KR20020016684A - Apparatus and method for d-channel packet service of integrated services digital network - Google Patents

Abstract

PURPOSE: An apparatus and a method for a D-channel packet service of an integrated services digital network are provided to remove a switch processing work to packet data in software by processing packet data through a DP-BUS and processing subscriber data through a sub highway, thereby dispersing load during data processing, and increase subscriber capacity by using one more subscriber channel. CONSTITUTION: A subscriber requests a D-channel packet service(S10). A D-channel matching part separates D-channel packet data received from the subscriber(S11). The D-channel matching transmits D-channel packet data through a DP-BUS(S12) to a packet network matching part. The packet network matching part receives D-channel packet data from the D-channel matching part through the DP-BUS and transmits D-channel packet data to a packet network(S13-S14).

Description

Apparatus and method for de-channel packet service of general information and communication network {APPARATUS AND METHOD FOR D-CHANNEL PACKET SERVICE OF INTEGRATED SERVICES DIGITAL NETWORK}

The present invention relates to a D-channel packet service method of an integrated telecommunication network, and more particularly, to increase subscriber capacity in a de-channel packet service using an integrated information telecommunication network (ISDN). The present invention relates to a de-channel packet service apparatus and a method of the same.

The channel structure of the basic access in the channel structure of the ISDN subscriber interface is 2B + D, where the B channel is the basic user channel (information: voice data 64 Kbps PCM), and the de-channel is used to exchange control information between the user and the network. Or 16Kbps for low-speed digital data.

In this case, the de-channel may be used for transmitting packet data after exchanging control information. In the conventional case, the path is used for connecting a subscriber device (not shown) to a network as shown in FIG. A D-channel matching unit (IDPA-N) 1; A switch (2) for switching data transmitted / received through the D channel matching unit (1) according to a channel state; It consists of a packet network matching section 3 for connecting data input / output through the switch 2 to the packet network.

At this time, the D-channel matching unit 1 serves to control a plurality of subscriber boards (IBQA-N: ISDN Basic rate 2B1Q interface board Assembly), and the subscriber board (IBQA-N) is a board that accepts subscribers. to be.

In general, the D-channel matching unit 1 can accommodate 16 subscriber boards (IBQA-N), and can accommodate 8 subscribers with one subscriber board.

In addition, the D-channel matching unit 1, the switch 2, and the switch 2 and the packet network matching unit 3 may transmit packets through a 32-channel data bus called a subhighway (SHW). Process data and subscriber data.

Therefore, as a whole, it occupies 2B channels per subscriber and thus can accommodate (8SHW × 32 channels) / 2B = 128 subscribers.

However, in the related art, channels 30 and 31 of the last subhighway SHW7 of the eight subhighways SHW0 to SHW7 are allocated as fixed paths of the de-channel data for the de-channel packet data service.

2 is a block diagram showing the detailed configuration of the D-channel matching unit 1 and the packet network matching unit 3 in the de-channel packet service using the conventional subhighway (SHW).

As shown therein, the D-channel matching section 1 includes a bus matching circuit 1a for receiving D-channel packet data from a subscriber; A CPI (1b) for separating and controlling the de-channel packet data received through the bus matching circuit (1a); A link controller (1c) for transmitting the separated de-channel packet data to a specific channel of a subhighway; And an SHW matching circuit 1d for transmitting the linked de-channel packet data through the subhighway.

Next, the packet network matching section 3 includes an SHW matching circuit 3b for receiving the de-channel packet data through the subhighway; And a CPI 3a which extracts packet data from the data received through the SHW matching circuit 3b and transmits the packet data to the packet network.

Therefore, since the de-channel packet data needs to be transmitted through the subhighway together with the subscriber data, the software load is increased during link protocol processing.

Next, FIG. 3 is a flowchart illustrating a de-channel packet service process through a conventional subhighway. As shown in FIG. 3, when a subscriber requests de-channel packet service (S1), the D-channel matching unit 1 De-channel packet data received from the subscriber is separated (S2) and transmitted to a specific channel (channel 30, channel 31) of the subhighway through a link controller (not shown) (S3).

Accordingly, the switch 2 switches so that the transmitted packet data can be delivered to the packet network matching unit 3 (S4).

Next, the packet network matching unit 3 extracts packet data from the data received through the subhighway (S5) and transmits the packet data to the packet network (S6).

However, as a result of performing the de-channel packet service using the subhighway to process the subscriber data as described above, various problems have occurred.

In other words, the actual number of subscribers that can be accommodated is that by allocating the last two channels for 128 subscriber or de-channel packet data processing, the two channels for the last subscriber cannot be used to process subscriber data, so that only 127 subscribers are available. .

In addition, there is a software load for processing the de-channel packet data connected to the switch 2, and there is a problem in that the load is increased during the link protocol (LAPB) process.

Accordingly, the present invention was created to solve the above-mentioned conventional problems, and process packet data using a dedicated data bus (DP-BUS) for the de-channel packet service, subscriber data through the sub-highway By processing only, the switch processing work for the packet data is not necessary by software, so that the load can be distributed during data processing, and one more subscriber channel can be used to increase the capacity of the subscriber. An object of the present invention is to provide a de-channel packet service apparatus and method for a communication network.

1 is a schematic structural diagram of an exchange inside a conventional de-channel packet service.

2 is a block diagram showing a detailed configuration of a de-channel matching unit and a packet network matching unit in a de-channel packet service using a conventional subhighway (SHW).

3 is a flowchart illustrating a de-channel packet service process through a conventional subhighway.

4 is a schematic structural diagram of an exchange inside a de-channel packet service according to the present invention;

FIG. 5 is a block diagram showing a detailed configuration of a de-channel matching unit and a packet network matching unit in a de-channel packet service using a de-channel packet dedicated bus (DP-BUS) according to the present invention; FIG.

6 is a flowchart illustrating a de-channel packet service process through a de-channel packet data dedicated bus according to the present invention.

*** Description of the symbols for the main parts of the drawings ***

10: D channel matching unit 20: switch

30: Packet network matching unit DP-BUS: D channel packet data dedicated bus

In the present invention, in the subscriber board (IBQA-N), the de-channel packet data is processed through a de-channel packet dedicated bus (DP-BUS), and the subscriber data is configured to be processed through an existing subhighway. do.

In addition, the present invention is characterized in that the capacity of the subscriber can be increased by using one more subscriber channel of the subhighway.

The present invention for achieving the above object is a D-channel matching unit for connecting a subscriber device (not shown) to the network (network); And a de-channel packet data dedicated bus (DP-BUS) for directly transmitting de-channel data between packet network matching units for directly accessing data transmitted and received through the D-channel matching unit to the packet network. do.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

First, in hardware, the present invention includes a de-channel packet data dedicated bus (DP-BUS) connected to directly transmit de-channel data between the D-channel matching unit 10 and the packet network matching unit 30.

In this case, the dedicated bus DP-BUS may be configured by connecting a serial bus provided in the CPI in the subscriber board IBQA-N with a serial bus provided in the CPI in the packet network matching unit 30.

In other words, the configuration of the subscriber and the packet network is directly connected without passing through the switch 20. The configuration is shown in FIG.

As shown, the sub-highway SHW processing the subscriber data from the D channel matching unit 10 to the packet network matching unit 30 through the switch 20 has one subscriber to the last channel (channels 30 and 31). (B1_127, B2_127) was further accommodated to process 128 subscriber data.

In addition, the de-channel packet data is transmitted through a dedicated bus (DP-BUS) connected to the D-channel matching unit 10 and the packet network matching unit 30.

FIG. 5 is a block diagram showing the detailed configuration of the D-channel matching unit 10 and the packet network matching unit 30 in the de-channel packet service using the de-channel packet dedicated bus (DP-BUS) according to the present invention.

As shown therein, the D-channel matching section 10 includes a bus matching circuit 10a for receiving de-channel packet data from a subscriber; It is composed of a CPI (10b) to separate the de-channel packet data received through the bus matching circuit (10a) and transfer control to the packet network matching unit 30 through a de-channel packet dedicated bus (DP-BUS).

Next, the packet network matching unit 30 is composed of a CPI 30a that directly receives the de-channel packet data through a de-channel packet dedicated bus (DP-BUS) and transmits the de-channel packet data to the packet network.

That is, the sub-way processes the subscriber data and transmits the de-channel packet data directly through the de-channel packet-dedicated bus (DP-BUS). Path) is much simpler and the load burden on the link controller 10c is reduced.

FIG. 6 is a flowchart illustrating a data processing process when a de-channel packet dedicated bus (DP-BUS) is provided as shown in FIG. 4.

As shown therein, once the D-channel matching unit 10 requests the de-channel packet service (S10), the D-channel matching unit 10 separates the de-channel packet data received from the subscriber (S11).

Next, if the de-channel packet data is transmitted through the de-channel packet dedicated bus (DP-BUS) (S12), the packet matching unit 30 decodes the de-channel packet dedicated bus (DP-BUS). Channel packet data is received (S13) and transmitted to the packet network (S14).

Accordingly, the D-channel matching unit hardwarely processes the D-channel data, which had to be processed differently from the subscriber data in the conventional switch 20, and increases the transmission speed through a direct connection path (DP-BUS) with the packet network. Therefore, the processing burden related to switching can be reduced in software.

As described above, the de-channel packet service method of the integrated information communication network of the present invention uses a de-channel packet data dedicated bus (DP-BUS) to process packet data and to process subscriber data through a subhighway. In general, the switch processing work on the packet data becomes unnecessary, so that the load can be distributed during data processing and one subscriber channel can be used to increase the capacity of the subscriber.

Claims (3)

A D-channel matching unit for connecting the subscriber device to a network; A de-channel packet data dedicated bus (DP-BUS) is provided between the packet network matching unit to directly connect the de-channel data transmitted and received through the D channel matching unit to the packet network. Channel packet service device. The de-channel packet service of claim 1, wherein the de-channel packet data dedicated bus is directly connected to the CPI serial bus of the D-channel matching unit and the CPI network of the packet network matching unit. Device. When the subscriber requests the de-channel packet service, the D-channel matching unit separates the de-channel packet data received from the subscriber and transfers the de-channel packet data to the packet network matching unit through the de-channel packet dedicated bus (DP-BUS). And the packet network matching unit transmits the received de-channel packet data to the packet network.