JPS63155993A - Subscriber line signal line concentration system - Google Patents

Abstract

PURPOSE:To decrease the cost of a transmission line by adding a header corresponding to a subscriber allocating position to a subscriber line signal and sending the result so as to apply line concentration to subscriber line signal links and to connect them to an exchange. CONSTITUTION:A packet line concentration multiplexer 5 and a multiplexed signal link 6 are provided and the packet line concentration multiplexer 5 applies line concentration to the subscriber line signal link 4. The multiplexed signal link 6 connects the packet line concentration multiplexer 5 and an exchange 2. Since a header representing the allocated position of a subscriber is added to the subscriber line signal corresponding to each subscriber and the resulting signal is received/given via the multiplexed link 6 between the packet line concentration multiplexer 5 and the exchange 2, the signal link between the packet line concentration multiplexer 5 and the exchange 2 is subject to line concentration. Thus, remarkable reduction in the subscriber line signal links is attained and the transmission cost is reduced.

Description

[Detailed Description of the Invention] [Summary] By adding a header corresponding to the subscriber accommodation position to the subscriber line signal and transmitting it, the subscriber line signal link can be concentrated and connected to an exchange, Reduce transmission line costs.

[Industrial application field]

The present invention relates to a method for accommodating subscriber line signals in a communication network, and more particularly to a subscriber line concentration system that reduces transmission line costs by performing packet A-line multiplexing of subscriber line signals.

A subscriber line signal is a signal that mainly exchanges call control information between a terminal and a subscriber line signaling device of an exchange. l5
When introducing new systems such as DN services and broadband services, it is necessary to establish an efficient method for accommodating subscriber line signals in order to make the system more economical and realize these services at an early stage. be done.

[Conventional technology]

FIG. 5 is a diagram showing the concept of a conventional method of accommodating subscriber line signals. In the figure, 1-1 to 1-n each represent a subscriber, and 2 is an exchange. Reference numeral 3 denotes a subscriber line signaling device provided in the exchange 2, which connects the subscribers 1-1 to 1-n by subscriber line links 4-1 to 4-n, respectively.

In this way, conventionally each subscriber and the exchange were connected in a 1:1 relationship via a subscriber line link, and the exchange identified the subscriber based on the location where the subscriber line link was accommodated.

[Problem that the invention seeks to solve]

Thus, in conventional subscriber line accommodation systems, subscriber line links are connected to subscriber line signaling equipment in a 1:1 relationship with each subscriber.

However, in cases such as broadband service networks where the number of terminals to be accommodated is expected to be small at the beginning of the system's introduction, subscribers may be accommodated at small remote stations in rural areas, such as Sapporo or Sendai; In this case, in the conventional method described above, subscriber line signal links as many as the number of subscribers are installed in Sapporo and Sendai. The problem was that the cost of the transmission line was extremely high because it had to be installed from small-scale remote stations such as , etc. to the central station in Tokyo.

[Means for solving problems]

The present invention is an attempt to solve the problems of the prior art, and has the basic configuration shown in FIG. 2, the packet concentrator multiplexer 5
and a multiplexed signal link 6.

Packet line multiplexing device 5 concentrates subscriber line signal links 4 .

A multiplexed signal link 6 connects the packet concentrator multiplexer 5 and the exchange 2 .

[For production]

A packet is sent between the i-line multiplexing device 5 and the exchange 2 via a signal link 6 which is multiplexed by adding a header indicating the subscriber line signal corresponding to each subscriber to the subscriber line signal corresponding to that subscriber. Since the transmission and reception are arranged, the signal link between the packet concentrator multiplexer 5 and the exchange 2 can be concentrated.

〔Example〕

FIG. 2 shows the overall configuration of an embodiment of the present invention. In this figure, the same parts as in FIG. 5 are designated by the same numbers. 5 is a packet concentrator and multiplexer, and 6 is a signal link.

The subscribers 1-1 to 1-n are connected to the packet concentrator multiplexer 5 via signal links 4-, to 4-n, and the packet concentrator multiplexer 5 is connected to the switch 2 via the signal link 6. The subscriber line signaling device 3 is connected to the subscriber line signaling device 3. Subscriber 1-1
~1-n, when there is no subscriber line signal data (hereinafter simply referred to as data) to be sent, the subscriber line signal device 3 and the packet concentrator multiplexer 5 use a certain flag pattern (hereinafter abbreviated as F pattern). , respectively signal link 4+
~4-n, 6.

For example, when subscriber 1-1 transfers data to exchange 2, subscriber 1-8 stops sending the F pattern and sends the data to signal link 4-. The packet concentrator multiplexer 5 monitors the signal links 4-1 to 4-n, and when it receives a signal that is not an F pattern, it determines that it is valid data. When the packet concentrator multiplexer 5 receives this data from the signal link 4-1, it stops sending the F pattern to the signal link 6 and places a header (for example, 01) corresponding to the subscriber accommodation position in front of the data. The added header data is sent to the signal link 6.

The subscriber line signaling device 3 monitors the signaling link 6 and
When a signal that is not a pattern is received, it is determined that it is data with a header, and the header portion is separated to restore the original data. At the same time, it is identified from the separated header part that the subscriber's location is 1-1, and the data is processed.

Next, when transferring data from subscriber line signaling device 3 to subscriber 1-■, for example, subscriber line signaling device 3 stops sending the F pattern to signal link 6 and adds data to be transferred. Header-attached data to which a header (for example, 01) corresponding to the passenger accommodation position is added is sent to the signal link 6.

The packet concentrator multiplexer 5 monitors the signal link 6, and when it receives a signal that is not an F pattern, it determines it as valid data and divides the header from the received header-attached data to generate the original data. Restore. At the same time, the subscriber location 1-1 is identified from the separated header, and the restored data is sent to the signal link 4-1 corresponding to the subscriber 1-1.

Figure 3 shows an example of the subscriber line signal format, (a
) is the subscriber line signal format on the signal link 4-1 in the above explanation, and (b) is the subscriber line signal format on the signal link 6 in the above explanation. In the figure, the L2 frame indicates a subscriber line signal,
A is an address field, l is an information field for call origination, incoming call, etc. when applicable to the 15DN interface, C is a control field, and Fe2 is an information field for error control. In FIG. 3 (bl), DLl and DLC indicate a header, DLr is an information field indicating the subscriber location, and DLC is an information field for error control.

FIG. 4 shows an example of the configuration of a packet concentrator and multiplexer, illustrating a case where the concentrator ratio is 821. In the same figure, fat
indicates the configuration of the upstream side, 11 is the upstream side reception control section, 12
1 is an upstream buffer memory, 13 is an upstream transmission control unit, 1
4 is an upstream Q memory, 19 is a signal link on the subscriber side (upstream), and 20 is a signal link on the subscriber line signaling device side (upstream).
It is. Further, (b) shows the configuration of the downstream side, where 15 is a downstream reception control section, 16 is a downstream buffer memory, 17 is a downstream transmission control section, 18 is a downstream Q memory, and 19 is a signal link on the subscriber side. (down), 20 is a signal link (down) on the subscriber line signaling device side. The format of subscriber line signals in signal links 19 and 20 is shown in Figure 3, respectively.
), (suppose that it is in the form of bl.

The reception control unit 11 monitors the signal link 19, and when it receives a signal that is not an F pattern, it stores the received data in the area corresponding to the subscriber's accommodation position in the upstream buffer memory 12 until the next F pattern is detected. Write. At the same time, the accommodating location of the subscriber that has just been received (hereinafter referred to as subscriber number) and the number of bytes of data written to the upstream buffer memory 12 are written to the upstream Q memory 14. The upstream transmission control unit 13 monitors the upstream Q memory 14 and sends the F pattern to the signal link 20 when there is no data.

If there is data, stop sending the F pattern, read the subscriber number and number of bytes from the upstream Q memory 14,
First, a header corresponding to the subscriber number is created and sent to the signal link 20. Next, the area of the upstream buffer memory 12 corresponding to the subscriber number is read out by the number of bytes read from the upstream Q memory 14, and sequentially sent to the signal link 20. When all data have been sent, the upstream Q memory 14 is monitored again, and if there is data, the above procedure is repeated to send the data to the signal link 20, and if there is no data, the F pattern is sent to the signal link 20 again. do. on the other hand,
The downlink reception control unit 15 monitors the signal link 20, and when it receives a signal that is not an F pattern, it separates the header at the beginning and analyzes the subscriber number. The data sent following the header is stored in the downstream buffer memory 16.
is written in the area corresponding to the subscriber number obtained through the analysis. At the same time, this subscriber number and the number of bytes of data written to the downstream buffer memory 16 are written to the downstream Q mesori I8. This operation continues until the next F pattern is detected.

The downlink transmission control unit 17 monitors the downlink Q memory 18 and sends the F pattern to the signal link 19 when there is no data.
Send to. When there is data, the sending of the F pattern is stopped, the area corresponding to the subscriber number in the downstream buffer memory 16 is read out, and the area is sent to the signal link 19 corresponding to the subscriber number. And downstream Q memory 1
When the number of bytes read from the downstream Huffer memory 16 has been read and sent to the signal link 19, the F pattern is sent to the signal link 19 again.

〔Effect of the invention〕

As explained above, according to the present invention, subscriber line signal links can be concentrated by adding a header corresponding to the subscriber accommodation position to the subscriber line signal and multiplexing the subscriber line signal. It becomes possible to significantly reduce the number of line signal links, reducing transmission line costs.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the basic configuration of the present invention, FIG. 2 is a diagram showing the overall configuration of an embodiment of the present invention, FIG. 3 is a diagram showing an example of subscriber line signal format, and FIG. 4 is a diagram showing an example of the subscriber line signal format. FIG. 5 is a diagram showing an example of the configuration of a packet concentrating multiplexing device. FIG. 5 is a diagram showing the concept of a conventional method for accommodating subscriber line signals. 1-1 to 1-n-・Subscriber 2-Exchange 3・-Subscriber line signaling device 4-. ~4-n...-Subscriber line link 5-Packet concentrator multiplexer 6-Signal link 11-Upstream reception control section 12.--Upstream buffer memory 13-Upstream transmission control section 14...-Upstream Q Memory 15 - Downlink reception control unit 16 - Downlink buffer memory 17 - Downlink transmission control unit 18 - Downlink Q memory 19 - Subscriber side signal link 20 - Subscriber Signal link on line signal device side J of the present invention
Figures 1-1 to 1-n showing the physical structure 4-1 to 4-n 4-1 to 4-n A: Link Showing the overall structure of an embodiment of the present invention Figure 2 shows an example of the configuration of the

Claims (1)

[Claims] In a method of connecting subscriber line signals of a plurality of subscribers (1) to an exchange (2) via a signal link (4), a packet concentrator for concentrating the subscriber line signal links (4). A multiplexing device (5) and a multiplexed signal link (6) connecting the packet concentrating multiplexing device (5) and the exchange (2) are provided, and a multiplexed signal link (6) is provided to connect the subscriber line signal corresponding to each subscriber. It is characterized in that a header indicating the accommodation location of the subscriber is added and the packet is sent and received between the packet concentrator multiplexer (5) and the exchange (2) via the multiplexed signal link (6). Subscriber line signal concentration method.