WO2014204352A1

WO2014204352A1 - Safe mobile communication device

Info

Publication number: WO2014204352A1
Application number: PCT/RU2014/000415
Authority: WO
Inventors: Юрий Борисович СОКОЛОВ; Валерий Филиппович ИВАНОВ; Вячеслав Александрович ФЕТИСОВ
Original assignee: Sokolov Yuriy Borisovich; Ivanov Valeriy Filippovich; Fetisov Vyacheslav Aleksandrovich
Priority date: 2013-06-21
Filing date: 2014-06-05
Publication date: 2014-12-24
Also published as: RU2013128386A

Abstract

The invention relates to the field of radio communications and specifically to a personal radio-communication system, and can be used in a mobile telephone communication system. A safe mobile communication device consists of a subscriber terminal (1) which belongs to a user and which includes, connected to a central processor (11), a radiotelephone transceiver (14) and at least one additional auxiliary radiation transceiver (15). The latter is matched, by means of an additional communication channel, to an auxiliary transceiver (24) of an individual repeater (3) which is connected to a power source and which includes a microprocessor (21) and also an auxiliary radiotelephone transceiver (23). In addition, the safe mobile communication device contains a means for affixing an individual repeater to the body of the user of the subscriber terminal (1), said means being designed in such a way that the individual repeater (3) is positioned between the knee and the sole of the foot of the user.

Description

SECURE MOBILE COMMUNICATION DEVICE

Technical field

The invention relates to the field of radio communications, in particular, to the technology of mobile telephone communications, and can also be implemented in such mobile devices, for example, laptop computers, which incorporate a radio module using harmful electromagnetic radiation to humans.

State of the art

Currently, the World Health Organization (WHO) has proved that electromagnetic radiation emitted by a mobile means of communication is harmful to human health, as it increases the risk of cancer in it (WHO press release N ° 208 of May 31, 201 1 g .). Known methods of protection against electromagnetic radiation, in which to reduce its power in the area of the head of the subscriber use various shielding elements. Thus, US Pat. No. 5,657,386 describes a mobile communication device made in the form of a mobile phone, in which its radio transmitting unit is mounted on the subscriber’s head, and a screen made of plastic with carbon fiber filler is installed between the head and this radio transmitting block. Obviously, such a solution creates additional inconvenience for the subscriber. Another disadvantage of the known mobile communications is the mismatch of their radiation powers and the radiation powers from the base station. With almost the same sensitivities of their receivers, the reduced radiation power of the mobile communications equipment compared to the base station is often the cause of one-way communication, at which only signal reception from the base station is possible. The main reasons for this include the low radiation power of a mobile communication device and its poor location, for example, indoors.

The most effective way to protect against electromagnetic radiation and at the same time increase its reliability is to use such a mobile communication device, made, for example, in the form of a subscriber terminal (mobile phone, smartphone, etc.), which can interact with an individual repeater. If the latter is, firstly, at a certain distance from the user, and secondly, it uses radiation that is harmless to the user for communication with the subscriber terminal, then electromagnetic radiation from the subscriber terminal is also safe for the user. The closest analogue (prototype) of the claimed invention is a secure mobile communications device described in US patent N9 74441 16 and consisting of a user-owned subscriber terminal, including a radiotelephone transceiver associated with a microcomputer and at least one main auxiliary radiation transceiver, agreed upon additional communication channel with the transceiver of an individual repeater connected to a power source and including a controller connected to the internal Renny memory, auxiliary radiotelephone transceiver, as well as an individual transceiver transceiver.

However, the disadvantage of this device is the inconvenience of its operation due to the need to carry an individual repeater in the bag or briefcase of the user. This is because the placement of an individual repeater on the user's body, for example in the pocket of his trousers or on their belt, negatively affects other organs (except the head) of the user due to their irradiation with the electromagnetic field of the individual repeater. Here, in particular, it can be noted that as a result of numerous studies officially published in various scientific journals, it was found that when carrying an electromagnetic field source (used in mobile communication systems) in the pockets of trousers, the state of the reproductive system deteriorates sharply , and in women.

Other disadvantages of the known secure mobile communications device will be discussed in the following description. In accordance with the foregoing objective of the present invention is to remedy the above disadvantages.

Disclosure of invention

The main task to which the invention is directed is to eliminate the harmfulness of wearing an individual repeater on the user's body.

The essence of the solution of the problem according to the invention lies in the fact that a secure mobile communication device, consisting of a user terminal belonging to the user, including a radiotelephone transceiver connected to the central processor and at least one additional auxiliary radiation transceiver, coordinated according to additional communication channel with an auxiliary transceiver of an individual repeater connected to a power source and including a microprocess op associated with internal memory, as well as auxiliary radiotelephone priomoperedatchi- com, contains means for attaching an individual repeater to the body of the user of the user terminal, moreover, the design of this fastener is implemented in such a way that it ensures placement of an individual repeater between the knee of the user and the sole of his leg.

An advantage of the present invention is the safety of carrying an individual repeater on a user's body.

Other features and advantages of the invention will be apparent from the detailed description, as well as from claims 1 to 16.

Brief Description of the Drawings

The invention is further explained in the description of specific options for its implementation and the accompanying drawings, in which:

figure 1 depicts a block diagram of a secure mobile communications device; figure 2 depicts a functional diagram of a secure mobile communications device; Fig. 3 depicts a top view of shoes (right sneakers) for the user's right foot;

figure 4 depicts a top view of shoes (left sneakers) for the left leg of the user;

5 is a front view of a user's trousers;

6 depicts variants of sensor circuits wearing shoes, sensor wearing pants and a position sensor;

Fig. 7 depicts a flowchart of the operation of a secure mobile communications device.

The best embodiments of the invention

Figure 1 presents the structural diagram of a secure mobile communications device, in which the number 1 denotes a subscriber terminal (AT) having a transmitting antenna (PA) 2, and the number 3 is a two-way individual repeater (IR), located in user's shoes or on his clothes. In general, a secure mobile communications device may comprise n (n> 1) individual repeaters. Subscriber communication terminal 1 can be made in the form of devices such as a mobile phone, laptop, smartphone, tablet computer, as well as devices that contain a radio module designed to transmit data using radiation harmful to the user (subscriber), for example - measures, standard Wi-Fi. Individual repeater contains transceiver the antenna of the repeater (PAR) 4 and has the ability to connect to AT 1 by means of (k = 1, 2, ...) auxiliary emissions (VI), each of which is indicated in the form of two solid parallel arrows 5. Moreover, the parameters ( power, frequency) VI 5 is selected based on the minimum damage to the health of the user. The mobile communication system also includes transceiver base stations (BS) 6, each of which has an antenna 7 and is connected to the switching center (CC) 8 of the mobile communication. Base station 6 is a single-channel or multi-channel stationary transceiver station used for organizing communications with mobile subscribers in a limited geographical area and usually located in its center. Depending on the context, the term base station may refer to the coverage area of a trunked communications system, a cell, a sector within a cell, or a group of cells. The bi-directionality of individual repeaters is determined by their ability to relay messages from both AT 1 to BS 6 and BS 6 to AT 1. Mobile switching center 8 is used in mobile communication systems such as GSM, CDMA, JDC and provides all types of connections, which AT needs in the process of operation 1. Mobile switching center 8 serves a group of hundreds of base stations and provides call routing and call management functions. It also monitors the AT 1 continuously using position registers, movement registers, and other specialized devices. To communicate with another subscriber, two options are used. The first option is carried out by directly transmitting from AT 1 to the input of the transceiving BS 6 and receiving from it directly AT 1 the electromagnetic radiation encoded by the corresponding message, indicated in FIG. 1 by the broken dotted arrow 9. The second communication option is carried out, firstly, by receiving AT 1 from TS 3 and transmission from AT 1 to TS 3 encoded by the corresponding message VI 5, and, secondly, by transmitting from TS 3 to the input of the transmitting and receiving BS 6 and receiving from it TS 3 encoded with the corresponding b- scheniem electromagnetic radiation, indicated by broken line arrow 10. The further description for brevity below the corresponding broken line, or two continuous parallel arrows will also imply The corresponding communication channel. For example, instead of the phrase "the process of transmitting to the input of the transmitting and receiving base station and the process of receiving from it the electromagnetic radiation encoded by the corresponding message is shown by a broken arrow 10" we will write "sending and receiving messages is carried out on channel 10". It should be noted that in the general case, the term “communication channel” or simply “channel” here and hereinafter also refers to a combination of technical means and physical media designed to transmit information and control signals from one user to another. In the first version, control signals are exchanged between AT 1 and the BS 6 transceiver, and in the second, between the IR 3 and BS 6 transceiver. It can be noted that in the process of implementing the second communication variant, as a rule, only one IR 3 is used which is connected through VI 5. At the same time, in general, AT 1 can communicate with VI 5 at once with several IR 3. It should be noted that in the general case, several VI flows can be used simultaneously for communication between AT 1 and IR 3 5, i.e. k> 1. In this case, each auxiliary radiation can be generated by AT 1 and two-sided IR 3 in the form of a stream of light, infrared, ultrasonic radiation encoded by the corresponding message or electromagnetic radiation encoded by the corresponding message. To transmit and receive the latter in AT 1, either the first special antenna (PSA) or PA 2 can be used, used both for receiving and transmitting VI 5, and for receiving and transmitting electromagnetic radiation encoded with the corresponding message 9. Similarly, for transmitting and receiving VI 5 in the form of a stream of electromagnetic radiation in PR 3, either a second special antenna (ICA) or PAIR 4 can be used. In the latter case, it is possible to use a duplex filter - a device that separates the transmission and transmission bands. If TS 3 is located inside the user's shoes, then the body of the user can be used as a physical medium for the distribution of one of the flows of VI 5, for example, the second stream (k = 2). In this case, instead of the BCA antennas, PAR 4, a special adapter installed in the user's shoes can be used. This adapter provides direct or capacitive communication with the user's body. Naturally, AT 1 must also have the same adapter, forming a capacitive or direct connection with the user's palms. It should also be noted that, to a lesser extent, channels 9, 10 are physical (they are, for example, a combination of time and frequency separation of signals and are defined as a sequence of radio frequency channels with the possibility of hopping over frequencies and time windows) and may also include logical control channels. These include, in particular, control signal transmission channels, common channels control channels, individual control channels, frequency adjustment channel, parallel access channels through which control and synchronization signals are exchanged between BS 6 and AT 1 (channel 9) or BS 6 and two-way IR 3 (channel 10). All these signals are generated in the base station controller (not shown in the figure) associated with BS 6. The simultaneous use of several VI 5 streams can optimize their application in such a way that each of these streams will be the most effective from the point of view reliability and quality of data exchange between AT and IR.

Figure 2 presents the functional diagrams of the two-sided IR 3 and AT 1, made in the form of a mobile phone, communicator or smartphone. The subscriber terminal 1 contains a certain number s (s = 1, 2, ...) of radiotelephone transceivers (RPP) 14 and additional transceivers (ATP) 15 of auxiliary radiation connected to the central processor 1 1 via the internal bus 12 and interface 13. RPP 14 and DPP 15 include low noise input amplifiers and power amplifiers, connected, in particular, to PA 2 through bandpass ceramic filters. In another embodiment of the mobile communication device, the DPP 15 can be connected to a separate antenna or to a special means for emitting and receiving VI 5. Received PA 2, electromagnetic radiation encoded by the corresponding message, or auxiliary radiation encoded by the corresponding message after passing the bandpass filter is transmitted by a low-noise input amplifier and, after appropriate conversion, is fed to the input of the central processor 1 1. In the transmission mode, a digital signal generated the central processor 11, as well as in the facilities included in the RPP 14 and the DPP 15 (I / Q generator, phase modulator, mixer, etc.) is supplied to a power amplifier controlled by central processor 1 1. Amplified to of the required level, the signal through the ceramic bandpass filter enters PA 2 and is emitted into space by means of electromagnetic radiation encoded by the corresponding message or auxiliary radiation encoded by the corresponding message. The digital logical part of AT 1 consists of elements connected (directly or via interface 13) to the central processor 1 1, which include control memory (UP) 16, authenticity module (MP) 17 subscribers, keyboard (K) 18 , microphone (Mk) 19 and display 20. Of the other elements of the digital logical part that are not shown in the figure, note sound emitter, channel equalizer, channel encoder / decoder. The digital logic part performs the tasks of demodulating, encoding, compressing and reconstructing the signal encoded by the corresponding message. The latter can be formed by the subscriber either by means of the keyboard 18 or the microphone 19. The digital logic part displays the necessary information on the display screen 20, and also exchanges information with the MP 17, which provides authentication of the subscriber, encryption of the data transmitted to him, as well as the exchange of control signals between AT 1 and BS 6. The subscriber authenticity module 17 contains identifying information including, in particular, a subscriber number. It can be noted that in the GSM standard for mobile communications, special SIM cards are used as authenticity modules. Moreover, the aforementioned exchange of control signals between the means using the subscriber authenticity module and the transceiver base station is also carried out using identifying information stored in the subscriber authenticity module. All the elements included in the AT 1 are powered by their own battery (not shown in the figure). A two-sided IR 3 contains a microprocessor 21 connected via its own internal bus via an individual repeater (IIR) 22 interface with m (m = 1, 2, ...) auxiliary radiotelephone transceivers (VRPP) 23 and to auxiliary transceivers (Runway) 24. Of the other elements included in the IR 3, it is possible to note the internal memory (VP) 25 connected to the microprocessor 21 and the battery 26, designed to power all the elements included in the IR 3. The functional diagram of the runway 23 and the runway 24 can be similar to the above to the transceivers RPP 14 and DPP 15, respectively. The auxiliary radiotelephone transceiver 23 is a bi-directional radiotelephone transceiver, and the runway 24 is a bidirectional transceiver VI 5, each of which is coordinated in its parameters, respectively, with BS 6 transceiver and the corresponding DPP 15. Higher than - The given bi-directionality of the transceivers is due to the possibility of working both on the reception of data and on their transmission. The runway 23 includes an output block connected to PAIR 4. The runway 24 also includes an output block that can be connected to either PAR 4, or to a separate antenna or to a special transmitter of VI 5. If there are several Agreed DPP 15 and Runway 24 as VI 5, it is possible to use such radiation streams that underlie well-known communication system standards, such as, for example, Bluetooth, Wi-Fi. In other embodiments, the execution of the DPP 15, runway 24, it is possible to use light, infrared or ultrasonic radiation. As already noted, it is also possible to use the user's body as a physical medium, which is part of an additional communication channel. In this case, the DPP 15 of the subscriber terminal should be connected to the first adapter (A1) 27, and the runway 24 of the individual relay to the second adapter (A2) 28, while the first and second adapters are matching devices (respectively between the user's body and AT 1 and between the user's body and ID 3) and are intended to use the user's body as a physical medium, which is part of an additional communication channel. The first and second adapters are matching devices, the circuits and designs of which are known from those technologies in which the user's body is used as a physical medium of a VI or as a conductor of alternating electric current. In some embodiments, the first and second adapters can be implemented in such a way that these adapters are connected directly to the central processor 11 and the microprocessor 21. In this case, the elements associated with the formation of the necessary electromagnetic fields must be included in the adapters. The technology for using the user's body as a physical medium was first described in US patent N ° 6754472. In this patent, the first and second adapters contain, in particular, a pair of electrodes that are in close proximity to the human body and perform the functions of interaction (transmission and reception) of modulated electromagnetic fields directly with the user's body. The microprocessor 21 is connected to the internal memory (VP) 25, which can store, in particular, a pre-formed information message by the user, which, as will be shown below, can be sent without using the controls of AT 1 itself. In addition to the listed elements of IR 3 can be connected to elements such as an external battery (V A) 29, an electric energy generator (SEE) 30, a solar battery (SB) 31, a shoe sensor (DNO) 32, a position sensor (DP) 33, a sensor of wearing pants (DNB) ) 34. In the starting position IN 3 find camping in standby mode. This is an energy-saving mode that provides minimum power consumption from the battery 26 due to the automatic shutdown of the main power consuming general schemes and elements. The transition to operational state of IR 3 occurs after the DNO 32 or DNB 34 is triggered. As noted, the main task to which the invention is directed is to eliminate the harmfulness of wearing an individual repeater on the user's body. This is achieved by maximally removing the individual repeater from the user's vital organs by placing it between the user's knee and the sole of his foot. The following describes two options for solving the problem of developing a constructive means of fastening IR 3 on the body of the user AT 1. In the first embodiment, ID 3 is located in the shoes of the user, and in the second - at the bottom of the user's trousers. In FIG. 3 shows a variant of the placement of the elements VA 29, SEE 30, DNO 32, DP 33 in the user's shoes, made in the form of a right shoe 35, and FIG. 4 shows a variant of placing on the left shoe 36 elements BA 29, SB 31, as well as parts of the DP 33, made in the form of a magnetic plate 37. The means for fastening an individual repeater on the right shoe 35 are made in the form of a compartment 38 located on its side. To accommodate the power supply, made in the form of VA 29, on the other side of the right shoe 35 is the first additional compartment 39, and behind the right shoe 35 is the second additional compartment 40, designed to store the SEE 30. A feature of the above compartments is that the compartments are made on the side surface of the shoe in the form of pockets, the opening and closing of which is carried out using three zippers 41. The electric energy generator 30 generates energy from its own mechanical vibration, is connected Noah walking user. This increases the period of operation of the IR 3 both from the battery 26 and from the VA 29. The principle of the SEE 30 is based on the Faraday law of electromagnetic induction, according to which the generated electromotive force is equal to the rate of change of the magnetic flux passing through the circuit. In practice, a small movable magnet is surrounded by a certain number of coils in the SEE 30. The battery 26 is recharged by moving the magnet from place to place. There are other well-known principles for converting the mechanical vibrations of the SEE 30 into electrical energy. It can be noted that one of the first sources in which shoes with integrated SEE 30 was described is US patent N ° 791 1339. For the purpose of interaction between BA 29 and SEE 30 with an individual repeater, compartments 38, 39, 40 are interconnected by conductors placed inside the shoe and ending with the corresponding connectors. Design BOTTOM 32 consists of a first reed switch 42 located on the right side 43 of the right shoe 35 and a magnet 44 located on its left side 45. The magnet 44 and the first reed 42 are placed in such a way that the contacts of the last trigger after the parts 43 and 45 come closer due to the tightening of the lace (not shown in the figure), threaded through the holes 46 of the right shoe. The design of the DP 33 consists of the already mentioned magnetic plate 37 and the second reed switch 47. located in front of the right 48 of the shoe 35. In order to quickly charge the battery 26 or VA 29 in the front of the left 49 of the shoe 36 is installed SB 31 connected to special charger. Charging the battery 26 is carried out after its placement in the battery compartment 50 located on the left side 51 and closed with a zipper 52.

Figure 5 shows a variant of the placement of IR 3, VA 29, SEE 30 and DNB 34 in the trousers 53 of the user. To accommodate the IR 3, the fastening means is made in the form of a pocket 54 made in the lower part of the left half of the user's trousers 55. In addition, the user's trousers 53 contain a pocket 56 for containing a power source made in the form of a BA 29. In the upper part of the right half of the 57 trousers there is a pocket 58 for holding a power source made in the form of a SEE 30. designed to generate electrical energy in the process of its mechanical vibrations when the user walks. As in the previous case, pockets 54, 56, 58 are interconnected by conductors placed inside the fabric of the trousers and ending with the corresponding connectors. In the upper part of the pockets 54, 56, 58 are means for closing them, made in the form of buttons, buttons or zippers. The sensor 34 of the worn trousers, connected with the means intended for connecting the IR 3 to a power source, for example, a battery 26, is made in the form of trousers of a flat magnet 60 and a third reed switch 61 located near the belt 59. When tightening the belt 59, the flat magnet 60 approaches the third Reed switch 61, as a result of which its contacts are closed. The advantage of using compartments 38, 39, 40 and pockets 54, 56, 58 is the possibility of independent use of various types of IR 3, A 29, SEE 30 during the operation of AT 1. Next, we consider the principles of functioning of DNO 32, DP 33, DNB 34, which provide additional capabilities when operating a secure mobile communications device. The sensor 32 of the worn shoes and DNB 34 allow you to translate IR 3 in the mode of economical consumption of electric energy from power sources 26, 29, 30 in cases where shoes and trousers are not used by the user. In addition, as already noted, the user's shoes contain a position sensor designed to fix a predetermined distance h (0 <h <H) between the corresponding parts of the shoe, dressed on the right and left foot of the user. When this DP 33 is connected to a means of transmitting an informational message, which in its memory can be recorded in advance. This allows the user to send special messages without using AT 1 by z (z = 1, 2, ...) presentations at a distance h of the magnetic plate 37 to the second reed switch 47. This may be necessary in cases where the user is unable to use AT 1 directly (car accident, attack by criminals, partial paralysis of the user, etc.). The described DNO 32, DP 33, DNB 34 can have a different design and different principles of their work. Figure 6 shows a simplified connection diagram of the DNO 32, DP 33, DNB 34 to IR 3. As an example, this description shows the simplest sensors based on the closure of contacts 62, 63, 64 of reed switches 42, 47, 61 when presented to them magnets 44, 37, 60 at a close distance h. It can be seen that the maximum output voltage taken from each sensor depends on the resistance value of the resistors 65 and on the input resistance of the input port 66. The latter, in the general case, are used to connect external equipment to the microprocessor 21 and can be directly integrated into its circuit. In order to use a special message to determine the coordinates of the user, the information message transmission means 67, in addition to the VP 25, contains a global positioning unit (GPS) 68. It can be seen from the figure that the information message transmission means 67 also functions as a means for connecting an individual repeater to the power source when triggered (by closing the contacts 62) DNO 32 or when triggering (when closing the contacts 64) DNB 34. Operation of the safe mob Flax communication is performed in accordance with the algorithm shown in Figure 7. The practical implementation of this algorithm is carried out using special software that is stored, in particular, in such elements as UP 16, VP 25, and CC 8. The start of the algorithm (step 69) is due to donning or shoes in the form of sneakers 35, 36, or trousers 53, after which the DND 32 or DNB 34 are triggered and IR 3 is turned on. If the latter is in compartment 38, then the DND 32 is triggered after tightening the lace threaded through aperture 46, which causes the magnet 44 to approach the reed switch 42. As a result, the contacts 62 are closed and a voltage drop appears at the input of the input port 66, which is converted by the microprocessor 21 into a signal, which allows the IR 3 to go out of standby mode. If IR 3 is in pocket 54, then the DNB 34 is triggered after the magnet 60 approaches the reed switch 61. As a result of this, the contacts 64 are closed and a voltage drop appears on the other input of the input port 66, which after conversion to the microprocessor 21 transfers IR 3 from standby mode. After enabling IR 3, action 69 also describes the establishment of a connection between AT 1 and two-way IR 3 by means of VI 5. Next, step 70 is performed to evaluate the quality of communication between AT 1 and η-th IR 3. If the number of IR 3 is two (n = 2) , then one IR 3 can be placed in shoes, and the other inside trousers. In step 70, not only the quality of communication is evaluated by means of VI 5 between AT 1 and IR 3, but also the parameters of the two-way IR 3 are displayed on the display 20 of the subscriber terminal 1 (state of the power supply of the two-way mobile repeater, its location, etc. d.). Checking the quality of communication, as well as transferring the above parameters, can be carried out by generating a special signal in IR 3, which either transmits data on the quality of the signal received by it from AT 1 through a channel using auxiliary radiation, or is itself a signal - they are judged on the quality of communication, but already in the subscriber terminal itself. The signal quality assessment itself is carried out by standard methods using special software after the signal passes through an analog-to-digital converter, which can be contained in the central processor 1 1. Measurement or estimation of the signal level is a standard function in many mobile communication systems, for example, CDMA or GSM mobile telephone system. As a rule, the signal level is estimated after its detection and calculation of the signal-to-noise ratio, integrated over a certain period of time. It should be noted that evaluation of signal quality in the simplest case can be reduced to measuring its signal level. Objective (instrumental) methods make it possible to determine the degree of correlation between theoretically predicted and real estimates of the signal-to-noise ratio. For mobile systems, the signal-to-noise ratio corresponding to acceptable quality varies from 15 to 25 dB. If the communication quality between the ηth IR 3 and AT 1 is not satisfactory ("No" in condition 71), then step 72 is performed, which is connected with the connection of the new (n + 1) -th IR 3, by means of which it is supposed to receive and transmit electromagnetic radiation encoded by the corresponding message. If the communication quality between TS 3 and AT 1 is satisfactory ("Yes" in condition 71), then step 73 is performed to transmit identifying information to the VP 25 and to establish, with its help, the connection between TS 3 and BS 6. If after that the communication quality between IR 3 and BS 6 on channel 10 is unsatisfactory ("No" in condition 74), then action 75 is performed, associated with the establishment of communication between AT 1 and BS 6 through channel 9, as well as action 76, associated with the reception and transmission of data through BS 6. Moreover, this data includes both the corresponding message and the control signals phenomena, i.e. in this case, AT 1, containing the central processor 1 1 and UP 16, transmits to the input of the transceiver BS 6 and receives electromagnetic radiation encoded by the corresponding message, and also exchanges control signals between AT 1 and the transceiver BS 6. If the quality of communication between the IR 3 and BS 6 on channel 10 is satisfactory ("Yes" in condition 74), then step 77 is performed associated with the establishment of communication between AT 1 and BS 6 by means of IR 3 on channels 5, 10. If after that the position sensor 33 was not turned on (“No” in condition 78), then transfer to BS 6 transmitting and receiving and the electromagnetic radiation encoded by the corresponding message, as well as control signals between AT 1 and BS 6 receiving and transmitting are transmitted via channels 5, 10 (step 76). Now, as an example, we consider one of the options for enabling DP 33 ("Yes" in condition 78), which results in the execution of step 79 to generate an information message. Suppose that the user is in a critical position and needs to be imperceptible to nearby people, i.e. Without using AT 1, transmit the following informational message: SOS, N 55.755831 E 37.617673. Moreover, for this it is necessary, firstly, the double actuation of the DP 33, and secondly, the time T of the second operation must be greater than the time t of the first operation. Thus, in order to carry out the aforementioned transfer, the user must twice bring the back of the left shoe 36 to the front of the right shoe 35 at a distance h (h <H). At that, the time t during which the back of the left shoe 36 is for the first time near (by a distance h <H) of the front 48 should be less than the time T during which the back of the left shoe 36 is for the second time near the front of the right shoe 35. As a result of these proximity of the magnetic plate 37 and the second reed switch 47 contacts 63 are closed two times and two rectangular pulses of duration t and T appear at the input of input port 66. These pulses are converted in microprocessor 21 into a command that implements step 79 by sending the above SOS message, for example, as an SMS message , which also includes data N 55.755831 Е 37.617673 of the user's location, which are removed from the output of BS 68. It can be noted that for the implementation of step 79, it is necessary to pre-select such manipulations with sneakers 35, 36 related to their proximity, probability arose veniya which during normal walking should be minimal.

Industrial applicability

The invention can be used in such communication fields as: mobile telephone communications of all known standards, a trunked radio telephone system, personal radio stations. This invention can also be widely used in public places where the presence of a large number of people makes it difficult to use secure mobile communications operating on such auxiliary radiation (for example, the Bluetooth standard), which, due to the deterioration of signal / noise due to the large number devices limits the number of users. Using in this case the user’s body as the medium included in the additional communication channel, one can not be afraid of signal / noise deterioration due to the large number of users of the safe mobile communication device located simultaneously in one place.

Claims

CLAIM

1. A secure mobile communication device, consisting of a user terminal owned by the user, including a radiotelephone transceiver connected to the central processor and at least one additional auxiliary radiation transceiver, coordinated via an additional communication channel with the auxiliary transceiver of an individual repeater, connected to a power source and including a microprocessor associated with the internal memory, as well as an auxiliary radiotelephone reception a transmitter, characterized in that it comprises means for attaching an individual repeater to the user body of the subscriber terminal, and the construction of this means of fastening is carried out in such a way that it ensures the placement of an individual repeater between the knee of the user and the sole of his leg.

2. The safe device according to claim 1, characterized in that the fastening means is made in the form of a compartment made on the user's shoes and intended for placement of an individual repeater in it.

3. The safe device according to claim 2, characterized in that the user's shoes contain a compartment for accommodating a power source, made in the form of an external battery.

4. The safe device according to claim 2, characterized in that the user's shoes contain a compartment for placing a power source in it, made in the form of an electric energy generator, designed to generate electrical energy during its vibration when the user walks.

5. Safe device according to any one of paragraphs. 2 - 4, characterized in that the additional transceiver of auxiliary radiation of the subscriber terminal is connected to the first adapter, and the auxiliary transceiver of the individual repeater is connected to the second adapter, while the first and second adapters are designed to use the user's body as a physical medium - dy entering an additional communication channel.

6. Safe device according to any one of paragraphs. 2 - 4, characterized in that the compartments are made in the form of pockets placed on the side surface of the shoe.

7. A secure device according to any one of paragraphs. 2 - 4, characterized in that the compartments are interconnected by conductors placed inside the shoe and finish and- with the appropriate connectors.

8. A safe device according to any one of paragraphs. 2 to 4, characterized in that the shoes comprise a sensor for wearing shoes associated with a means for connecting an individual repeater to a power source.

9. A secure device according to any one of paragraphs. 2 to 4, characterized in that the shoes contain a position sensor designed to fix a predetermined distance between the corresponding parts of the shoe, dressed on the right and left foot of the user.

10. The safe device according to claim 9, characterized in that the position sensor is connected to the means of transmitting the information message.

1 1. The secure device of claim 10, wherein the means of transmitting the information message comprises a global positioning unit.

12. The safe device according to claim 1, characterized in that the fastening means is made in the form of a pocket made in the lower part of the user's trousers and intended for placement of an individual repeater in it.

13. The safe device according to item 12, characterized in that the user's trousers contain a pocket for accommodating a power source, made in the form of an external battery.

14. The safe device according to claim 12, characterized in that the user's trousers contain a pocket for accommodating a power source in it, made in the form of an electric energy generator, designed to generate electrical energy during its mechanical vibrations when the user walks.

15. Safe device according to any one of paragraphs. 12-14, characterized in that the pockets are interconnected by conductors located inside the trouser fabric and terminating in the corresponding connectors.

16. A secure device according to any one of paragraphs. 12-14, characterized in that the trousers comprise a sensor for wearing trousers associated with a means for connecting an individual repeater to a power source.