DE19826631A1 - Telecommunication device with a data connection - Google Patents

Abstract

The invention relates to a telecommunication device for a digital telecommunication network, comprising a subscriber exchange (LE), an access node (AN) and a management system (MS) for the telecommunication network. If required, a data link between the node management in the access nodes (AN) and the management system is established temporarily through one or several base channels (Lx-TSy). To this end, a virtual ISDN terminal (TE-v) is installed in the access node (AN) which dials the management system through the subscriber exchange (LE) for data communication. The virtual ISDN subscriber terminal exchange (TE-v) consists of a dial software (DU-SW), which can be dialed by the management system (MS) through an unequivocal address, in addition to a configuration software (CFG-SW) which executes the operational and maintenance functions (OA & M) in the access nodes (AN) and updates the operational software. The invention enables high data speed for file transfer services according to FTP(TCP/IP) or FTAM(OSI), especially in a V.5 interface.

Description

The invention relates to a telecommunications device in a digital Telecommunications network, such as the ISDN, with a bidirectional data connection between the node management in a subscriber access node (AN) and the management system (MS) of a telecommunications network. Such Connection uses the management system for operational and maintenance functions (OA), for polling services or for transferring software to update Operating software in the access node. In the present case, the access node connected to the local exchange via a V.5 interface.

To manage the resources of network devices in an ISDN network, such as for example to flexibly configure access node management node (AN) for subscriber connections in the context of the operational and maintenance radio tions exist between the management system of the telecommunications network and the network devices data connections. Such data connections are either implemented in the form of a separate data communication network (DCN), which provides separate data channels to the access nodes, or from Existing user channel connections are used overhead channels. Furthermore For this purpose, certain individuals are also used in some telecommunications networks User channels, which are usually used to transmit message signals from the Serve subscriber connections, keep them free.

However, existing solutions usually use them for economic reasons either a separate data communication network (DCN) or overhead channels. A separate data communication network must either as a modem network or as local data transmission network (LAN) can be established.

Complex network elements, such as large network nodes in the form of concentrators, are connected to the management system of the telecommunications network via a management interface (Q _AN ), which can be, for example, a standardized Q3 interface. With the help of configuration software installed in node management, the operator of the access node can use the management interface to adapt it to the respective tasks and operating conditions. The disadvantage, however, is that conventional Q _AN interfaces have a relatively low data rate, so that, for example, it takes several hours for the configuration of a new network node or for the operating software to be updated by software upgrades of a node used.

Management functions also have only a small number in overhead channels Data rate available. So there is hardly any possibility of telecommunications adapt the network sufficiently quickly and flexibly to changing operating conditions sen. In addition, continuous use of overhead channels is not in possible in all cases because the connections used are not at all levels of the Connection hierarchy in their multiplex frames have frame headers.

Especially equipment with interfaces V.5.1 and V.5.2 according to ITU-T recommendations Lungs G. 964 and G. 965 do not contain standardized options for Use of overhead channels for data communication from network management to the access node.

ITU-T recommendation G. 964 "V-Interfaces at the Digital Local Exchange (LE) -V.5.1-Interface (based on 2048 kBit / s) for the Support of Access Network (AN) ", Geneva: ITU 1994, defines an interface for ISDN subscriber exchanges and an access node, e.g. to a multiplexer, via a single 2048 kbit / s connection.

In contrast, ITU-T recommendation G. 965 defines "V-Interfaces at the Digital Local Exchange (LE) -V.5.2-Interface (based on 2048 kBit / s) for the Support of Acces Networks (AN) ", Geneva: ITU 1995, an interface for ISDN subscriber switching provide up to 16 separate 2048 kbps connections on the subscriber side as individual 2048 kbit / s connections as well as primary rate connection can be used.

Both interfaces are specially designed for the connection of extensive networked Apron facilities in the form of local loop networks instead of convents tional subscriber lines, and can be for access nodes directions from any manufacturer can be used without specific Special features of the manufacturer must be observed.

Each 2048 kbit / s connection L 1 to L n transmits according to the ITU-T recommendations G. 703 and G. 704 in time division multiplexing 32 time channels (TS 0 to TS 31), which according to the "A law" as pulse code modulation can be coded with 8 bits per sample. Regardless of the content, all time channels are available with a uniform basic data rate r _b = 64 kbit / s and have a fixed time sequence to each other in time division multiplex operation.

All 2048 kbit / s connections L 1 to L n have with respect to the transmission of Control and signal data have a uniform structure. The time channel TS 0 serves in everyone Connection to frame identification and frame synchronization. Part of the 64 kbit / s time channels TS 1 to TS 31 is also used for so-called "Communication Chan nels "(C channels). These contain data packets of one or more "Communication Paths" (C branches), mostly of different types, with data for the Signaling, protocol control and ISDN data from subscriber lines. The C channels are in the special case of a V.5 interface depending on the configuration for the Location of some of the time channels TS 15, TS 16, TS 31.

The remaining time channels are available as user channels and transmit message signals. The C channels of the V.5 interfaces communicate via the connection access protocol LAPV5, which is standardized in ITU-T recommendations G. 964 and G. 965. This is based on the access protocol LAPD of the data channel in accordance with ITU-T recommendations Q.920 and Q.921. However, the LAPV5 protocol and the C-channel data frame are more complex than with the D-channel because of the variety of C-branches and the addresses they contain. The data channels D ₁₆ from ISDN terminals or the data channels D ₆₄ can therefore not communicate directly with the C channels of the interface V.5.2 due to the various data frame formats. This is only possible by adapting the protocol and frame structures using a mapping function and a frame relay function. The data packets of the various C branches are separated or combined depending on the transmission direction and converted into the corresponding multiplex structure and protocol form.

The protocol architecture present in an access node with a V.5 interface is shown in ITU-T recommendations G. 964 and G. 965, section 8.2 in conjunction with FIG. 6, and section 8.5 . Then the layer 2 protocol functions in the access node are divided into sub-layers. These are the so-called "Enveloping Function" sub-layer LAPV5-EF, which supports the transition from and to the C-channel protocol, the "AN Frame Relay" sub-layer AN-FR, which supports the transition between the LAPV5 data frame and the LAPD Data frames realized, and the "Data Link" sublayer LAPV5-DL. In the present description, FIG. 2 shows excerpts of the protocol architecture for the access node in the form of function block V.5.2-PM.

Since only a small number of participants are involved in the practical operation of an access node a connection between the access node and the subscriber at the same time mer switching center, manages the switching according to the standards set the time channels available as user channels to the access node and points these dynamically according to the connection requirement.

The invention has the task of an inexpensive data connection between an access node and the management system, which show a high Data rate requires no additional hardware and as little as possible valuable useful channel capacity.

To solve the problem, an additional is in the access node according to the invention Liche software component is installed, which subsequently as selection software referred to as. The selection software forms together with a configuration software in the access node a virtual ISDN terminal device, which from the side the subscriber exchange on the connection layer via a unique Address can be selected.

As part of the self-dial function, the management system sends a call to virtual ISDN terminal equipment. After accepting the call by dialing software switches the subscriber exchange for a limited time an n × 64 kBit / s Ver binding between the management system and a configuration software in the Network access node. The local exchange uses between Subscriber exchange and access node at least one time channel Interface that it otherwise assigns as a useful channel. This enables management system bidirectional data communication with the configuration software of the access node with a high data rate.

The invention is explained below using an exemplary embodiment become. The associated drawings show:

Fig. 1 is a sample of a telecommunication network with the relevant for the invention network devices,

Fig. 2 details for explaining the function of the access node used.

Both drawings show only functional elements in the form of hardware and Software components. The excerpt from the telecommunications shown network was reduced to those functional units which are used to explain the Invention are absolutely necessary. These are for a better understanding of the invention represented in the form of functional units. These can be significant in practice executed more complex and in the form shown as individual real assemblies sometimes not be localizable.

Fig. 1 shows a local exchange LE and an access node AN, wel che each other via a transport network are connected n STM. In the present example, the transport network STM n is designed in the form of a ring as a synchronous transport module STM 1, but can also be implemented in a different structure and / or with other multiplex stages of the plesiochronous digital hierarchy or the synchronous digital hierarchy. The network transitions from and to the lower hierarchical level implement branch multiplexers ADM, so-called add-drop multiplexers.

The interface between the local exchange LE and the transport network contains time-division multiplex connections based on ITU-T recommendations G 703 and G 704 with data rates of at least 2048 kbit / s and pulse frame structures with 125 µs duration. The access node AN and the local exchange LE are over the transport network STM n with an interface V.5.2 with n × 2048 kbit / s connection connections L 1 to L n as described above.

Each user channel connection between the access node AN and the telecommunications nication network runs in a separate time channel as a transparent connection a switching network GSW in the local exchange LE. The switching matrix GSW provides access to the time channels on the telecommunications network side the interface V.5.2 and mediates subscriber connections with terminals TE 1 or TE 2 of the access node AN. On the side of the access node AN access to individual time channels of interface V.5.2 through the interface device V.5-IF, which, depending on the communication direction, the time channels of the Interface V.5.2 multiplexed or demultiplexed, so that everyone regardless of the content Time channel is available separately. This can happen between these two access points Transport network have any shape.

In an access node device, configuration is usually for the operator  software CFG-SW in the form of management applications and programs for Update the operating software installed. With this, the operator realizes the Operation and maintenance function (OA) for the node.

To implement the invention, a virtual ISDN terminal TE-v is installed in the access node AN, as shown in FIG. 1, using software. In addition to the CFG-SW configuration software, another software component is installed, the DU-SW selection software.

The selection software DU-SW receives its own address in order to be able to dial the virtual ISDN terminal device TE-v on the part of the local exchange LE via a C channel. This address is assigned in the data link layer (layer 2 , according to the OSI reference model).

The management system MS is n × 64 over a standard ISDN connection kBit / s connected to the local loop exchange LE. The connection can be designed as a base channel connection or as a primary rate connection.

FIG. 2 shows further details of the exemplary embodiment with selected functional units of the access node AN with hardware and software components which are relevant for the implementation of the invention. The access to the C channels of the interface V.5.2 takes place in the access node via a functional unit, which is called the protocol engine V.5.2-PM below and is connected to the interface device V.5-IF. The protocol machine V.5.2-PM corresponds to the known version according to ITU-T recommendations G. 964 and G. 965, FIG. 6 and remains unchanged when compared to conventional use when used according to the invention.

The protocol machine V.5.2-PM realizes on layer 2 bidirectional data communication between the different sub-layers mentioned at the beginning by adapting the access protocols and the data frame structure. In the present case, the selection software DU-SW is designed so that the virtual ISDN subscriber line TE-v is reached via a 16 kbit / s data channel D ₁₆ .

A data connection between the C channel C _{64 of} the interface V.5.2 on which the call from the management system MS arrives and this D channel D ₁₆ must therefore be established. The selection is made from C channel C ₆₄ via the sub-layer LAPV5-EF. The complex LAPV5 data multiplex of the C channel with the data packets from different C branches is broken down into individual C branches in the mapping function and distributed to the other sublayers according to the layer 2 addresses. In the present case, the AN frame relay function AN-FR converts the call of the virtual ISDN terminal device contained in a C branch into a D channel signal in LAPD format.

According to ITU-T recommendations G. 964, section 9, the address of the virtual ISDN terminal in layer 2 consists of a number with 13 bits in the number range 0. . . 8175.

The invention works as follows:
The management system MS sends a call to the address of the virtual ISDN terminal TE-v via the ISDN signaling, which the dialing software DU-SW accepts. The subscriber exchange LE between the management system MS and the interface device V.5-IF of the access node AN then builds up a temporary data connection on any other time channel Lx-TSy of the interface V.5.2 and the configuration software CFG-SW and the management system MS enter the desired data communication.

The switching network GSW thus mediates in addition to subscriber connections with konven tional terminals TE 1 or TE 2 also have a data connection on request between management system MS and the virtual ISDN terminal TE-v via a time channel Lx-TSy of the interface V.5.2, which the subscriber exchange LE flexibly managed as a user channel.

According to a further development of the invention, the selection software can be accessed nodes are asked by the subscriber exchange LE to increase a bundle of 64 kbit / s connection ready for the transmission speed put. In this case, the selection software establishes a temporary data connection, which extends over several time channels in the V.5 interface.

The temporary data connection can be used between the management system and the node management can be used for any type of data communication Operating and maintenance tasks, polling services and upgrades of the operating software,  the transmission speed being flexible according to the application can be adjusted. For updating the operating software, various known data transmission services are used, such as that So-called "File Transfer Access and Management - FTAM" according to the recommendation ISO 8571 or the "File Transfer Protocol - FTP" known from the Internet. To this For example, the operating software or the configuration software CFG-SW of the node are updated.

A major advantage of the invention is that if necessary without change the standardized V.5 protocol with the help of ISDN signaling very quickly a bidirectional n × 64 kbit / s data connection on one or more 64 kbit / s user channels can be set up. The connection capacity required for this is available outside of temporary data communication for user channels.

To implement the invention, the operator of an access node device just install the selection software DU-SW and the configuration software adapt the invention.

Claims (7)

1. Telecommunications device for a digital telecommunications network with a subscriber exchange (LE), an access node (AN), which has a node management, and with a data connection between the node management and a management system (MS), which at least between the subscriber exchange (LE) and the access node (AN) of the telecommunications network uses a base channel (Lx-TSy) set up as a useful channel, characterized in that
that a virtual ISDN terminal (TE-v) is installed in the access node (AN), which can be selected by the management system (MS) via a unique address in the connection layer and
that when the virtual ISDN terminal device (TE-v) is selected, a base channel (Lx-TSy) is temporarily provided for the data connection, which the subscriber exchange (LE) manages dynamically. 2. Telecommunication device according to claim 1, characterized in that A selection software (DU-SW) is installed in the access node (AN), which together with a configuration software (CFG-SW) the virtual ISDN subscriber line (TE-v) forms. 3. Telecommunication device according to claim 2, characterized in that the selection software (DU-SW) when dialing from the management system (MS) Configuration software (C FG-SW) activated so that this data communication with the management system (MS). 4. Telecommunications device according to claim 1, characterized in that the access node (AN) and the subscriber exchange (LE) via one V.5 interface are connected. 5. Telecommunications device according to claim 3, characterized in that the subscriber exchange (LE) the base channel (Lx-TSy) by a dynamic channel assignment managed as a user channel if no selection of Side of the management system. 6. Telecommunication device according to claim 1, characterized in that the selection software (DU-SW) is installed at a terminal of the access node (AN) for a data channel (D ₁₆ ) and communicates via its access protocol (LAPD). 7. Data connection according to claim 1 and 2, characterized in that the Subscriber exchange (LE) on request by management system (MS) for increasing the transmission speed an n × 64 provides kbit / s connection with several base channels.