EP1186133A1 - Method and device for selective message transmission - Google Patents

Abstract

Several message flows that are independent of one another (e.g. messages for different addressees) are frequently transmitted via a message path having a transmission protocol with secured message transmission. Since the transmission protocol cannot often distinguish the message flows, the delivery of messages of a message flow is delayed due to the fact that a previous message of another message flow has been lost and must be repeated. The invention solves the above-mentioned problem.

Description

description

METHOD AND DEVICE FOR SELECTIVE MESSAGE TRANSMISSION

1. What technical problem should your invention solve?

2. How has this problem been solved so far?

3. How does your invention solve the stated technical problem (give advantages)?

4. Embodiment (s) of the invention.

5. Drawing

to 1.

In many applications, a message path that has a transmission protocol with secure message transmission is used to send several independent message streams, i.e. Transmit messages for different recipients or for different, mutually independent activities of a recipient, with a user of the message link, e.g. a certain class of a higher protocol layer is to be understood.

Since secure message transmission normally also requires delivery of the messages in the same order in which they were sent, but the transmission protocol often cannot distinguish the message streams, it can happen that the delivery of the messages of a message stream is delayed because one or more previous messages from one or more other message streams have been lost and must be repeated. The problem is not solved directly in the existing ITU-T signaling system No. 7. However, by using several (up to 16) transmission links (which is often the case especially when using the MTP of level 2 (according to ITU-T recommendation Q.703)), a certain decoupling of the data streams between two signaling points ( the signaling route selection fields are used for ITU 16, for ANSI 256 data streams are achieved) because transmission errors on a transmission route

(Link) does not affect the flow of messages on other transmission links.

In the broadband signaling network, however, because of the use of high-capacity transmission links, multiple transmission links are rarely used (more than two are normally not necessary). Therefore, the independent data streams are separated much less. The protocol used (SSCOP, Q.2110) also offers no possibility to differentiate between different data streams.

To 3.

The present invention shows how existing protocols using the so-called "multiple-selective retransmission" method (MSR) - and in particular SSCOP

(Q.2110) or derived protocols - in simple

Way can be expanded with functions that solve the problem described under 1. (Inset: In contrast to the so-called Go-Back-N method, in which when a

Error / loss, all data packets from this error / loss are retransmitted, even if subsequent data packets have already been sent without errors, only the actually incorrect / lost data packets are retransmitted in the selective reject process. MSR procedures allow the existence of multiple gaps in the data stream and can repeat several or all missing data with a single request).

The invention includes based on the following findings: SSCOP can be easily expanded to deliver messages "out-of-sequence". This means that another protocol level can then be assigned to its users (applications), i.e. easily provide higher-level protocols with streams that cannot block each other.

When using implicit characteristics, i.e. of information already contained in data and / or protocol information of the higher protocol levels, e.g. of the SLS field according to Q.704 or Q.2210 for the identification of the currents, these can be transparently introduced as non-mutually blocking currents for higher protocol levels, i.e. without the higher protocols adapting to the introduction of the currents or having to know about them.

In the exemplary embodiment SSCOP / SSCF considered here, based on the protocol stack in FIG. 2, it is advantageous to split the problem of secured, sequence-accurate message transmission into mutually independent streams into two partial problems and to solve one partial problem in SSCOP and the other in SSCF. However, this decomposition is not mandatory and is not necessarily advantageous even if the protocol to be modified does not already have a layer structure.

The following describes a two-stage solution and the advantages of this structuring with SSCOP / SSCF. In a first stage, SSCOP - or another protocol which the so-called. "multiple-selective-retransmission" method used - expanded so that it is able to deliver messages immediately to the recipient of the message even if older messages have not yet been correctly received and delivered. All or only special messages can be delivered to the recipient immediately upon receipt, the term "immediately" being understood to mean that the delivery of these messages is not delayed by the detection of the loss of other messages. In the receive buffer used to establish the correct reception sequence, which is required by the protocol's receiving device for protocols using the "multiple-selective retransmission" method, messages intended for immediate delivery are therefore no longer buffered until all previous messages have been received, instead, it is advantageously only made a note (for example by storing and appropriately marking the sequence number, but not the data, of the received and delivered message in the reception buffer) that these messages have been correctly received and delivered to the recipient. As already mentioned, the delivery of these messages is not delayed by the loss of other messages. (It is of no importance for the present invention whether or not the data of these messages intended for immediate delivery are cached until all the previous messages are available, although the latter can be advantageous. The only important thing is the remark that these messages have already been delivered and therefore do not have to be sent to users again.)

Another advantage is that less memory has to be kept for receive buffers, since the data of such

Messages no longer need to be cached, but, for example, only their sequence numbers with the corresponding marking.

If only special (specific) messages are to be used by this function, a certain marking (marking) (such marking should not be confused with the marking of the sequence numbers of the messages already delivered, which were stored in the receive buffer), can be used in the messages made, or such messages are recognizable by their content. An example of the latter are messages which belong to SCCP class 0 (see Q.714) and which are identified by the value 0 in the protocol class parameter field of the SCCP message and for which applications (users of the SCCP) have an (essentially) reliable one but no delivery in the correct order is required.

It is also advantageous that in principle the immediate delivery to the recipient can take place without knowledge or modification of the transmitting device. On the other hand, the sending device can in principle label messages for immediate delivery without the receiving device of the protocol necessarily having to observe this labeling, ie the receiving device continues to deliver all messages completely and in the correct order to the next higher protocol level. This means that the advantage of immediate delivery of at least certain messages is no longer available, but the protocol still works correctly, ie the higher protocol levels receive all messages in the correct order. If an unused (i.e. reserved) protocol field is now used for identification, this function can therefore be introduced in a backwards-compatible manner, i.e. a transmitter device using this identification can communicate correctly with a receiving device, even if the latter ignores this identification because, for example, it does not understand it . However, it must be observed whether the users of the protocol modified in this way assume delivery in strict order of all messages (such as the protocols described in Q.2210 and Q.2140 for the so-called "retrieval" when using Q.2110). It must then be weighed whether the present invention should not be used or whether the functions of the user protocols which are based on delivery in strict order are modified or restricted. (In the case of Q.2210 and Q.2140, Q.2140 would have to be modified such that on an AAL-RETRIEVE_BSNT request by Q.2210, the modified Q.2140 returns an AAL-BSNT confir to Q.2210, in where the value of the BSNT parameter contained therein is equal to the highest value of the SN value obtained in AA-DATA-Indication. As a consequence, messages with a lower sequence number than said SN value are sent which have not yet been received or may not yet have been received from the SSCF were delivered to the user.)

In a second stage, functions are introduced which make it possible to control a large number of different message streams in such a way that messages from one stream are delivered in the correct order, but message losses on other streams do not delay the delivery of messages from one stream. Advantageously, these functions are not introduced as part of the SSCOP or other existing and extended protocols according to the first stage, but rather in a separate protocol layer, which can be referred to as a convergence or multiplexing layer, although it is also incorporated directly into the existing and already modified protocols is possible. Depending on the application, an existing convergence layer can be expanded (e.g. the SSCF for the NNI described in Q.2140) or a new convergence layer can be introduced. With regard to the data sent over the transmission link, there are two Markings necessary. One is an identification of the data stream, the other a numbering of the messages within a data stream. Possibly. control messages must still be defined to control (eg initialize) the individual data streams.

The identification of the message stream shows an advantage of arranging the function in a separate protocol layer. As a result, message stream identifications that are already contained in the data of the users can be used, which makes the introduction of a separate protocol field unnecessary and thus saves transmission capacity. This also means that there is no need to change the interface between the transmission protocol and its (existing) users. For example, this is possible with MTP Level 3 (Q.2210, Q.704), which - depending on the ITU-T or ANSI version - identifies between 16 and 256 explicit protocol streams via the so-called signaling route selection field (SLS). Furthermore, in this special case, additional information already available from the messages (e.g. origin and / or destination addresses or parts thereof) can be used in order to achieve a finer division of the messages into individual, independent streams. The layer Q.2140 lying between Q.2210 (broadband MTP level 3) and Q.2110 (SSCOP) could therefore be modified accordingly without this having any effect on Q.2210.

Alternatively, the message streams can also be explicitly identified using a new protocol field, which means that

The advantage is that this can be done independently of the application, so that the convergence or multiplexing layer no longer has to know about the fields of the user protocols. However, the interface to existing users must then be expanded, since then at least when transferring and possibly. even when receiving data the current to which the

Data belongs must be explicitly identified. Also have to Additional data is normally transmitted because existing protocols rarely have sufficiently large unused fields, although this is not excluded.

For the numbering of messages within a data stream, a new field will normally also have to be introduced in the messages, because existing protocols rarely have sufficiently large unused fields, although this is not excluded.

Control messages or feeders to control the

Message streams are particularly necessary when the number and existence of the streams are not fixed but have to be dynamically agreed between the two end points of the transmission link. However, if you start from a fixed definition

Streams of messages, then there is a special control of the

Message flows are not absolutely necessary. It may However, it can be advantageous since this can make the protocol more robust and any protocol errors that may have occurred in a message stream cannot influence other streams. If no special control is carried out, the currents are automatically switched on when the connection is established

Initialized protocol (e.g. SSCOP).

Possible control functions are e.g. into consideration

■ open and end a stream

■ Reset the sequence numbers of a stream

■ individual flow control

The convergence layer (or the additional function built into the protocol) has the following functions:

• Management of a receive buffer for each (active) stream. • Management of a send and a receive sequence number. • Receive the messages for a stream and check the sequence number.

• If the sequence number is delivered to the user - and possibly other messages waiting in the receive buffer for this message - to the user.

• If there are gaps in the sequence number, the message is buffered in the receive buffer.

• When sending the message, assignment of the transmission sequence number and, if applicable, the stream identification. • Possibly. Execution of the control functions.

Furthermore, it can be advantageous that for one (or more streams) of the streams (which is used, for example, for messages of SCCP class 0), delivery in the correct order is dispensed with.

It should be noted that the present invention is not limited to MSR methods. It can also be applied to ordinary selective rejects or go-back-n processes. In these cases, however, there are more adjustments, e.g. Introduction of a reception buffer or a status bar to track the messages that have already been delivered, required than with the MSR procedure.

To 4.

In one exemplary embodiment, SSCOP (Q.2110) is modified such that a free bit is used in SD-PDUs to identify messages which do not have to be delivered “in-sequence” (see FIG. 1). Q.2140 is also modified to introduce 17 streams, one for SCCP class 0 messages and 16 for the 16 possible SLS values of other messages (see Figures 4, 5 and 6). To avoid changing the user At the same time, the maximum permitted message length for the SSCOP (parameter k) increased to 4100 octets, since the modified SSCF (for the fields SQ #, St # and Status) requires an additional 4 octets per message (SD-PDU with MTP-3b data) space (see Figure 3).

To 5.

The accompanying drawing with Figures 1 to 6 supports the representation of the invention described above.

Claims

claims

1. A method for transmitting messages between a transmitting and receiving device of a transmission link, accordingly

- Messages are numbered when sending and

- Messages are requested again from the receiving device if it uses the numbering to identify gaps in the received message stream, characterized in that all or only special messages, i.e. Messages with special characteristics upon receipt to the recipient immediately, i.e. regardless of whether messages must be repeated due to a gap determined by the receiving device.

2. The method according to claim 1, characterized in that messages that are delivered immediately are delivered by the receiving device to a multiplexing device, the multiplexing device assigning received messages based on the special features mentioned different message streams and messages of a message stream independent of messages from another stream treated further.

3. The method according to claim 1 or 2, characterized in that a special feature can be a marker added by the transmitting device in the messages and / or a specific content of the messages.

4. The method according to any one of claims 2 to 3, characterized in that the said multiplex device is a device of the transmission link itself or a device of a protocol layer superordinate to the transmission link.

5. Receiving device of a transmission link, which receives numbered messages and requests messages again when they are numbered

Gaps in the received message stream determined, characterized in that they all or only special messages, i.e. Messages with special characteristics upon receipt to the recipient immediately, i.e. delivered regardless of whether messages need to be repeated due to a gap found.

6. Multiplexing device which receives messages from the receiving device according to claim 5, characterized in that it assigns received messages based on special features of the messages to different message streams and processes messages of a message stream independently of messages from another stream.

7. Multiplexing device according to claim 6, characterized in that the said multiplexing device is a device of the transmission link itself or a device of a protocol layer superordinate to the transmission link.

8. The method according to any one of claims 1 to 4, characterized in that it represents a modification of the protocol according to Q.2110 or a protocol derived therefrom.

9. The method according to claim 8, characterized in that the modification of the protocol according to Q.2110 or a protocol derived therefrom takes place in that in the SD

PDUs a free bit is used to identify messages that are to be delivered to the recipient immediately.