EP1180275A1

EP1180275A1 - Method for monitoring bit transmission quality in packet-oriented transmission

Info

Publication number: EP1180275A1
Application number: EP00926710A
Authority: EP
Inventors: Joachim Charzinski; Mathias Bischoff; Jürgen Graf
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 1999-06-02
Filing date: 2000-04-10
Publication date: 2002-02-20
Also published as: CA2375819A1; WO2000076108A1

Abstract

The bit transmission quality of a connectionless switching operation such as an IP-packet switching operation is monitored by providing each packet with a checksum. This checksum only helps to determine, at the receiving end, whether or not an error has occurred during the transmission process. It is not possible to determine the number of bit errors that have occurred using this procedure. According to the invention, these problems are solved by applying the BIP calculation method used in connection-oriented switching to connectionless switching.

Description

description

_V erfa _h ren for monitoring the Bitübertragungsgüte in packet-oriented transmission ^¬.

_T he invention relates to a method according to the preamble of claim. 1

In modern information processing systems, the information is transferred in SDH frames (Synchronous Digital Hierarchy). The SDH transmission is a connection-oriented exchange. For example, ATM cells or IP cells (Internet Protocol) can be inserted into the SDH frames. These must be inserted into the SDH frame on the sending side and removed again on the receiving side. In the prior art, the IP cells are integrated into ATM cells and these are transferred into the SDH frame. Here, the packaging and depacketing processes are to be carried out twice.

To monitor the bit transmission quality, cross-sum calculations are carried out periodically for all data transmitted between two reference points in SDH frames. For example, two switching nodes can function as reference points, between which a transmission section is arranged. Here, the bit error rate is quantified on the transmission section. The checksum calculations are carried out independently of one another both in the transmitting and in the receiving switching node. It is in a cyclic time grid over z. B. Every eighth bit a parity assessment. On the transmission side, the determined result is entered in a test field BIP (Bit Interleaved Parity) and is sent to the receiving switching node in the SDH frame. There are three different BIP fields in SDH frames, each of which is used in the path, multiplex section and regenerator section overhead and has different sizes. The sizes the path and mux section BIPs depend on the size of the SDH frame and range from 2 to n * 24 bits. The regenerator section GDP always has 8 bits. The receiving side, the test field übertra ^¬ gene GDP is evaluated and the same in accordance with a comparison of this analysis with its own Quers mmenbe- bill a quantification of the bit error rate on the transmission portion performed.

The advantage of this method is that the number of bit errors that occur is determined. This means, for example, that bit errors (e.g. bits 5, 7) that are close together can also be determined (tuft errors). On the other hand, the problem is that the equipment required for SDH frames is very expensive and complex.

In contrast to connection-oriented switching, connectionless switching does not create a permanent connection between the sending and the receiving device. IP packet switching can be used as an example for connectionless switching. Each packet is provided with a checksum to monitor the bit transmission quality. With the help of this checksum, bit errors can also be determined at the receiving end. However, the checksum only allows a recognition of whether an error has occurred during the transmission process or not. As a consequence, the IP packet in question is discarded at the receiving end. It is not possible to determine the number of errors that have occurred, as is the case, for example, with the GDP calculation method.

The invention has for its object to show a way how a more efficient monitoring of the physical transmission quality can be carried out even in connectionless switching. The invention is, starting from the preamble of claim 1. patent applica ^¬ solved by the features specified in the characterizing part shopping ^¬ male.

An advantage of the invention is in particular the transfer of the BIP calculation method known in connection-oriented switching to connectionless packet switches. This has the advantage that there is a more detailed error pattern in the system by determining the number of bit errors that have occurred. This bit error can also be recorded section by section, while the checksum method used in the prior art only permits an end-to-end statement.

Advantageous developments of the invention are provided in the subclaims.

The invention is explained in more detail below on the basis of an exemplary embodiment.

Show it:

Figure 1 2 switching nodes that complete a transmission section

Figure 2 is a flow chart of the method according to the invention.

1 shows a configuration on which the method according to the invention is carried out. Accordingly, two switching nodes R _A , R _{B are} shown, which terminate a transmission section UA. The switching nodes R _A , R _B are to be designed, for example, as IP routers. Furthermore, IP packets are to be routed via the transmission section UA via WDM (Wave Division Multiplexing). According to the present embodiment, it is assumed that the the sending switching node is the IP router R _A and the receiving switching ^{node is} the IP router R _B. As shown in FIG. 1 is ent ^¬ detachable, the sending IP router R _A transfers IP packets of different lengths on the transfer section to the receiving UA IP router R _B. The transmission section UA is designed bidirectional, for better understanding only the transfer from the sending IP router R _A to the receiving IP router R _B ever ^¬ but pointed out.

The invention will in the following with reference to the Darge in Fig. 2 ^¬ presented flowchart explained in more detail.

In the sending IP router R _A , the BIP calculations are carried out over a plurality of transmitted bits within a time interval. The higher-level packet structure is irrelevant here, ie the checksum calculation is carried out using the bits of several packets. The time interval is specified by two successive control packets PM. The determined result is now stored in a test field BIP together with a sequence number in a control packet PM, which is inserted quasi-periodically in the stream of outgoing IP packets. The quasi-periodic insertion is necessary because the IP packets are of variable length and their transmission cannot be interrupted. In this respect, periodic insertion of the control packages PM is not possible. According to the invention, it is now provided to reset a counting device when a control packet PM is inserted by the IP router R _A. If this has reached a predefinable threshold value, the control packet PM is inserted into the IP packet stream as the next packet immediately after the current IP packet has been sent. In the period of time that the counter device needs to reach the threshold value, the bits are counted and the GDP checksum calculation is carried out (time interval).

If the receiving IP router R _{B determines} the arrival of a control packet PM, its content has been with its own since _the GDP calculation performed last time a control packet was received. Further, the rows mitubertragene ^¬ is verfiziert sequence number that is to say, it must be high by 1, when the last control packet transmitted in the PM. If this is the case, the difference between the result of the self ermittel ^¬ th GDP calculation and GDP Pruffeld is formed. To measure the result ^¬ display the number n _B is then determined the set ^¬ bit errors. As can be averaged out in the Quersummenbe ^¬ bill bit errors, it is at the value n _B is a lower limit of the number of errors occurred.

With the value n _B determined in this way, an estimate p _{E is made for} the current bit error rate. It amounts to:

p _E = n _B / n _R with n _R = number of bits received

The size n _R can be paid exactly at the receiving end, for example by ASIC components. Alternatively, an estimate is entirely sufficient. Accordingly, it is then assumed that constant times have elapsed between 2 control packets PM. This is equivalent to the statement that the control packets PM are inserted periodically into the outgoing stream of IP packets. The same number of bits is thus transmitted at the same transmission speed.

According to the present exemplary embodiment, it was assumed that the devices R _A , R _{B are designed} as switching nodes between which the method according to the invention is used. However, the invention is not limited to such configurations. It can also be used on individual transmission sections of a point-to-point connection between two switching nodes, which are delimited by regenerators. The transmission sections formed by regenerators form the entire connection section between the transmitting and the receiving end establishment. In this case, each regenerator can carry out the GDP calculation or check and also write the result of their own calculation back into the control package PM that is sent on. This enables a bit error rate estimation in sections. The segmental bit error rate estimates stored in the individual regenerators can then be read out, for example, using X.25 protocols.

Claims

claims

1. A method for, monitoring the Bitübertragungsgüte in pa ^¬ ketorientierter transmission, comprising a transmitting device (R _A), from the information in variable length packets in accordance with a connectionless service of a receiving device (R _B) through a transmission section (UA) are fed, characterized in that in the transmitting device (R _A ) bit by bit within a predefinable time interval, according to an algorithm, a test information is formed which is stored in a control packet (PM) that is emitted by the transmitting device (R _A ) Stream of packets, the control packets (PM) are inserted quasi-periodically so that when a control packet (PM) arrives in the receiving device (R _B ), test information is also generated bit by bit over the packets received in the time interval, according to the same algorithm that according to a logical link between this test information rmation and the test information transmitted in the control packet (PM), an estimate is made of the bit errors that occurred during the transmission process.

2. The method according to claim 1, characterized in that the estimation is carried out by dividing the number of at least occurred bit errors (n _B ) by the number (n _R ) of the transmitted bits.

3. The method according to claim 1, 2, characterized in that the number of bits transmitted (n _R ) is measured at the receiving end.

4. The method according to claim 1, 2, characterized in that the number of bits (n _R ) transmitted on the receiving side is estimated ^¬ by starting from a periodic insertion of the control packets (PM).

5. The method according to claim 1 to 4, characterized in that the time interval is defined by the transmission of two successive control packets (PM).

6. The method according to claim 1 to 5, characterized in that the validity of the control packet (PM) is decided at the receiving end by evaluating the sequence number.

7. The method according to any one of the preceding claims, characterized in that the packets transmit information according to an Internet protocol (IP packets).

8. The method according to any one of the preceding claims, characterized in that the logical combination is a difference.

9. The method according to any one of the preceding claims, characterized in that the test information is carried out in accordance with a GDP calculation (bit interleaved parity).

10. The method according to any one of the preceding claims, characterized in that the transmitting (R _A ) - and receiving device (R _B ) are designed as switching nodes.

11. The method according to any one of claims 1 to 9, characterized in that the transmitting (R _A ) and receiving device (R _B ) are designed as regenerators.