JPH09247183A - Stm-atm converting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To automatically and mutually connection-converting a synchronous transfer mode(STM) signal on an STM network side and an asynchronous transfer mode(ATM) signal on an ATM network side without executing manual setting from the outside. SOLUTION: The overhead decoder 18 of an STM-ATM converting device 1 detects 'usage/unesage' by 'unusage' information from overhead in VC passes which are separated from the STM signal in a separating circuit 10 and outputs a prohibiting signal to prohibiting circuits 11-1 to 11-n and 15-1 to 15-n at the time of detecting 'unusage'. The prohibiting circuits 11-1 to 11-n prohibit the output of the VC passes to ATM cell converting circuits 12-1 to 12-n in accordance with the prohibiting signal from the overhead decoder 18. The prohibiting circuits 15-1 to 15-n prohibit the output of an ATM cell to STM signal converting circuits 16-1 to 16-n in accordance with the prohibiting signal from the overhead decoder 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an STM-ATM converter, and more particularly, to an STM-ATM converter which is routed on an arbitrary path layer basis and time slot multiplexed on a path basis.
TM (Synchronous Transfer M)
mode: A synchronous transfer mode (ATM) signal and an ATM (Asynchronous) which is multiplexed by being cellized for each routing unit.
The present invention relates to an STM-ATM conversion system for interconnecting and converting a signal from a non-transfer mode (asynchronous transfer mode).

[0002]

2. Description of the Related Art Conventionally, in this type of STM-ATM conversion system, as shown in FIG.
S time-multiplexed by the M cross-connect device 2
The STM-ATM converter 3 converts the TM signal into an ATM signal and sends it to the ATM network side. The ATM signal from the ATM network side is converted into an STM signal by the STM-ATM converter 3 and the STM cross on the STM network side. It is being sent to the connecting device 2.

On the STM network side, SDH (Sync) is used by a generally used STM cross-connect device 2.
Hronous Digital Hierarch
y: Synchronous digital hierarchy (VC) (V
An STM signal that is time slot multiplexed for each actual channel is accommodated in a plurality of input / output ports, and one arbitrary port faces the STM-ATM converter 3.

[0004] In the STM cross-connect device 2, a cross-connect is performed by a cross-connect switch 21 for each VC path. At the same time, the pattern insertion circuit 22 inserts "unused" information into the VC path corresponding to a time slot with no connection during the overhead.
Here, the “unused” information is information indicating whether each VC path is used or unused.

On the STM network side, the STM-ATM conversion device 3 is an STM based on the above STM network.
Opposite the signal. The VC path is assumed to be bidirectionally communicated.

When the STM-ATM converter 3 converts an STM signal into an ATM signal, the STM signal input from the STM network side is separated for each VC path by a separation circuit 30 and each of the VC paths is prohibited. 1-31-n
To enter.

Each of the prohibition circuits 31-1 to 31-n holds "unused" information manually (manually) input from an externally provided setting control unit 4 until its contents are changed.

When the "unused" information indicates "unused" of the VC path, each of the inhibition circuits 31-1 to 31-n inhibits the output of the VC path. Also, the prohibition circuit 31-1
-Unused information is "used" for the VC path.
, The VC path is output to the ATM cell conversion circuits 32-1 to 32-n.

The ATM cell conversion circuits 32-1 to 32-n convert the input VC paths into unique VPIs (Virtual Path Ide) corresponding to the respective VC paths.
ntifier (virtual path identifier) to give a cell, and output the ATM cell to the cell multiplexing circuit 33. The cell multiplexing circuit 33 is an ATM cell conversion circuit 32-1.
Multiplexes the cells input from .about.32-n and outputs them to the ATM network side.

On the other hand, the STM-ATM converter 3
When converting the M signal into the STM signal, the ATM signal input from the ATM network side is converted into the address filters 34-1 to 34.
In accordance with the VPI given to the cell by -n, the data is input to the corresponding VC path prohibition circuits 35-1 to 35-n.

Each of the prohibition circuits 35-1 to 35-n holds the "unused" information from the setting control section 4 until its contents are changed. Each of the prohibition circuits 35-1 to 35-n prohibits the output of the VC path when the "unused" information indicates "unused" of the VC path.
If the "use" of the C path is indicated, the VC path is set to S
It outputs to TM signal conversion circuits 36-1 to 36-n.

The STM signal conversion circuits 36-1 to 36-n convert the input ATM cells into an STM-converted VC path, and output the VC path to the time slot multiplexing circuit 37. The time slot multiplexing circuit 37 time slot multiplexes the VC paths input from the STM signal conversion circuits 36-1 to 36-n and outputs the VC paths to the STM network side.

Thus, the STM-ATM converter 3
By setting the use and non-use of the VC path from the setting control unit 4, the STM signal on the STM network side and the ATM signal on the ATM network side are mutually connected and converted.

[0014]

The above-mentioned conventional STM
-In the ATM conversion system, when connecting and converting the STM signal on the STM network side and the ATM signal on the ATM network side to each other,
It is necessary to externally set the presence or absence of conversion (use / unused by unused information) for each VC path.

Therefore, an object of the present invention is to solve the above problems and autonomously connect and convert the STM signal on the STM network side and the ATM signal on the ATM network side to each other without manual setting from the outside. It is to provide an STM-ATM conversion device capable of

[0016]

SUMMARY OF THE INVENTION STM-A according to the present invention
The TM converter interconnects the synchronous transfer mode signal time-slot multiplexed in virtual channel path units according to the synchronous digital hierarchy and the asynchronous transfer mode signal multiplexed into cells for each virtual channel path unit. An STM-ATM converter for converting, comprising: detecting means for detecting, from the synchronous transfer mode signal, unused information inserted into an overhead of the virtual channel path and indicating that the virtual channel path is unused; Celling prohibition means for prohibiting cellization of the virtual channel path in accordance with the detection result of the detection means, and conversion of cells in the asynchronous transfer mode signal to the synchronous transfer mode signal in response to the detection result of the detection means And a conversion prohibition unit for prohibiting the conversion.

Another STM-ATM conversion apparatus according to the present invention, in the above-mentioned configuration, wherein the detecting means decodes the overhead of the virtual channel path and decodes the unused information, and Each of the conversion prohibiting means has an overhead decoder for outputting a prohibition signal.

Another STM-ATM conversion apparatus according to the present invention comprises a synchronous transfer mode signal which is time-slot multiplexed for each virtual channel path for bidirectional communication according to a synchronous digital hierarchy, and a cell for each virtual channel path unit. STM-A which performs connection conversion by associating the multiplexed asynchronous transfer mode signals with each other.
A TM conversion device, wherein detection means for detecting, from the synchronous transfer mode signal, unused information inserted into the overhead of the virtual channel path and indicating that the virtual channel path is unused; and Celling prohibiting means for prohibiting celling of the virtual channel path where unused information is detected, and cells in the asynchronous transfer mode signal corresponding to the virtual channel path where the unused information is detected by the detecting means Conversion inhibiting means for inhibiting the conversion to the synchronous transfer mode signal.

Still another STM-ATM conversion apparatus according to the present invention, in the above configuration, wherein the detecting means decodes the overhead of the virtual channel path and decodes the unused information. Each of the conversion prohibiting means has an overhead decoder for outputting a prohibition signal.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First, the operation of the present invention will be described below.

The overhead of the VC path is decoded by an overhead decoder, and the cell prohibition of the VC path is prohibited by a prohibition circuit in accordance with the decoding result, and the conversion of the cells in the ATM signal into the STM signal is prohibited by the prohibition circuit.

As a result, only the used VC path can be converted into an ATM cell autonomously without manual setting from the outside, and the cell of the unused VC path which is generated when the manual setting is not performed from the outside. It is possible to suppress an increase in unnecessary traffic in the ATM network due to the development.

Also, since the ATM cells are autonomously converted, the ATM cell conversion / A
The change of the TM cell prohibition can be performed immediately and dynamically.

Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing the configuration of one embodiment of the present invention. In the figure, an STM-ATM converter 1 according to an embodiment of the present invention includes a separating circuit 10, prohibiting circuits 11-1 to 11-n, and an ATM cell converting circuit 12-1.
12-n, the cell multiplexing circuit 13, the address filters 14-1 to 14-n, and the inhibition circuits 15-1 to 15-n.
, An STM signal conversion circuit 16-1 to 16-n, a time slot multiplexing circuit 17, and an overhead decoder 18
And is connected to the STM cross-connect device 2 on the STM network side and an ATM network (not shown). Here, the STM cross-connect device 2 includes a cross-connect switch 21 and a pattern insertion circuit 22.

On the STM network side, an STM signal time-division multiplexed in units of VC paths complying with SDH by a generally used STM cross-connect device 2 is accommodated in a plurality of input / output ports. Is ST
It faces the M-ATM converter 1. For SDH, see CCITT Recommendation G. 707 to 709.

In the STM cross-connect device 2, the cross-connect switch 21 performs cross-connection on a VC path basis. At the same time, the pattern insertion circuit 22 inserts "unused" information into the VC path corresponding to a time slot with no connection during the overhead.
Here, the unused information is information indicating whether each VC path is used or unused, and the area of the signal label C2 in the overhead of the VC path is used.

On the STM network side, the STM-ATM conversion apparatus 1 performs STM processing on the premise of the STM network as described above.
Opposite the signal. The VC path is assumed to be bidirectionally communicated.

When the STM-ATM converter 1 converts an STM signal into an ATM signal, the STM signal input from the STM network is separated by a separating circuit 10 for each VC path, and each of the VC paths is inhibited by an inhibiting circuit 11-. 1-11-n
And to the overhead decoder 18.

The overhead decoder 18 detects "used / unused" based on "unused" information from the overhead of each input VC path, and when the "unused" is detected, outputs the inhibit signal to the inhibit circuits 11-1 to 11-1. 11-n, 15-1 to 1
5-n.

Each of the prohibition circuits 11-1 to 11-n holds "unused" information (prohibition signal) input from the overhead decoder 18 until its contents are changed. When the “unused” information indicates “unused” of the VC path, each of the inhibition circuits 11-1 to 11-n inhibits the output of the VC path.

When the "unused" information indicates "use" of the VC path, each of the prohibition circuits 11-1 to 11-n converts the VC path to an ATM cell conversion circuit 12-1 to 12-12.
Output to -n.

At the ATM cell conversion circuits 12-1 to 12-n, the input VC paths are given a unique VPI corresponding to the VC paths, and are converted into cells, and the ATM cells are output to the cell multiplexing circuit 13. I do. Cell multiplexing circuit 13
Multiplexes the cells input from the ATM cell conversion circuits 12-1 to 12-n and outputs the multiplexed cells to the ATM network side.

On the other hand, the STM-ATM converter 1
When converting the M signal into an STM signal, the ATM signal input from the ATM network side is converted to address filters 14-1 to 14-14.
In accordance with the VPI given to the cell by -n, the signal is input to the corresponding VC path prohibition circuits 15-1 to 15-n.

Each of the prohibition circuits 15-1 to 15-n holds the "unused" information from the overhead decoder 18 until its contents are changed. Prohibition circuits 15-1 to 15-
n, when the “unused” information indicates “unused” of the VC path, the output corresponding to the VC path is prohibited, and the “unused” information indicates “used” of the VC path. In this case, the VC path is connected to the STM signal conversion circuits 16-1 to 16-16.
Output to -n.

The STM signal conversion circuits 16-1 to 16-n convert the input ATM cells into a STM-converted VC path, and output the VC path to the time slot multiplexing circuit 17. The time slot multiplexing circuit 17 multiplexes the VC paths input from the STM signal conversion circuits 16-1 to 16-n by time slot multiplexing and outputs the result to the STM network side.

Thus, the STM-ATM converter 1
, The STM signal on the STM network side and the ATM signal on the ATM network side are connected and converted autonomously.

In this way, the overhead decoder 18 decodes the overhead of the VC path, and the prohibition circuits 11-1 to 11-n prohibit the cellization of the VC path according to the decoding result, and the prohibition circuits 15-1 to 15-1. By prohibiting the conversion of the cells in the ATM signal into the STM signal in 15-n, only the VC path being used can be autonomously converted into an ATM cell without manual setting from the outside.

Further, it is possible to suppress an increase in unnecessary traffic in the ATM network due to a cell of an unused VC path which is generated when manual setting is not performed from the outside.

Further, since the ATM cell conversion is performed autonomously, the ATM cell conversion / path change accompanying the path change on the STM network side is performed.
It is possible to change the ATM cell prohibition immediately and dynamically.

[0040]

As described above, according to the present invention, the synchronous transfer mode signal which is time slot multiplexed for each virtual channel path in accordance with the synchronous digital hierarchy and the cell is multiplexed for each virtual channel path unit. In the STM-ATM conversion device for interconnecting and converting the asynchronous transfer mode signal with each other, unused information inserted into the overhead of the virtual channel path and indicating that the virtual channel path is unused is detected from the synchronous transfer mode signal. According to the detection result, the virtualization of the virtual channel path and the conversion of the cells in the asynchronous transfer mode signal into the synchronous transfer mode signal are prohibited, so that the STM network side can autonomously operate without manual setting from outside. The connection between the STM signal and the ATM signal on the ATM network side is changed. There is an effect that can be.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 STM-ATM converter 2 STM cross-connect apparatus 10 Separation circuit 11-1 to 11-n, 15-1 to 15-n Prohibition circuit 12-1 to 12-n ATM cell conversion circuit 13 Cell multiplexing circuit 14-1 To 14-n address filter 16-1 to 16-n STM signal conversion circuit 17 time slot multiplexing circuit 18 overhead decoder

Claims (4)

[Claims] 1. A synchronous transfer mode signal which is time slot multiplexed for each virtual channel path in accordance with a synchronous digital hierarchy and an asynchronous transfer mode signal which is cell-multiplexed and multiplexed for each virtual channel path. An STM-ATM converter for converting, comprising: detecting means for detecting, from the synchronous transfer mode signal, unused information inserted into an overhead of the virtual channel path and indicating that the virtual channel path is unused; Celling prohibition means for prohibiting cellification of the virtual channel path in accordance with the detection result of the detection means, and conversion of cells in the asynchronous transfer mode signal to the synchronous transfer mode signal in accordance with the detection result of the detection means STM-ATM having conversion inhibiting means for inhibiting Conversion device. 2. The detecting means includes an overhead decoder which decodes the overhead of the virtual channel path and outputs a prohibition signal to each of the cell assembly prohibiting means and the conversion prohibiting means when the unused information is decoded. The STM-ATM according to claim 1,
Conversion device. 3. A synchronous transfer mode signal which is time-slot multiplexed for each virtual channel path for bidirectional communication in accordance with a synchronous digital hierarchy, and an asynchronous transfer mode signal which is cell-multiplexed and multiplexed for each virtual channel path unit. And an STM-ATM conversion apparatus for performing connection conversion in association with each other, wherein the synchronous transfer mode signal includes unused information inserted into an overhead of the virtual channel path and indicating that the virtual channel path is unused. Detecting means for detecting the unused information from the virtual channel path detected by the detecting means, and a cell prohibiting means for prohibiting celling of the virtual channel path in which the unused information is detected, and the virtual channel detecting the unused information by the detecting means The synchronous transfer of cells in the asynchronous transfer mode signal corresponding to a path An STM-ATM conversion device comprising: a conversion prohibition unit for prohibiting conversion to a mode signal. 4. The detection means includes an overhead decoder which decodes overhead of the virtual channel path and outputs a prohibition signal to each of the cell prohibition means and the conversion prohibition means when the unused information is decoded. The STM-ATM according to claim 3, wherein
Conversion device.