing elements of a spherical shape in a set can be different. It is preferable to choose the number of elements in the set equal to the sum of the letters that make up the alphabet, and the sum of the numbers that make up the natural series of numbers.

 All spherical sensitive elements included in the set of such elements are rigidly attached to the surface of the support element, made, for example, in the form of a plate. A support element with spherical sensitive elements fixed on its surface form a receiving unit. The transmitter and receiver of signals have similar sensing units, which ensures the reproduction of the transmitted information.

 From the theory of wave synthesis and the laws of quantum mechanics it follows that thought converted to radiation can have two quantum states simultaneously (see Grabovoi G.P. "Research and analysis of the fundamental definitions of optical systems in disaster prevention and predictive-oriented control of microprocessors", "Electronic Technique, Series 3, Microelectronics ", 1999, issue 1 (153), p. 10). One of these states is located on the sensitive element of the signal transmitter, and the other on the similar sensitive element of the signal receiver scarlet. To facilitate the work of the human operator generating the transmitted information, it is preferable to evenly distribute the spherical sensitive elements on the surface of the support element and arrange the centers of the spherical sensitive elements in parallel planes, as well as arrange these elements in the same rows.

 In addition, on the surface of the support element of the signal transmitter near each sensitive element of a spherical shape, an image of the corresponding letter of the alphabet, number or a certain symbol is performed. Along with the use at the first stage of information transmission by means of spherical-shaped sensing elements, a spherical module can also be used in which sensing elements arranged in the form of identical cubes made of a crystal are fixed in series. With a certain mutual arrangement of the cubes, they will normalize the radiation initiated by the thought of the human operator, which characterizes the combination of certain letters of the word.

 At the second stage of information transmission, the radiation emitted by a spherical-shaped sensitive element, in accordance with the similarity principle without any delay, is reproduced almost instantly in a similar spherical-shaped sensitive element that is part of the receiving unit of the signal receiver. Then the radiation enters the spherical module of the signal receiver, which is made similar to the spherical module of the signal transmitter. The spherical module of the signal receiver is made in the form of a glass sphere, in which the sensitive elements made in the form of identical cubes made of crystal are distributed in one direction and offset in two mutually perpendicular planes.

 After the radiation arrives at the first cube, which is closest to the receiver receiving unit, the initial radiation normalization by the first cube will occur at the moment when the radiation emanating from the third cube passes through the fourth cube. The next normalization action is carried out when radiation passes through all the cubes. Light is chosen as a medium of information due to the fact that it allows you to visualize and register the laws of relations established by the formula of general reality. The radiation emitted by some sensitive element of the spherical shape of the signal receiver, after normalization in the spherical module of the receiver, leaves the cube farthest from the receiving unit of the receiver, while the output of the normalized radiation depends on the diameter of the sensitive element of the spherical shape of the signal transmitter, which is similar to the emitting sensitive spherical element of the signal receiver.

 The sensing unit and the spherical module of the signal transmitter are made similar to the corresponding elements of the signal receiver, but may have different geometric dimensions. So, the geometric dimensions of the elements of the signal receiver can be 3-5 times higher than the dimensions of the corresponding elements of the transmitter. As a device that converts radiation emerging from the last cube, an optical converter made in the form of a radiation receiver and a microprocessor that converts the radiation intensity to digital data, or a normalized radiation sensor connected to the last cube via an optical fiber and connected through an electric signal amplifier can be used to a processor having software control.

 The attached drawings depict: FIG. 1 is a general view of an information transmission system (isometric view), FIG. 2 - receiving unit (front view), FIG. 3 - a separate sensitive element of a spherical shape, rigidly fixed to the supporting element.

 The claimed information transmission system comprises a receiving unit of a signal receiver 1, comprising a support element 2, on the surface of which the spherical shaped sensitive elements 3 rigidly fixed on it are uniformly distributed; a spherical module of the signal transmitter 4, containing a glass sphere 5, in which the sensitive elements 6, made in the form of identical cubes, are fixed; the receiving unit of the signal receiver 7, which is similar to a similar block of the signal transmitter and also contains a supporting element 8 and sensitive elements of a spherical shape 9, rigidly fixed to it; a spherical module of the signal receiver 10, which is similar to a similar module of the signal transmitter and also contains a glass sphere 11 in which the sensitive elements 12 are fixed, made in the form of identical cubes; a normalized radiation sensor 13, to which an amplifier 14 is connected, connected to the input of a programmed processor 15, to which a display 16 and a recording device 17 are connected; each sensitive element of a spherical shape using the fastening element 18 is rigidly fixed to the surface of the supporting element.

 Sensitive elements of spherical shape 3 and 9 are preferably made of a transparent material, for example glass. The diameters of all the sensing elements that make up any sensing unit, for example, to the signal receiver unit 1, must differ from each other, with each diameter corresponding to a certain letter, number or symbol. Preferably, the diameters gradually increase, for example, from 1 to 53 mm. Similarly, the diameters of all the sensing elements of a spherical shape 9, which are part of the receiving unit of the signal receiver 7, should be different from each other. Each sensing element of a spherical shape is rigidly attached to the surface of the corresponding supporting element by means of a fixing element 18, for example, by means of an adhesive joint. It is preferable to arrange the spherical sensitive elements on the surface of the support element in equal rows (see Fig. 2, some elements are not indicated), while the diameters of the elements gradually increase in each row.

 Each spherical module 4 or 10 (see Fig. 1) contains a glass sphere. For example, the spherical module of the signal transmitter 4 contains a glass sphere 5, in which the sensing elements 6, made in the form of identical cubes that form a monolithic system with the sphere, are distributed along the straight, perpendicular surface of the support element 2. The number of cubes may be 7, 14, etc. Usually seven dice are used. Cubes 6 or 12 are made from a crystal, for example from diamond or rock crystal. The cubes sequentially located in the spherical module have different orientations of the optical axes. The faces of adjacent cubes are parallel, and the cubes themselves are displaced in two mutually perpendicular planes. The spherical module of the signal transmitter 4 is preferably located in the center of the support element 2. The spherical module of the signal receiver 10 is remote from the receiving unit of the signal receiver 7, preferably at a distance of 200-1000 mm.

 The claimed information transfer system operates as follows. The operator (not specified), transmitting information, is the person who generates the thought. Within 0.1-5 s (the time depends on the bioenergetic field of a person), the operator activates the sensitive elements 3 of the receiving unit of the signal transmitter 1. The signals coming from the optical system of the operator are amplified by the sensitive elements of the spherical shape 3 of the signal transmitter and are practically instantly reproduced without any delay in the corresponding sensitive elements 9 of the signal receiver, the signal transmitted by any element of the transmitter 3 is reproduced by a similar element 9 of the receiver in tvetstvii with the similarity principle. The radiation of the sensing elements 9 of the signal receiver is then converted by the sensing elements 12 of the spherical module of the signal receiver 10. The amount of transmitted information corresponds to the amount of information contained in the generated optical image. For example, the information contained in a CD-ROM reader, after being perceived by the operator, can be completely transmitted to the signal receiver.

 When radiation passes through the elements 12, made in the form of cubes, the shape of the light volume is normalized, which is determined by the mutual arrangement of the cubes. Each diameter of the sensing element of a spherical shape 9 corresponds to a certain amount of normalized radiation coming out of the cube 12, which is the most distant from the receiving unit of the signal receiver 8. The normalized radiation coming out of this cube is transmitted through an optical fiber to the normalized radiation sensor 13, and coming from the sensor electrical signals after passing through the amplifier 14 are fed to the processor 15 with software control. The signals processed in the processor 15, corresponding to the transmitted information, in the form of letters, numbers and (or) symbols can be displayed on the display 16 and fed to the recording device 17, which can be equipped with blocks for recording and storing incoming information for its subsequent processing.

 The claimed transmission system in comparison with the known system has a significantly higher operational reliability, since the design of the claimed system is extremely simplified and there are no any moving elements. The claimed system, in contrast to the known one, provides information transmission over significant (many thousands of kilometers) distances without any delays. In addition, the claimed system has a higher noise immunity, since the barriers between its receiver and the signal transmitter are not obstacles for transmitting information.

Claims (6)

 1. The information transmission system, consisting of a signal transmitter and a signal receiver spaced from it, each of which contains a sensing unit made in the form of optical sensitive elements of a spherical shape having different diameters and rigidly fixed to the surface of the supporting element, and a spherical module made in the form of a glass sphere in which optical sensing elements are distributed distributed in one direction and offset in two mutually perpendicular planes, made identical cubes made of rock crystal or diamond, with transmitter elements similar to signal receiver elements, a spherical transmitter module located on the surface of the support element of its receiving unit, and optical sensitive elements of the transmitter perceive the information transmitted by the operator, the spherical signal receiver module is remote from its receiving unit and is connected to a device for converting radiation into output signals.  2. The system according to claim 1, characterized in that the optical sensitive elements of a spherical shape are evenly distributed on the surface of the support element, while the centers of these elements are located in parallel planes.  3. The system according to claim 1 or 2, characterized in that on the surface of the support element of the signal transmitter near each optical sensitive element of a spherical shape, an image is made of a certain letter of all letters of the alphabet, or a certain number of the whole series of natural numbers, or a certain symbol of arbitrary shape.  4. The system according to claim 1, characterized in that the optical sensitive elements of a spherical shape are located on the surface of the support element in the form of equal rows.  5. The system according to any one of the preceding paragraphs, characterized in that the diameters of the various optical sensitive elements of a spherical shape gradually increase.  6. The system according to claim 1, characterized in that the surface of the support element is located orthogonal to the direction in which the cubes of the spherical module are distributed.

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