RU2377741C1 - Method of switching subscribers in heterogeneous networks of integrated communication system and integrated communication system of facility (versions) - Google Patents

Abstract

FIELD: physics; communications.

SUBSTANCE: invention relates to communication engineering and can be used for mutual integration of existing different heterogeneous communication systems at a facility. The technical outcome of the invention is increased security and overall reliability of communication, wider coverage area of each of the integrated communication networks and increased number of telecommunication services for users. For this purpose heterogeneous networks are connected together through a gateway node, which contains modular programmable switches-gateways and a control device. The switches-gateways have modular structure. Each network is connected to its own switch-gateway of the corresponding type. The control device can pick out the number of the called subscriber from the signal which is received when establishing connection, can determine from the given number the network of the called subscriber and can determine the number of the called subscriber in their network, as well as establish connection between modules of switches-gateways.

EFFECT: end-to-end traffic forwarding of low-frequency communication channel routes.

17 cl, 1 dwg

Description

The invention relates to communication technology and can be used for the mutual integration of various heterogeneous communication systems existing at the facility, in particular trunking and conventional radio communications, radiotelephone systems, broadband radio access systems, technological and emergency dispatch telephone systems, into a single system to ensure normal functioning all technical facilities of the facility, the interaction of operating personnel and various services in normal operation, as well as in emergency s and emergency situations. Objects for the installation of integrated communication systems (CAC) objects can be objects of administrative, industrial, transport, cultural, sports and other purposes. The invention may also find application in facilities distributed over territories or water areas. In this case, heterogeneous communication systems are understood to be communication systems that are heterogeneous in composition and do not allow subscribers of one network, which is a subsystem of the KSS, to directly establish connections with subscribers of another network of the KSS, that is, communication systems that include subsystems that are incompatible via an external interface, such as a radio interface.

Of particular practical interest is the relaying of signals from the external environment to buried spaces (for example, transport tunnels) provided by KSS.

A similar problem was solved during the creation of the Lefortovo transport tunnel in Moscow (Shishkov S.Yu. Dispatching the power supply system of the Lefortovo transport tunnel using the new generation of Dekont controllers // Industrial Automated Control Systems and Controllers, 2008, No. 3, p. 9), system communication in which is a prototype of the present invention. The relay of signals from the external environment to the tunnel and vice versa is carried out using repeaters, each of which is built on the basis of two stationary radio stations operating in cross-relay mode. The transceivers of the repeater are connected through the controller, with which low-frequency paths of the transmitters and receivers are connected crosswise. Repeater radios communicate with mobile and portable subscriber stations in an appropriate environment. If it is necessary to establish connections between subscriber stations located in different environments, the signals received by the repeater radio station from the outside using a specialized controller are converted into signals received by the radio station operating in the tunnel, and vice versa. The frequencies of the repeater in the tunnel are similar to the frequencies of the external city (territorial) repeaters of the corresponding services. This enables subscriber stations to operate in both environments at their own frequencies, that is, without switching channels. To separate the signals of urban (territorial) repeaters and tunnel repeaters, codes specially designed to ensure identification of the respective repeaters in those areas of the tunnel where radio signals can pass from the outside to the tunnel and vice versa can be entered into their signals.

However, this principle of relaying signals has a number of disadvantages: it is not possible to connect and work between subscriber stations belonging to different radio networks; connection and operation between two subscriber stations located in the same environment is not ensured; connection and operation of subscriber stations using different operating modes (duplex, simplex) is not provided.

In addition, the transmission of information from a subscriber of one communication network of an object to a subscriber of another network can be carried out only with the help of an object manager as an intermediary. This significantly increases the load on the dispatcher, whose main function is to ensure the safe operation of the facility and to supervise the necessary technical measures both in normal operation and in emergency situations. In case of failure of the control room equipment (for example, as a result of an emergency), the establishment of interconnections with this option is impossible, which reduces the overall reliability of the KSS.

A method for transmitting information in heterogeneous wireless communication networks is known from the description of the patent application US 2008/0056210 A1 (published on March 6, 2008). According to this method, it is intended to use a specialized device (server) located on a moving vehicle that provides transparent access for the user to various external information networks.

However, at the same time, it is necessary to provide everyone who needs the possibility of this connection with external systems (vehicles and individuals) with additional equipment, which, when the number of subscribers is large, requires significant costs. In addition, in this way it is impossible to provide communication for those people who stay within the facility for a short time, which is especially important, in particular, for public transport systems, as well as for various rescue, emergency, repair and other services arriving at the facility in emergency and emergency situations.

The claimed invention allows to overcome these disadvantages of the known technical solutions.

The main objectives of the present invention are: maximum adaptation of the functionality of communication systems to the administrative and industrial-technological structure of objects for various purposes and user requirements; improving the reliability of the functioning of systems and the availability of communication through mutual functional reservation of various communication networks of objects; providing opportunities for the long-term development of object communication systems by creating additional functional resources for connecting new generation networks to them; ensuring high technical and economic indicators of communication networks.

When creating a KSS, one of the determining conditions is the maximum use of the functionality of each of the subsystems (networks) that are part of the KSS of the facility and perform specific tasks, usually oriented to a specific user segment (management, operational and technical measures, security, elimination consequences of emergency and emergency situations, etc.). The integrated capabilities of the KSS are considered mainly as additional functionality, providing the possibility of direct information exchange between subscribers of various subsystems in situations provided for by the relevant regulations for the operation of facilities, and especially in emergency and emergency situations. At the same time, the modernization of subscriber terminals used in each of the subsystems of the KSS facility is not required.

The main differences between the KSS of the object of the present invention are: the ability to integrate trunking and conventional radio communications networks operating at the facility, telephone and emergency dispatch networks, broadband wireless access and other communication networks based on the use of intersystem (internetwork) programmable gateway switches; the use of modular programmable switch-gateways (MPCS) with connection to each of the input / output modules of integrated communication subsystems and the interaction of the modules using a software control unit or a personal computer with corresponding consoles; the ability to relay signals from one physical medium to another, for example, from a transport tunnel to the external environment and vice versa; the ability to save and further use the communication networks operating at the facilities by integrating them with new generation networks; the ability to integrate various communication networks operating in adjacent territories with a virtual expansion of their coverage areas; the possibility of ensuring, with the help of the MPPCS reserve capacity, the interaction of communication tools used by units of various departments and services arriving at facilities in emergency situations with communication networks operating at facilities.

The invention ensures the achievement of technical results, expressed in: increasing the security and overall reliability of communications through the integration and mutual redundancy of all communication networks of objects; expanding the coverage of each of the integrated communication networks operating in adjacent territories; expanding the list of telecommunications services provided to users, including through interconnections for subscribers; which together leads to an increase in the reliability and efficiency of facility management, rescue and repair measures in emergency situations with virtually no increase in the volume of equipment involved in them.

These technical results are achieved due to the fact that the method of switching subscribers in heterogeneous networks of an integrated communication system is characterized in that the calling subscriber is a user of the first communication network, and the called subscriber is a user of the second communication network, while receiving a signal from the calling subscriber transmitted through the communication channel the first network, allocate the number of the called subscriber in the received signal, determine the second network by this number, provide end-to-end switching of low-frequency paths analog and / or digital channels directly involved in the required network connection, and converting the signals to pass them from one network to another, determine the number of the called subscriber in the second network, transmit a signal through the communication channel of the second network to establish a connection with the called subscriber.

In the particular case of the implementation of this method in the switched low-frequency paths, the required diagrams of signal levels in the communication channels are set.

In another particular case of the implementation of the method in switched low-frequency paths, the control and synchronization signals are matched.

In another particular case of the implementation of the method in switched low-frequency paths, the modes of signal reception / transmission are agreed.

These technical results are also achieved due to the fact that the SSS of the object, which includes heterogeneous communication networks, is characterized by the fact that the networks are interconnected via a gateway node (UMC), configured to receive a signal from the calling subscriber, highlighting the number of the called number in the received signal the subscriber, determining the given number of the called subscriber’s network, ensuring end-to-end switching of the low-frequency channel paths directly involved in the required network connection, and mations for propagating signals from one network to another, and also to determine the called number in its network and transmission over the communication channel signal of the network to establish a connection with the called subscriber.

In the particular case of performing KSS is a multiple radio reception system.

In other special cases, the UMC is configured to install signal level diagrams in communication channels, or is configured to match control and synchronization signals in switched low-frequency paths, or is configured to match signal reception / transmission modes in switched low-frequency paths.

The indicated technical results are also achieved due to the fact that according to the second embodiment, the SSS of an object, which includes heterogeneous communication networks, is characterized by the fact that the networks are interconnected via UMS containing MPPC and a control device. Moreover, the MPPCS modules are made with the possibility of direct connection between each other, each network is connected to its own module of the switch-gateway of the corresponding type. The control device is configured to extract, in the signal received when the connection is established, the number of the called subscriber, determine the called number from the given network number and determine the number of the called subscriber in his network, establish interconnections between the gateway switches.

In the particular case of performing KSS networks are interconnected through more than one UMS. At the same time, the KSS is made with the possibility of choosing a switching path based on the state of employment and throughput of communication channels.

In another particular case, KSS is characterized by the fact that the control device is capable of transcoding the subscriber numbers of the complex communication system of the object into the subscriber numbers of internal numbering systems of the corresponding heterogeneous communication networks.

In another particular case, the control device and the switch-gateways are configured to convert signals to obtain the desired diagrams of their levels in communication channels, matching control signals and synchronization, as well as matching modes of signal reception / transmission.

Also in the particular case, the control device is configured to select the best signal received over different communication channels according to the signal-to-noise criteria and the number of errors.

In another particular case, the control device is configured to allocate system resources based on given priorities.

In another particular case, the KSS is characterized by the fact that heterogeneous communication networks are the network / networks of trunking, conventional radio communications, broadband wireless access, technological VHF radio communications, radiotelephone communications / radio access, production telephony, emergency dispatch communications, emergency alerts on wired and / or broadcasting.

The structural diagram of the KSS object is shown in the drawing.

The invention is as follows.

An example of a facility equipped with KSS is a transport tunnel. The KSS of the transport tunnel includes a technological VHF radio communication network, a radiotelephone / radio access network, a production telephone communication network, an emergency dispatch communication network, and an emergency warning network on FM broadcast channels. Moreover, this technical solution includes a multiple radio reception system.

The main elements of this system are UMS 1, containing a control unit (control unit, not shown in the drawing) and MPPC (shown in the drawing as a combination of modules 3, 4, 5 - N), as well as a switchboard for control rooms (KDP) 2.

A feature of UMS 1 is the modular construction and the possibility of combining modules into groups. This allows on the basis of UMC 1 to organize the joint work of different types of radio networks, despite the difference in the applied communication standards (protocols), frequency ranges and operating modes.

KDP 2 also has a modular structure and is designed to provide the ability to connect dispatchers to UMS 1. Depending on the composition of the network, the principles of communication, the composition and functions of dispatchers in the system, more than one UMS can be used, access to which dispatchers are carried out using KDP.

UMS 1 contains modules MPPC 3, 4, 5, 6, 7 - N and control unit connected to each module. Structurally, the MPPC are built on the basis of a SNV-12 type comparator manufactured by Raytheon JPS Communications and produced in the form of blocks. The unit includes 12 modules connected to transceivers, a processor module, an interface module, and a power supply module. Up to three blocks can be combined into a single system. At the same time, the MPPCS design allows you to directly connect them together. IPPC allows using through these modules end-to-end switching of low-frequency analog and / or digital channel paths directly involved in the required network connection, all necessary signal transformations for passing them from one network to another, as well as establishing the required diagrams of their levels in communication channels, coordination control and synchronization signals and coordination of signal reception / transmission modes (duplex, half duplex or simplex).

Since the subscribers of all communication networks are simultaneously considered as KSS subscribers, within the framework of which a unified external numbering system is installed, the control unit is configured to select the called number of the called subscriber when the connection is established, determine the called subscriber's network number and determine numbers of the called subscriber in his network. The control unit is also configured to distribute system resources based on predetermined priorities.

For clarity, the figure shows only the elements of the VHF radio network.

The repeater of the city (territorial) subdivision of the corresponding radio network has a transmission frequency f ₁ and a reception frequency f ₂ . Two transponders are installed at the facility for each radio channel: a repeater P _n 8 operating on an external environment and a repeater P _t 9 operating in a tunnel. Each of these repeaters is connected at a low frequency to a separate module UMS 1 through wired lines. The repeater R _n 8 has a transmission frequency f ₂ and a reception frequency f ₁ , which is necessary for working with a city repeater. The repeater R _t 9, by analogy with the repeater of the urban unit, uses the frequency f ₁ for transmission, and the frequency f ₂ for reception.

The structure of the repeater R _n 8 includes a transmitter of the relay (Rx _n ) 81 and a receiver of the relay (Rx _n ) 82. Similarly, the structure of the relay PT 9 includes a transmitter of the relay (Rx _t ) 91 and a receiver of the relay (Rx _t ) 92.

Tx _N 81 and Rx _N 82 are connected to the antenna-feeder system (APS) 83, and Rx _t 91 and Rx _t 92 are connected to a signal input / output device (UVVS) in / out of a radiating coaxial cable (CIR) 10, using which in the tunnel propagates all the radio signals.

The signal received by the relay P _n 8 at a frequency f _{1 is} demodulated and transmitted to the corresponding module 3 of the UMC 1 via a wired line in the form of an analog signal or in the form of packet data via TCP / IP. UMS 1 transmits the received signal from module 3 to module 4, to which the repeater P _t 9 is connected. The signal is transmitted to the repeater P _t 9 via a wired communication line, and then is transmitted to the tunnel at a frequency f ₁ . Accordingly, subscribers in the tunnel receive this signal and answer the call at a frequency f ₂ , which is the receiving frequency of the relay P _t 9. Next, the received signal is transmitted via wire lines to the UMC 1, processed by it and emitted by the relay P _n 8 at a frequency f ₂ .

An additional remote receiver 11 can be connected to one of the UMS modules 1 that are part of the group used by this radio network at a low frequency through the drive line. The drawing shows the connection of the additional remote receiver 11 with UMS 1 module 5.

An additional remote receiver 11 provides the necessary energy balance of radio communications based on the KIC 10 and the quality of communication.

UMS 1 constantly selects the best signal received by the receivers 92 and 11 according to the signal-to-noise criteria and the number of errors and transmits to the relay R _n 8 for radiation in the external environment in the direction of the repeater of the city unit.

If it is necessary to connect a subscriber station of a given radio network to a subscriber station of another radio network, the received UMC 1 signals are transmitted to the modules of the group used by the other radio network and vice versa.

Specialized control panels installed at the dispatchers' workstations are connected via wired communication lines to the KDP 2 dispatch modules and, through switching with the corresponding interface modules, to the required UMS 1 interface modules, which provides the dispatchers with the opportunity of direct priority connection to the modules of any of the groups, and therefore, the ability to connect and work with subscribers of any of the radio networks connected to one or more UMS 1.

The general algorithm for establishing interconnections, that is, switching subscribers, is illustrated by the following example of the connection of the subscriber (subscriber “A”) of the technological VHF radio communication network (Network-1) with the subscriber (subscriber “B”) of the radiotelephone communication / radio access network (Network-2). Subscriber "A" using the subscriber terminal Network-1 sends a call to his network and the number of the called subscriber (subscriber "B") assigned to him in the KSS. For subscriber “A”, the entire procedure for establishing a connection is similar to the procedure for establishing connections with subscribers of its Network-1.

The UMS control device 1 identifies the caller as a Network-1 subscriber, and by the transmitted number identifies the caller as a Network-2 subscriber. The control device determines in UMC 1 the corresponding switching point, which provides end-to-end connection of low-frequency analog and / or digital paths of those Network-1 and Network-2 channels that are directly used in this network connection, as well as the gateways necessary for this connection.

For subscriber “A”, the entire procedure for establishing a connection is similar to the procedure for establishing connections in your own Network-1.

Next, the control device transcodes the number of the called subscriber (subscriber "B") from the number in the KSS to the number assigned to him in his network. The call to subscriber "B" is transferred to Network-2. For subscriber B, the whole procedure for receiving a call and establishing a connection is similar to the procedure for establishing connections in your own Network-2.

By means of control signals from the UMC control device 1, through the selected gateways, the low-frequency paths are end-to-end and the necessary diagrams of the transmitted signal levels are established in them, the control and synchronization signals are transcoded and matched, and the signal transmission / reception modes, such as, for example, duplex, half duplex, are matched simplex.

This algorithm for establishing interconnections is implemented with all other options for connecting subscribers of networks that are part of the KSS. If necessary, interconnections can be carried out with the participation of the dispatcher, which is established programmatically in accordance with the established regulations for the operation of objects.

Thus, the invention provides the ability to integrate communication networks that are heterogeneous in technology, methods for transmitting and processing signals, signaling, etc., in contrast to existing options for integrating networks, usually of the same standard, distributed over various objects and territories, based on inter-network roaming. Thanks to the listed circuitry and design features, the invention provides the ability to integrate communication networks without changing the design, electrical parameters and functioning algorithms of subscriber terminals operating in each of the integrated networks, as well as without connecting additional equipment to them. A distinctive feature of the invention is the direct integration of networks using appropriate gateways at the level of dedicated low-frequency signals (information signals, control signals, etc.), which allows, in particular, to integrate radio communication networks that are different in frequency ranges, signal transmission methods, and radio interfaces, without making any changes to these system parameters, which would lead to a significant increase in complexity and an increase in the volume of subscriber and stationary equipment.

Claims (17)

1. A method for switching subscribers in heterogeneous networks of an integrated communication system, characterized in that the calling subscriber is a user of the first communication network, and the called subscriber is a user of the second communication network, while receiving a signal from the calling subscriber transmitted through the communication channel of the first network, the received signal, the number of the called subscriber, the second network is determined by this number, the end-to-end switching of low-frequency paths of analog and / or digital channels is provided, directly participating them in the required interconnection, and converting the signals for passing them from one network to another, determine the number of the called subscriber in the second network, transmit a signal through the communication channel of the second network to establish a connection with the called subscriber. 2. The method according to claim 1, characterized in that in the switched low-frequency paths set the desired diagrams of signal levels in the communication channels. 3. The method according to claim 1, characterized in that in the switched low-frequency paths, the control and synchronization signals are matched. 4. The method according to claim 1, characterized in that in the switched low-frequency paths agree on the modes of reception / transmission of signals. 5. A complex communication system of an object, which includes heterogeneous communication networks, characterized in that the networks are interconnected through an interconnect node, configured to receive a signal from a calling subscriber, highlighting the number of the called subscriber in the received signal, and determining the call number from this network number the subscriber, providing end-to-end switching of the low-frequency paths of the channels directly involved in the required internetwork connection, and signal conversion for their passage from one set in another, and also to determine the called number in its network and transmission over the communication channel signal of the network to establish a connection with the called subscriber. 6. The communication system according to claim 5, characterized in that it is a multiple radio reception system. 7. The communication system according to claim 5, characterized in that the gateway node is configured to install signal level diagrams in the communication channels. 8. The communication system according to claim 5, characterized in that the gateway node is configured to coordinate control and synchronization signals in switched low-frequency paths. 9. The communication system according to claim 5, characterized in that the node interconnect is made with the possibility of coordination in the switched low-frequency paths of the modes of reception / transmission of signals. 10. The complex communication system of the facility, which includes heterogeneous communication networks, characterized in that the networks are interconnected via a gateway node containing modular programmable gateway switches and a control device, while the gateway switch modules are designed to be directly connected to each other , each network is connected to its own module of the switch-gateway of the corresponding type, the control device is configured to highlight in the signal received when establishing the connection e number of the called subscriber, determining the number of this network and the called subscriber number identification callee in its network connectivity between modules gateway switches. 11. The communication system of claim 10, wherein the networks are interconnected via more than one gateway node. 12. The communication system according to claim 11, characterized in that it is configured to select a switching path based on the state of employment and bandwidth of the communication channels. 13. The communication system of claim 10, characterized in that the control device is configured to transcode the subscriber numbers of the complex communication system of the object into the subscriber numbers of internal numbering systems of the corresponding heterogeneous communication networks. 14. The communication system of claim 10, characterized in that the control device and the switch-gateways are configured to convert signals and set the desired diagrams of their levels in communication channels, matching control signals and synchronization, as well as matching modes of signal reception / transmission. 15. The communication system of claim 10, wherein the control device is configured to select the best signal received over different communication channels according to the signal-to-noise criteria and the number of errors. 16. The communication system of claim 10, characterized in that the control device is configured to distribute system resources, based on the given priorities. 17. The communication system of claim 10, characterized in that the heterogeneous communication networks are the network / network trunking, conventional radio communications, broadband wireless access, technological VHF radio communications, radiotelephone communications / radio access, industrial telephone communications, emergency dispatch communications, emergency alerts on wired and / or broadcast channels.