WO2003047278A1 - Message handling method for signalling system no. 7 and a system of this type - Google Patents

Abstract

The invention relates to a message handling method for signalling system no. 7, in addition to a system of this type comprising the following steps or devices for carrying out the following steps: message guidance (9, 10; 23) for sending a message to a target address; message distribution (7, 8; 24) for delivering the message to the correct recipient within the node, whereby the message guidance step handles an address within the node in the same manner as an address external to the node.

Description

description

Message handling procedure for a signaling system No. 7 and system

This invention relates to a

Message handling method for a signaling system No. 7 according to the preamble of claim 1 and a system according to the preamble of claim 7.

The signaling system No. 7 was already used for digital switching centers in the United States in the early 1980s. It has now become the international basis for the exchange of signaling messages between digital exchanges. It was the first central channel signaling system, i.e. In this system, the user channels were treated separately from the signaling channels for the first time. The signaling information is transmitted together for many user channels in one or more 64 Kbit / s signaling channels. Such signaling channels correspond to the user channels and can therefore be treated like user channels, i.e. they can be switched through switching networks without processing the signaling of the channels. This in turn results in signaling end points (SEP) within the network

Signaling transfer points (STP). The generic term for SEP and STP is signaling points (SP: signaling points) or nodes. Together with signaling channels, the SPs form their own signaling network, which can be viewed completely separately from the useful path network. The connection in the utility network is controlled by the exchanged signaling in the signaling network. This is described, for example, in "Technik der Netze" by Gert Siegmund, Rv Decker 's Verlag, Heidelberg, 1996. In signaling networks according to signaling system No. 7, incoming messages are transferred to a message handling device in a message transfer part. This

Facility must determine whether the message is for its own node, i.e. the message should be sent to an internal node address or whether it should be forwarded to an external address. According to the ITU-T Q.70x recommendations, in particular the ITU-T Q.704 recommendation, message handling takes place in three steps, which is shown in FIG. 3. The messages are first fed to the message distinction 33 from a signaling channel 22. By checking the destination address of the received message, this determines whether the message is intended for its own node or not. If the message is intended for its own node, it is forwarded to the message distribution 35, which delivers the message to the correct recipient inside the node. If the message is not intended for its own node, it is passed to the message control 34, which forwards the message in the direction of the destination address via a signaling channel 22 to another node. In addition, the message routing device 34 receives messages from its own node via the line 36.

The two-stage message handling explained with reference to FIG. 3 has advantages if a majority of the messages are intended for internal node addresses. Conventional SPs contain both a SEP functionality (signaling endpoint) for the network route network and an STP functionality for the signaling network. If you only consider the modules that provide the SEP functionality, almost 100% of the messages generated are intended for internal recipients. It is completely different with the STP functionality: Here only 1 to 2% of the

Messages intended for your own node. Since the SPs in conventional networks include both a SEP and an STP functionality, approximately 80 to 90% of the messages are intended for the own node.

If, according to the ITU-T recommendations, each node in a signaling network is known by only one address, message distinction is a simple function that is configured only by setting the address of the corresponding node. No special mechanisms or data structures are therefore required to access this address, which is necessary for the comparison with the destination address of an incoming message.

In the recent past, there has been a consolidation of exchanges in the telecommunications sector. In addition, the telecommunications market has been deregulated in many countries, so that instead of a monopoly company, several companies now offer their telecommunications services.

Due to the changes in the telecommunications sector, the need has been increased to implement the logical separation of the useful network and the signaling network even in the hardware configuration of the networks. Switching systems were therefore developed that can be operated as standalone STP, e.g. the SSNC (Signaling System Network Control) from Siemens.

The changes in the telecommunications sector also created the need to share an exchange between several companies. For this reason, it is desirable that a signaling point in a signaling network be addressable under multiple addresses. The number of these different addresses remains of a node is small, the message distinction can simply be expanded in such a way that all addresses of the node are checked one after the other. For example, Bellcore asked for four addresses per node for the US market.

If, for example, the number of addresses per node increases to 64, as intended for the exchange manufactured by Siemens for the US market (EWSD (electronically controlled digital dialing system), this requires a different solution. This can consist in the introduction of a bit vector which determines for each address in the address space whether a separate node is thereby identified. For signaling networks in accordance with the ITU-T-Q.7Ox recommendations, such a vector would be 2048 bytes (2 ¹⁴ bits) long. For networks in accordance with ANSI / Bellcore specifications that use addresses of 24 bit length, the bit vector would have a length of 2 Mbytes (2 ²⁴ bit). For an EWSD that is equipped with a signaling system of the type CCNC (Common Channel Network Control) for the US market, a method is used that only requires about 3 KB of memory. However, this method has the disadvantage that there are restrictions on the possible values of the internal address. In addition, up to four comparisons are required for each message discrimination process.

The object of the invention is to provide an effective message handling method and a system.

This task is accomplished by a

Message handling method according to claim 1 and a system according to claim 7 solved.

An advantage of the solution according to the invention is that all the devices, that is to say data structures and functions, are already present in the message routing in order to use the destination address of a message to determine where the

Message should be forwarded. For external

The signaling channel must be determined for address-oriented messages. Ultimately, a process for which the message is intended must be determined for internal destination addresses. The correct signaling channel or the next internal process on the way to the target process are collectively referred to as a link set. The

Message routing only needs to be expanded in such a way that the internal addresses can simply be

Data structures of the routing are included. As a result, these data structures are usually only slightly enlarged and the computing power required for message routing is also only slightly increased.

When using the invention

Message handling method or the system according to the invention in an STP, the small proportion of 1 to 2% of internal messages makes the small increase in computing power plausible.

Furthermore, with the invention

Message handling procedures and the corresponding system practically no limitation of the address pool associated, which is significantly smaller than the size of the address space itself.

The message handling method according to the invention and the corresponding system can also be used in nodes with a single self-address.

Because for the invention

Message handling procedures and the corresponding system no new functions or data structures need to be implemented, the implementation is simplified and is therefore more robust. Since the message handling method according to the invention and the corresponding system do not require the step of message differentiation before the step of message distribution, the

Message routing, especially for messages that use the node only as a transfer point, is accelerated.

Another advantage of the message handling method according to the invention and the corresponding system is that all functions for transfer traffic associated with message routing, such as e.g. Screening (prevention of unauthorized use) or accounting (supplying basic information for the creation of bills), which are carried out on the basis of the DPC field, automatically or by simple extension also record the traffic terminated in the node. This recording of SEP traffic is an extension of the recording previously defined in the ITU-T standard Q.7 52.

Preferred embodiments of the invention are explained in more detail below with reference to the accompanying drawings.

1 shows an exemplary representation of a system with a message distinction integrated in the message routing.

Fig. 2 shows a schematic representation of the message handling, in which the

Message differentiation is integrated in the routing.

3 shows a message handling according to ITU-T Q.704. The message handling 21 shown in FIG. 2 only includes the message routing 23 and the message distribution 25. Since the data structures in the message distribution contain not only node-external addresses but also all node-internal addresses, the message distribution 25 also takes over the functionality of the message differentiation. Since, as mentioned above, in standalone STPs or if one only looks at the STP functionality in SPs, only 1 to 2% of the messages are directed to addresses within the node, the use of the functions intended for message distribution leads to none or even for addresses within the node to insignificant performance losses. As mentioned above, the function required for message differentiation is simple as long as only one node-internal address or in any case a small number of node-internal addresses need to be managed.

Fig. 1 shows an exemplary representation of a system with integrated in the routing

Message discrimination. Reference number 1 refers to an STP, e.g. to the SSNC (signaling system network control) offered by Siemens. An SSNC can provide the STP functionality in an SP or can also be used as a stand-alone STP.

1 shows a platform 2 terminating a first character channel and a platform 3 terminating a second character channel. Each of the platforms 2 and 3 terminating the character channel is connected to other exchanges via signaling channels 5 and 6, respectively. The signaling channels can be bundled into groups of signaling channels.

The signaling-terminating platforms receive, among other things, MSU messages (MSU: message signaling unit) via the signaling channels. By MSU Messages are transmitted signaling messages of layer 3 in accordance with ITU-T Q.704. MSU messages contain a DPC field (destination point code) and an SLS field (signaling link selection field). The SLS field and the DPC field in ITU-T Q.70x based sinalization networks are 4 and 14 bits, respectively. With ANSI Tl.111, the corresponding lengths are 8 bits for the SLS field and 24 bits for the DPC field. The DPC field contains an address that is unique throughout the network. The SLS field denotes a signaling channel of several signaling channels that lead to the same target node. Furthermore, the message routings 9 and 10 receive messages from the signaling system No. 7 via the links 11 and 12, respectively. These are end-to-end messages (peer-to-peer messages).

In the case of the message routing 9 and 10, the messages received by them are forwarded via the signaling channels 5 and 6 to another switching center, to the respective other message routing or to the message distributions 7 and 8. For this purpose, a process ID (ID: identification) is determined in the message control based on the DPC field in the MSU messages.

If the address of an MSU points to another node, the process ID determined in routing 9 or 10 refers to the process which carries out the outgoing routing on the platform terminating the selected outgoing signaling channel. Typically, an MSU goes through several layers before being transmitted over the signaling channel. For example, check bits are added in layer 2 for secure transmission of the message.

Message distributions 7 and 8 include

Message distribution processes 7a to 7c and 8a to 8c. Each of the message distribution processes 7a to 7c and 8a up to 8c manages one or more internal node addresses and has a process ID. The

Finally, message distribution processes pass the messages on to other platforms 13. This means application programs in the exchange, which e.g. the construction and dismantling of user channels in

Carry out utility network.

In order to determine the process ID, a two-column table can be stored in the routing, which assign the process IDs to addresses in the DPC field. In another embodiment, a tree structure can be stored in the routing of the messages, via which the addresses of the DPC field are linked with corresponding process IDs. The advantage of a tree structure is that it can be searched faster.

After determining the process ID, the operating system delivers the message to the identified process. This process can be on the same or a different platform.

The message routing 9 or 10 forwards messages directed to internal node addresses to the message distribution 7 or 8 assigned to it. In contrast, it forwards messages directed to addresses external to the node to the signaling channels 5 and 6 connected to it. It can happen that the message routing 10 receives messages for external nodes that can only be reached via one of the signaling channels 5 or that has to send messages to internal addresses via the message distribution 7 to internal addresses. The routing 10 first sends such messages to the routing 9. The same applies to the routing 9. In another

Embodiment additional connections are provided so that the message routing 10 messages without detour via the routing 9 directly to the

Message distribution 7 can send. In this

In an embodiment, connections are preferably also provided such that the message routing 9 can send messages directly to the message distribution 8.

Claims

claims

1. Message handling method for a signaling system No. 7, which comprises the following steps: message routing (9, 10; 23) for sending a message in the direction of a destination address message distribution (7, 8; 24) for delivery of the message to the correct internal node recipient, characterized in that the message routing step treats both an in-node and an out-of-node address in the same manner.

2. Message handling method according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the

A plurality of addresses is assigned to the node in which the message handling method is carried out.

3. Message handling method according to one of the above claims, characterized in that the step of routing comprises the substep of determining a process ID of the process that has to process the message further, the process ID being determined on the basis of the DPC and / or the SLS field becomes.

4. The message handling method according to claim 3, so that the identified process is the one that sends the message on the outgoing signaling channel (5, 6; 22) to be selected if the address of the message is an internal node address.

5. Message handling method according to claim 3 or 4, characterized in that the identified process a message distribution process

(7a-7c, 8a-8c) who is responsible for the further delivery of the message to the corresponding internal address.

6. Message handling method according to one of the preceding claims, so that it is carried out in a system which complies with the ITU-T Q.7Ox recommendation or the ANSI Tl.111 standard.

7. Message handling method according to one of the preceding claims, wherein the message routing step generates message-accompanying data in which a bit indicates whether the corresponding

Message is intended for an internal or external address.

8. A system which implements a signaling system No. 7, comprising: a message routing device (23) for

Sending a message towards a destination address; a message distribution device (24) for delivering the message to the correct internal node recipient, since the message routing device has units that process both internal and external addresses.