JPH057216A - Signal identifying method - Google Patents

Abstract

PURPOSE:To identify the storing of an ATM(Asynchronous Transfer Mode) signal in a digital hierarchy (SDH) transmitter. CONSTITUTION:For an ATM cell 4 mapped to a virtual container (VC)-4, the position in a pay load 15 is dislocated backwards by 5 bytes per one line and when the VC-4 constituted of 9 lines is a reference, the position is dislocated by 45 bytes. Then, the value of an H4 byte 3 of a pass overhead (POH) 2 is monitored, 45 is added to the value of the H4 byte of a certain VC-4, and when the result exceeds 52, the value for subtracting 53 from it, and when the result does not exceed 52, the value is compared with the value of the H4 byte of the next VC-4 as it is and at the time of the coincidence, that is, it is decided as the storing of the ATM signal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a signal identification method, for example, a digital hierarchy (SDH: Sy).
nchronous Digital Hierarc
hy) interface to ATM (Asyncron)
ous Transfer Mode: Asynchronous transfer mode
D) A method for identifying whether or not a signal is contained.

[0002]

2. Description of the Related Art CCITT (International Telegraph and Telephone Advisory Committee)
The draft recommendation (1990 edition) by G. 709, as shown in FIG. 5.20, the normal STM (Sync
In addition to accommodating and transmitting a hornous transfer mode (synchronous transfer mode) signal, a virtual container (Virtual Container) VC-
There is also defined a method of mapping ATM cells to No. 4 and transmitting ATM using the SDH transmission system. FIG. 4 shows this. 1 is a virtual container VC-4 that accommodates and transmits either an ATM signal or an STM signal, 2 is a path overhead (POH), 3 is an H4 byte, and 4 is an ATM.
A cell, 5 is an ATM cell header, and 15 is a payload.

Next, the operation will be described. VC-4 is 9
It consists of rows and 261 bytes, the first of which is the POH.
It is 2. On the other hand, the ATM cell has a length of 53 bytes and is a payload 15 excluding POH2 of VC-4.
It is mapped without any gaps in the area called. POH2
There is a 1-byte area called H4 in the 9 bytes of, and when accommodating an ATM signal, the offset between the beginning of the first ATM cell area of the row in which the H4 byte is located and the H4 byte is written in byte units. In the case of signal accommodation, this value is an integer from 0 to 52. Also ST
When accommodating the M signal, the H4 byte represents the low order VC multiframe.

STM based on such SDH
The ATM hybrid transmission system is configured, for example, as shown in FIG. In the figure, 6 is an SDH transmission device,
7 is an SDH multiplexer / separator, 8 is an STM processor, 9 is S
A TM processing unit, 10 is an ATM processing device, 11 is an ATM processing unit, 12 is an interface unit, 13 is a transmission line, and 14 is an erroneous connection part.

However, there are two types of interfaces as described above.
If the interface to be connected to the ATM processing device is erroneously connected to the STM interface as shown in the figure, the SDH transmission device does not monitor the contents of the payload. The erroneous connection cannot be recognized and is recognized as a failure in the ATM or STM processing device, and it is difficult to distinguish it from a failure in the processing device.

[0006]

Since the SDH interface is constructed as described above, when the SDH transmission device is conventionally applied to the STM / ATM hybrid transmission system, the SDH transmission device has a virtual container. Does not discriminate whether it accommodates an ATM signal or an STM signal. Therefore, the ATM device and S
If the TM device is connected incorrectly, A
Since the TM device cannot detect the cell synchronization loss until it is detected, there is a problem that operation and maintenance are difficult.

The present invention has been made in order to solve the above problems, and an object thereof is to provide a method for identifying whether an ATM signal is accommodated at the SDH interface level, in other words, a virtual container. It is an object of the present invention to provide a signal identification method capable of identifying a signal contained in a transmission unit when a predetermined transmission unit such as the above is received.

[0008]

A signal identifying method according to the present invention has the following steps. (A) a receiving step of continuously receiving a predetermined transmission unit which accommodates and transmits any one of two or more different signals, and (b)
A determination step of determining the type of a signal accommodated in the transmission unit based on the predetermined information recorded in each of the two continuous transmission units received in the reception step.

[0009]

In the signal identifying method according to the present invention, the determination step is the interface level and the predetermined information between the continuous transmission units received by the receiving step (for example, H4 of POH of VC-4).
Byte) is monitored to determine the signal accommodated in the transmission unit.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. The configuration of the transmission system is the same as that shown in FIG. 5, and FIG. 1 is a flow chart for explaining the operation of the SDH transmission device 6 provided with the signal identifying method according to the present invention. In the figure, 16 indicates that the SDH transmission device 6 is another SDH.
The first VC- that receives the first VC-4 from the transmission device 6
4 receiving step, 17 receiving the next VC-4, 18 receiving H4 of two consecutive VC-4s received
This is a step of determining the identification of the signal in the VC-4 by using the identification method described later using the bytes. After step 18,
Returning to step 17, the next VC-4 is received, and in step 18, the VC-4 internal signal is judged again. After that, this is repeated. Further, 19 is a receiving step and 20 is a determining step.
Next, FIG. 2 is an explanatory diagram showing the principle of an embodiment of the ATM signal accommodation identification method according to the present invention, and shows a state in which ATM cells are mapped to, for example, two consecutive VC-4s. In FIG. 2, the same parts as those in FIG.

Next, the operation will be described. As shown in FIG.
The boundary of the ATM cell mapped to VC-4 is VC
-4 bytes of row 15 of the payload 15 is not divisible by 53 bytes of ATM cell, and 5 bytes per row of payload
It shifts byte by byte, and in 9 lines (1 frame), it shifts by 45 bytes. Therefore, paying attention to this characteristic, the value of the H4 byte is obtained by adding 45 to the value of H4 in the previous VC-4, and if the result exceeds 52, subtract 53 from it, or less than 52. If so, it will be the value as it is. For example, as shown in the figure, if the value of H4 in a given VC-4 is 25, the value of H4 in the next VC-4 is obtained by adding 45 to 25, which is 53 less than 70.
Become 7.

On the other hand, the multi-frame display when the STM signal is accommodated changes so that the value of H4 increases by 1 for one frame, and is fixed when there is no multi-frame. Since there are many cases, one frame of H4 bytes
It is possible to easily identify the accommodated signal by observing the change for each frame.

FIG. 3 is a flow chart showing an embodiment of the judgment step 20 of the ATM signal accommodation identification method according to the present invention, which is considered from the above principle. nth VC-4
The value of the H4 byte of is set to x (n), and the number obtained by adding 45 to this is set to y (n). If y (n) is greater than 52, subtract 53 from y (n) to obtain z (n),
If y (n) is a number of 52 or less, z (n) is used as it is. The z (n) thus obtained is compared with the value of the H4 byte of the (n + 1) th VC-4, that is, x (n + 1), and if they match, it means that the ATM signal accommodation is detected. Become.

As described above, in this embodiment, CCIT
Recommendation G. Synchronous digital hierarchy (SDH: Synchronou) compliant with 707, 708, and 709.
sDigital Hierarchy interface and a virtual container (VirtualContainer)
on STM (SynchronousTr)
transfer mode: Synchronous transfer mode) signal or ATM (Asynchronous Transfer)
er Mode: Asynchronous transfer mode) In an SDH-based STM / ATM hybrid transmission system that accommodates and transmits any of the signals, Recommendation G. 709-compliant virtual container VC-4 pass-over head (POH)
Whether or not the value of the H4 byte indicates the position of the boundary of the ATM cell by monitoring the change of the H4 byte value for each frame, and the accommodation of the ATM signal is identified by the result. The ATM signal accommodating and identifying method characterized by the above has been described.

The ATM signal accommodating / identifying method according to this embodiment can be easily used in an SDH transmission apparatus.
Whether or not the signal is accommodated can be determined, and the accommodated signal type can be confirmed at the interface of the SDH transmission device. As described above, according to this embodiment, H of POH of VC-4 is
By monitoring 4 bytes, in the SDH transmission device, before performing the check processing in the ATM processing unit, the AT
It becomes possible to easily identify the accommodation of the M signal.

Example 2. In the first embodiment described above, there are two types of signals accommodated in the VC-4, the ATM signal and the STM signal, which can be distinguished by the H4 byte. However, the VC-4 is the transmission unit in the present invention. This is an example, a signal that also accommodates an ATM signal and an STM signal, and an example of information that determines a signal that also accommodates H4 bytes. The present invention attempts to determine a predetermined transmission unit by comparing information between transmission units when a signal in the transmission unit cannot be determined only by information in the transmission unit. Therefore, if the present invention is applied to a system in which data is continuously transferred, the same operational effect as that of the first embodiment can be obtained.

[0017]

As described above, according to the present invention, VC-
Since it is decided to compare predetermined information such as H4 bytes among the transmission units such as 4, it is possible to easily determine the type of the accommodated signal.

[Brief description of drawings]

FIG. 1 is a flowchart illustrating a signal identification method according to the present invention.

FIG. 2 is an explanatory diagram showing an embodiment of a signal identifying method according to the present invention.

FIG. 3 is a flow chart showing an embodiment of a determination step of the signal identification method according to the present invention.

FIG. 4 is an explanatory diagram for explaining mapping of ATM cells to VC-4 in the SDH interface.

FIG. 5 is a block diagram showing a configuration example of an SDH-based ATM / STM hybrid transmission system.

[Explanation of symbols]

1 VC-4 (example of virtual container, transmission unit) 2 POH (path overhead) 3 H4 byte (example of predetermined information recorded in transmission unit) 4 ATM cell 5 ATM cell header 6 SDH transmission device 7 SDH Multiplexing / separating unit 8 STM processing device 9 STM processing unit 10 ATM processing device 11 ATM processing unit 12 Interface unit 13 Transmission line 14 Misconnection part 15 Payload 19 Reception process 20 Judgment process

Claims (1)

Claims: 1. A signal identification method (a) comprising the following steps:
A receiving step of continuously receiving a predetermined transmission unit that is transmitted by accommodating any one of two or more different signals, and (b) each of two continuous transmission units received by the receiving step. A determining step of determining the type of the signal accommodated in the transmission unit based on the recorded predetermined information.