EA017487B1 - Method of information transceiving - Google Patents

Abstract

The invention relates to communication systems and can be used for transmitting information to zones of emergency situations. The invention is characterized in that a receiving unit receives its coordinates from a satellite navigation system (for example GPS) and, using coordinate values (longitude and latitude), forms its personal activation code and a format of information reception (algorithm of information decoding) at a corresponding broadcasting standard frequency. For transmitting the information to dedicated users, depending on their location, an emergency situation region and its locations are first selected and limited for information transmission, then a matrix is formed for the selected locations, each cell of which has coordinates, after which a data packet is formed for users of the selected location, at the start of said packet the activation code of the information transmission is enclosed, the code is formed on the basis of coordinates of each separate matrix cell, identical to the activation code of the user's receiving unit. After that the data packet is transmitted to all matrix cells from the ground station to one or several broadcasting satellites, radius of action of which covers the emergency situation area. The broadcasting satellites transmit data packets at the frequency of standard broadcasting in a format based on values of the receiving units coordinates. The receiving unit, having received the activation code which corresponds to that formed by it's the personal activation code activates and starts receiving and recording the information being transmitted in the corresponding format. The information may be of any character - text, audio address, video or graphic image, etc.

Description

The invention relates to communication systems and can be used to transmit information to emergency zones.

The effectiveness of coordination of actions of all public administration systems, rescue services, personnel of government agencies and law enforcement agencies involved during emergencies (ES) caused by natural and technological disasters and in the aftermath of their consequences depends largely on the clear and trouble-free operation of communication and telecommunication systems resources.

Thus, US experts note that a powerful US telecommunications network, which today, along with special (government, diplomatic, intelligence, military) and general (telephone, paging, trunk, cable, satellite, etc.) communication systems, includes Internet resources, in one instant, it can significantly lose its effectiveness as a result of a natural disaster, accident, terrorist act or other emergency. During severe earthquakes, floods, hurricanes and other natural disasters, communication systems, including mobile communications and special communications systems, are primarily disconnected due to the destruction of communications equipment and communications. Even if the communication systems are not technically damaged, the connection ceases to function due to network congestion, as the number of calls from subscribers increases many times, which instantly overloads and blocks communication. This happens in all cases, including industrialized countries.

A striking example of this is the disconnection of wired and cellular communications in Washington and New York for several hours after the tragedy of September 11, 2001. This happened due to hundreds of thousands of calls made by subscribers almost simultaneously blocking overloaded PBXs. According to American experts, the allowable number of calls from telephone subscribers in New York on September 11 was exceeded by 14 times, while during the earthquake in San Francisco on October 17, 1989 - by 10 times. According to other sources, the largest national telecom operator AT&T received 100 million more calls than usual this day (1).

A known method of transmitting information and a system for its implementation, including the installation of transceiver stations (cells) placed in such a way that their radius of action overlap each other and connected to a cellular network. For the implementation of cellular communication, mobile phones are used that receive and transmit sound information using electromagnetic signals received and transmitted by cellular stations (2).

The disadvantage of this method of transmitting information in natural disaster areas is that as a result of natural disasters (earthquakes, floods, hurricanes, etc.) and man-made disasters (explosions in industrial enterprises, explosive storage facilities, fuel storage facilities, etc. ) the terrestrial technical infrastructure of cellular communications (transceiving communications nodes, etc.) is being destroyed. In addition, the second drawback is a sharp overload of communication channels as a result of a multiple increase in the number of calls at the time of emergency, which leads to overloading the PBX and blocking communication. The main disadvantage of this communication system is the inability to massively transfer information to the affected areas to large masses of people with the goal of effective emergency management.

There is also known a method of transceiving information and a system for its implementation in emergency situations. Within the framework of the program for creating the Perspective Intelligent Network (ΑΙΝ), it is envisaged to provide, based on the use of technology of the Ι8ΌΝ data transfer standard, which has become widespread in the USA over the past 20 years, and also on the basis of intelligent terminal equipment (personal computers, cell phones and ordinary telephones, fax machines) to provide flexible telephone access to any service (telephony, 8M8, paging, data transfer, Etai, NTM, ETR, ^ ΑΙδ, \ УАР) b subscribers of the public telephone network (РиЬе 8 \\ 'Це11еб ΝοΙ \\ όγ1 <- Ρ8Ν) b Without the participation of an Internet provider or telecom operator. At the same time, the requirements for access control and priority selection in service will be met. The main goal of the program - the modernization and development of the Government Emergency Telecommunications Service (OET8) is to provide guaranteed communications for U.S. government subscribers during emergencies in which the corresponding communication resources (lines, channels, switching centers) can be disabled, overloaded.

Technical capabilities of the system are provided on the basis of flexible and efficient reallocation of resources and traffic reconfiguration, taking into account priorities both at the expense of federal (ET8, ΌΙ8Ν, ET8) and commercial (AT&T, MC1 \ Uog1bSot. Δρτίηΐ) public switched telephone networks based on digital technologies and The Internet. Access and connection of subscribers is carried out according to a single automated procedure (tone dialing of a combination 710-НС8-ОЭТ8 '' + РГН + subscriber number) regardless of their location based on a personal identification code (Ret8op1 1byepDeaiop Zhppyeg - Р1Л), in accordance with which the urgency category is established and call priority (3).

The disadvantage of this communication system is its extreme technical complexity and high cost. The possibility of destruction of the technical infrastructure of communication systems in the emergency zone, including the Internet,

- 1 017487 urban and special communications also makes this communication system not very effective during

Emergency. The main disadvantage of this communication system is the inability to massively transfer information to areas affected by emergencies to large masses of people in order to effectively manage and coordinate the actions of people and public services.

To organize joint actions by telecom operators to restore telecommunications resources and services in case of emergency, when the public wire telephone network is completely blocked or congested, a special Alert and Coordination Network (ΑΟΝ) has been created in the United States, with the help of which conference information is exchanged between regional emergency response centers. In this case, dedicated telephone lines organized on the basis of short-wave and satellite radio communication systems can be used. Depending on the level of damage and loss associated with emergencies, there are three categories of complexity for the restoration of telecommunications resources and services of national communications systems in the United States. Restoration operations of the third (highest) category (ΝΤΜ8 Kekroike Leue1 III) are carried out in emergency situations that directly affect the national security of the United States, or at the personal instruction of the president, as it was on September 11, 2001. In these operations, special groups and response headquarters (Ναΐίοηαΐ Etegdeisu Maiadetei! Theater, SottischsΙίοηκ Riis11oya1 Sgoir, Kedyuya1 Etegdeisu Miadetei! Theater, ΝΤΜ8 State Government, and representatives of the state, government and government representatives) are formed in these operations (central and local) counties, districts, cities) that assess the extent of damage and organize all work to restore telecommunication resources and services to the required extent (3).

Within the framework of the Distributed Resources (8NAKE8) project, for the organization of wireless communication of the US government authorities during an emergency, the current national short-wave communication network is being modernized, which includes almost all the receiving and transmitting short-wave radio communication centers of civilian and military ministries and departments in the United States, as well as personal radio amateur stations. Under the existing agreement - the Memorandum of Understanding between the American Radio Relay League and the National Communications System - US radio amateurs (over 400 thousand), in accordance with the regulations and rules approved by the Federal Communications Commission under the Disaster Management Act of 1974, undertake to provide the US government its equipment and frequencies for emergency communications in emergency situations (3).

The disadvantage of this communication system is its extreme technical complexity and high cost. In addition, the possibility of destroying the technical infrastructure of communication systems in the emergency zone, including the Internet, urban and special communications. The main disadvantage of this communication system is the inability to massively transfer information to areas affected by natural disasters to large masses of people in order to effectively manage and coordinate their actions.

The closest technical solution is a method and system for high speed packet data and low latency data transmission. This technical solution provides a combined transmission of packet data and low latency data. To this end, the parallel signaling channel transmits to the receivers a message indicating the designated receiver of packet data. The message also identifies the communication channels used to transmit packet data. Each receiver can selectively decode packets only when the message identifies the receiver as a designated recipient. Data packets stored in the buffer are ignored if the destination recipient is another mobile unit. According to one embodiment, the message is sent simultaneously with the data packet on the parallel channel (4).

The disadvantage of this method is that it does not allow the mass transfer of information to the emergency zone to specific recipients, depending on their location.

In addition, this technical solution does not allow the use of standard broadcasting satellites for the transmission of information and requires an independent communication system having parallel synchronization channels. The necessary information about the situation in various emergency zones can go to emergency management bodies via satellite special communication systems, which are held by representatives of state rescue bodies and employees.

Meanwhile, the problem of managing and coordinating a large number of people in the emergency zone is unresolved and relevant. A large number of people in disaster areas, in a state of panic and psychological stress, have no idea what they should do, move in any direction or stay in their places and wait for help. It is possible that a danger is approaching them from a certain direction, for example, water flows from a destroyed dam or chemicals from a destroyed storage, etc. In this case, they should have accurate information about where they need to move and where to wait for danger. They can also get information about the need to use any shelter to protect them, such as the metro or other places.

The fact of the matter is that during emergencies it becomes especially important to transmit various special information packets to many people at the same time, depending on their location, in order to manage and coordinate their actions. In the case when a large number of people are in the emergency zone, only direct transmission of information to people will be most effective. Feedback with a huge number of people will not only not have a positive effect, but will also complicate the situation. This is due to the fact that the masses of people who are in a panic and a state of stress and are not able to really assess the situation and their information will be primarily emotional.

The objective of the proposed invention is the creation of a transceiver system that allows information to be transmitted to the emergency zone to subscribers, depending on the coordinates of their location.

The problem is solved by a method including the formation of information packets necessary for transmission, encoding information packets in a special format, transmitting information packets to a transmitting device, converting encoded information packets by a transmitting device to an electromagnetic signal and transmitting it to a transmitting and receiving satellite, transmitting an electromagnetic signal from satellite to receiving subscriber device, identification of the receiving device, receiving and decoding in the receiving device of the electromagnet signal to the information for the subscriber, where according to the invention, the subscriber’s receiving device is additionally equipped with a module for receiving coordinates from a satellite navigation system, a module for generating, from received coordinates, a receiving code of a receiving device, which allows subscribers to obtain coordinates about their location from a satellite navigation system, form from the received coordinates activation and reception code of the receiving device, and when generating information for transmission, select the area in which the information will be transmitted form a coordinate matrix based on the contours of the selected region, each cell of which is assigned a code including the coordinates of the cell, the format of this code being identical to the format of the activation code and the receiving device, while the information generated for transmission with the codes of the receiving devices selected using the coordinate matrix is transmitted in the form electromagnetic signal to the satellite from which the electromagnetic signal carrying information is transmitted to the area of destination, while only those receiving devices receive this signal code whose code is identical to the code of the transmitted information.

During large-scale natural disasters (earthquakes, tsunamis, volcanic eruptions, floods, etc.) and emergencies caused by human activities (for example, large dam breaks, explosions at oil storage facilities, etc.), large areas may remain unsecured communications due to the destruction of ground-based technical equipment providing communications, such as telephone exchanges, cellular communication centers, etc. In this case, large masses of people and government employees cannot receive information about necessary actions from the state Twain and international coordination bodies and the rescue services. Lack of communication with people in the affected areas leads to panic and chaos, improper actions, which becomes the main reason for the increase in the number of victims and the damage done. In this situation, satellite communication systems cannot help, since there are very few subscribers to these systems.

The essence of the invention lies in the fact that the receiving device (PU) receives its coordinates from a satellite navigation system (for example, OP8) and, using the coordinate values (longitude and latitude), forms its personal activation code and the format for receiving information (information decoding algorithm) on corresponding standard broadcasting frequency. To transmit information to designated subscribers, depending on their location, the emergency area and its individual sections for transmitting information are first selected and limited, then a matrix is formed on the area of the selected area, each cell of which has coordinates, then information packets are created for the selected subscribers territory, at the beginning of these packages is attached an activation code for transmitting information based on the coordinates of each individual cell of the matrix, identical to the activation code of the subscriber’s PU. After that, a packet of information is transmitted for all cells of the matrix from a ground station to one or more broadcasting satellites, whose radius of operation covers the emergency area. Broadcasting satellites transmit information packets at a standard broadcasting frequency in a format based on the values of the coordinates of the PU. The control unit, having received an activation code corresponding to the personal activation code generated by it, turns on and begins to receive and record transmitted information in the appropriate format. Information can be of any nature - text, audio, video or graphic image, etc.

A diagram of a method for transmitting and receiving information is shown in FIG. 1 and 2, respectively.

The proposed method of transmitting information allows you to use special very simple controllers - pagers, mobile phones, computers and other devices with special built-in modules for receiving information to receive target information via standard broadcasting satellites, and only the subscriber to whom it is intended will receive information, depending on its location. If the subscriber is not in the zone for which the information is intended, his PU will not activate and ignore this information.

The alleged invention is illustrated by the following examples.

1. The control unit receives the coordinates of its location from the OP8 satellites and generates the control code (activation and reception code) of the control unit from the received coordinates, for example the control unit coordinates: 46 ° 57'32 (sec

- 3 017487 the correct latitude is displayed in the code as the last digit in latitude coordinates, for example, as 1) 42 ° 38'21 (east longitude is displayed in the code as the last digit in longitude coordinates, for example as 1), and the following code is generated: 46573214238211.

If south latitude, for example, number 2 is indicated at the end of latitude coordinates, for example, if west is longitude, number 2 is also indicated at the end of longitude coordinates, and the following code is generated: 46573224238212. The coordinate accuracy can be of any level. Thus, a code is generated containing complete information about the coordinates of the control panel.

2. When transmitting information to this control unit, the operator sends digital information in the form of text, sound or image (for example, a map indicating the direction of travel or destination), while at the beginning of the transmitted signal a digital code with the coordinates of the control unit is transmitted, for example 4657321423821.

Before receiving the code corresponding to the GO code of the control panel, the control panel is in sleep mode with minimal power consumption. After receiving the activation code, the receiving module activates the control unit and turns on the reception and recording of information and the control unit sends an alarm (sound, light, vibration or any combination of signals).

3. If the operator of the transmitting station sending the packets of information does not know the exact coordinates of the location of the control unit, but can know the approximate square of the location of the control unit, then it indicates the limits of the square to which information is transmitted, for example, from 46 ° 57'32 to 46 ° 57'37 north latitude and from 42 ° 38'21 to 42 ° 38'25 east longitude. The transmitter generates a matrix with cells equal, for example, 1 s, and transmits information by alternately scanning the matrix across all its cells, while the PU located within this square will receive its activation code and is activated to receive information. Information transmitted from the satellite will be received on the control panel. After the transmission of information is completed, the satellite operator transmits the end of transmission code and the control unit is deactivated and enters the signal standby mode (sleep mode).

4. If the operator of the transmitting station knows the area where the control unit is located, it can transmit information to the matrix with any boundary configuration. If the information is to be transmitted by the operator to a group of people located within the proposed area, he will scan the area of the emergency area and when transmitting a signal based on scanning matrix cells, all controllers located in the specified area of the emergency area will receive the necessary information.

PU can be of different levels of complexity and purpose. For example, there may be PUs of four (or more) basic types.

PU common use. At the end of the usual GO code of these controllers, for example, 15 or another number of digits is set - 0 (or other), for example 465732142382110000000000000000000. Such controllers receive information intended for all controllers in the information zone.

Collective controllers with a specific 15-digit code after the regular code, for example 46573214238211454126319756893.

Such launchers can operate in two modes and receive information simultaneously in standard and special modes or one of them at the request of the launcher owner. For such launchers, information can be sent regarding only specific owners of launchers located in the information zone possessing this code, for example, only rescuers in the emergency zone to separate the actions of rescuers from the actions of other people. Each team can have its own code to discretely control different structures - rescuers, police, doctors, military.

Individual PU. Individual controllers operate on the same principle as special ones and can have an individual 15-digit code after a regular code. They can be intended for members of the government, leaders of rescue operations, etc.

Special multi-channel controllers can have several reception channels and simultaneously receive information on each channel separately.

This may be necessary while transmitting a large flow of various information, for example, if the control unit is used for remote control of a complex technical tool. For example, some complex systems controlled centrally may lose control as a result of the destruction of the control system or communications of this system in the emergency zone. For example, it can be nuclear power plants, oil refineries, large fuel terminals, hydraulic structures, dams, etc. In this case, autonomous mini-control units with the help of controllers can be installed to execute specific commands of electronic actuators, for example, electronic valves that shut off oil and gas pipelines, water intake locks on dams and hydraulic structures, etc. In this case, each communication channel of the control panel can be used to independently control different modules of the managed object.

Communication control centers (CSC), which form and send information packets to the emergency zone, are recommended to be located in the most secure regions, and they may have several duplicate centers. The NCC can use the Internet, mobile communications and special means to communicate with governments, state emergency management services from different countries, the UN, and centers for forecasting various natural disasters - tsunamis, tornadoes, storms, earthquakes, volcanic eruptions

- 4 017487 new, etc.

The incoming information intended for transmission to the emergency zone should contain the coordinates of the disaster area, the main text and may contain other applications, such as maps, diagrams, tables, etc. This information is redirected by the CSC operators to the transmitting station, and from it to the communication satellite, which sends this information to the air in the zone covering the emergency area. Different communication satellites may be used depending on the location of the emergency area.

To cover the entire globe or most of it, satellite systems can be used that are switched with each other via radio channels and controlled through a base satellite connected to a control center on Earth.

Information taken into account.

1. A.M. Abayus. Ε.Ν. Κΐιαίίίον. 1psgsa5s οί sGGssNusps55 οί arriesayoi οί sottsshsayoi 5uet aiy ίηGogtayoi 1essio1odu a! here is 8 Yiyoyoi 8. δΟΙΕΝΟΕ ED1TNOIT ΒΘΚΟΕΚΚ Thaikasioik οί Not 1n1egpayoia1 Asayetu οί 8с1еисе Н & Ε. νοί. 3. 2007/2008, 8 EDV, 1p8Lisk, 2008, p. 361-366, ΙδΒΝ 978-9952-45101-6, ΙδδΝ 2070-0334.

2. Cellular communication. History, standards, technologies, 1yr: //se1ie1.gi/.

3. A.M. ABA80ν, Ε.Ν. Κΐιηίίίον. 1i1egiayoyia1 SoiGeheise ^ eνе1οртейΐ! О 30 уеагк ргоГ. Iatiy Ada Akuyu Prgo1et5 ίί heys G18k, heys Cha1e soschyysyoi aiy agsY1es1ige, 28-29 arge1, Waki, 2005.

4. Landby Stein A. (USA), Razumov Leonid (USA), Bao Gang (USA). Method and apparatus for high speed packet data and low latency data transmission. Patent of Russia, 2422998 C2 dated 10.24.2001.

Claims (1)

CLAIM The method of transmitting information includes the formation of information necessary for the transmission of packets, the encoding of information packets into a special format, the transmission of information packets to a transmitting device, the conversion of encoded information packets by a transmitting device into an electromagnetic signal and its transmission to a transceiver satellite, the transmission of an electromagnetic signal from a satellite to a receiving subscriber , identification of the receiving device, receiving and decoding in the receiving device of the electromagnetic si sent to the subscriber information, characterized in that the subscriber receiving device is additionally equipped with a coordinate receiving module from the satellite navigation system, a generating module from the received coordinates of the receiving code of the receiving device, which allows subscribers to receive coordinates about their location from the satellite navigation system, from the received coordinates activation code and reception of the receiving device, and when generating information for transmission, select the area to which the information will be transmitted, form on the basis of the contours of the selected area, the coordinate matrix, each cell of which is assigned a code including cell coordinates, and the format of this code is identical to the format of the activation code and reception of the receiving device, while the information generated for transmission with the codes selected using the coordinate matrix of the receiving devices is transmitted as electromagnetic signal to the satellite from which the electromagnetic signal carrying the information is transmitted to the destination area, and this signal is decoded.