JPH0416037A - Packet switchboard - Google Patents

Abstract

PURPOSE:To attain packet switching in other channel even when packet switching through one channel is disabled by providing a means inter-converting a data link protocol of B and D channels and a means transferring layer 3 information of a packet mutually between both channels. CONSTITUTION:A B-channel packet handler module PHMB104 implements B channel packet store and forward switching and a D-channel packet handler module PHMD105 implements D channel packet store and forward switching. A central control section CC107 controls the PHMB104 and PHMD105 through a control bus 114 to transfer directly the packet layer 3 information from the PHMB104 to the PHMD105 via a transfer line 103. A protocol conversion section 108 of the link level is provided on the PHMB104 to transfer the received packet by the PHMB104 to the PHMD105, then even when the packet switching using the B channel is disabled by the packet switching, the packet switching processing using the D channel is attained.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field 1] The present invention relates to a packet switch that supports I5DN packet switching services.

[Prior Art] In the packet switching service in l5DN, packet communication is provided not only on the B channel which is an information channel (but also on the D channel which is a signal channel).
The usefulness of D-channel brush 95 communication has been proposed because the two B channels can be used for other communication purposes.

Against this background, with the spread of ISDN in recent years, the number of I5DN packet terminals that support D-channel Bake95 communication has increased. However, future packet switching systems will not only use D channel packets (
, a data terminal that also supports B channel packets must be accommodated, and a packet handler module (hereinafter referred to as PHM) as a packet switching control device having two bucket processing functions for B channel and D channel is required.

FIG. 4 is a block diagram showing an example of the system configuration of a conventional packet switch. In the figure, due to the hardware configuration of the packet switch 100, in order to reduce the cost burden on users who use only D channel packet terminals, the packet switch 100 is configured as a packet handler module (PHM).
It is divided into a PHMB 104 that performs channel packet exchange processing and a PHMD 105 that performs D channel packet exchange processing, and the user can optionally use the PHM.

In the packet switch shown in FIG. 4, B channel packets arriving at the office line 15DN-next group interface 101, the office line ISDN basic interface 102, or the extension ISDN basic interface 103 are sent to the central control unit (
CC) 107, the data is transmitted to 28MB 104 via transmission line 111 and communication path switch 106. Also,
The D channel packet is sent to PHMD 105 via control bus 112 under the control of central controller (CC) 107 . Note that the control bus 114 is connected to the central control unit (CC) 1.
07 is for controlling the 28MB104.

[Problems to be Solved by the Invention] However, in the conventional packet switch shown in FIG. 4, the PHM function is divided into PHMB 104 and PHMD 10.
For example, when transmitting a B channel packet from a 28MB104, the packet cannot be transmitted if a failure occurs or if the B channel is busy. This has the disadvantage that the switching service at the packet switch cannot be performed smoothly.

[Means for Solving the Problems] The present invention has been made for the purpose of solving the above-mentioned problems, and includes the following configuration as one means for solving the above-mentioned problems.

That is, in a packet switch that supports ISDN packet switching services, a B channel switching means for storing and forwarding B channel packets, a D channel switching means for storing and forwarding D channel packets, and a data link protocol for the B channel and a data link protocol for the D channel are used. The apparatus includes a protocol conversion means for mutually converting a data link protocol, and a means for mutually transferring layer 3 information of a packet between the B channel exchange means and the D channel exchange means.

[Operation] In the above configuration, even when packet exchange via the B channel or D channel becomes impossible, packet exchange can be performed using other channels.

[Embodiments] Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

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

In FIG. 1, a central control unit (CC) 107 controls the entire packet switching 1100, and connects an l5DN-next group interface 101 (hereinafter referred to as PRT) and an l5DN basic interface 102 (hereinafter referred to as BRT) via l.
Connected to 5DN120. In addition, the extension 15DN basic interface 103 (hereinafter referred to as BRI) has IS
A DN packet terminal 121 (hereinafter referred to as DTE) is connected. In addition, each interface supports 5 APIs (service access) as a packet data transfer service.
The layer 3 information of the D channel packet with point identifier)=16 is sent to the D channel packet handler module, which will be described later.

B channel packet handler module (hereinafter referred to as PHM)
A D channel packet handler module (hereinafter referred to as P
1o5 (referred to as HMD) is in charge of storing and forwarding D channel packets. The 28MB 104 also includes a protocol conversion unit 108 having a link-level protocol conversion function in order to perform layer 2 control of B channel packet exchange and establish a data link with the PHMD 105.

A central control unit (CC) 107 controls the communication path switch 106 to set PRTIOI, BRT 102°BRI 103
A communication path is formed between each interface of the PHMB 104 and the PHMB 104. The transmission path 111 is for transmitting B channel packets, and the control bus 112 is for transmitting D channel packets.
This is for controlling each interface of the 02°BR1103. In addition, the central control unit (CC) 107 connects the PHMB 104 and PHMD 105 via the control bus-114.
from the PHMB 104 via the transfer path 113.
X, 25, which is layer 3 information of the packet to the HMD 105
A packet level protocol (hereinafter referred to as X, 25PLP) is directly transferred.

Next, the packet processing procedure in the packet switch in this embodiment will be explained with reference to the flowchart shown in FIG.

A B channel packet or a D channel packet from the 15DN 120 is received by the PRTIOI or BRT 102, and is also received by the D channel packet, which is an extension terminal of the packet switch 100.
B channel packet sent from TE 121,
Alternatively, the D channel packet is received by the BR1103.

In step S1 of FIG. 2, when reception of a B channel packet or a D channel packet is detected on the above-mentioned interface, the interface that received the packet sends the packet via the control bus 112 in the next step S2. The central control unit (CC) 107 is notified of the reception. In step S3, the central control unit (CC) 107 that has received the notification controls the channel switch 106 to form a packet transmission path between the interface that received the packet and the PHMB 104 in the case of B channel packet reception. and sends the received B channel packet to PHMB 10
Accumulate to 4. Further, if the received packet is a D channel packet, the received packet is stored in the PHMD 105 via the control bus 112.

Next, if the received packet is a B channel packet, the determination in step S18 is YES, so step S
Proceed to step 4. That is, when starting to transmit the accumulated B channel packets, the PHMB 104 requests the central control unit (CC) 107 to check all accessible channels in step S4. Upon receiving the request, the central control unit (CC) 107 checks the B channel used for B channel packet distribution in step S5, and determines whether there is any error or failure.

If the result of the determination in step S5 is YES, that is, if there is a failure etc. in the B channel, the process advances to step S6.
The central control unit (CC) 107 is connected to the PHMD 105.
Requests the establishment of a data link on a channel. Then, in the following step S7, it is determined whether the link setting is completed.

If the data link is normally set as a result of the determination in step S7, the central control unit (CC) 107 obtains a YES determination in step S19, and then sets the PH link in step S8.
The MB l 04 is allowed to transfer the layer 3 information of the packet, X, 25 PLP, to the PHMD 105. Then, continue (in step S9, PHMBI○4
performs protocol conversion to establish a data link with the PHMD 105, and sends the
Transfer the PLP to the PHMD 105. The PHMD 105 sequentially stores the transferred X and 25 PLPs.

Next, step S 10te PHMD 105 is X.

Analyze the header of the 25PLP and identify the interface that transmits the 25PLP. Continuing (in step Sll), the PHMD 105 transmits the accumulated packets to the interface specified in step SIO via the control bus 112.

If it is determined in step S5 that B channel brushing 98 times is possible, the process advances to step S12, and the central control unit (C
C) 107 requests the PHMB 104 to set up a data link on the B channel for the B channel packet. Then, in step S13, it is determined whether the data link setting is completed, and if the data link is set normally, the central control unit (CC) 107 performs the next step S13.
14, the PHMB 104 is permitted to transmit the packet.

The PHMB 104, which has received permission to transmit the packet, analyzes the header part of the X, 25 PLP in step S15, and
Specify the interface that sends the V.25PLP. Then, the central control unit (CC) 107 controls the communication path switch 106 in step S16 to control the communication path 111, ! :,
The PHMB 104 is connected and the packet is sent to the interface specified in step S15.

If the received packet in step S3 is a D channel packet, the determination in step S18 is NO, and the process advances to step S6 (i.e., the D channel packet stored in the PHMD 105 is
When transmitting channel packets, the central control unit (CC)
107 requests the MD 105 to set up a data link on the D channel (P) in step S6, and in the next step s7
to determine whether the link setting is complete. When the link setting is completed, a negative determination is received in the following step S19,
Proceed to step S10 and enter X and 25P in PHMD105.
Analyze the LP header part. Central control unit (CC) 107
identifies the interface based on the analysis results,
Send the packet to the specified interface via control bus 112.

If it is determined in step S7 or step S13 that the requested link cannot be set up, the process proceeds to step S17, and the calling party is notified that the packet channel is not possible and that the incoming call is rejected.

As explained above, according to this embodiment, a link-level protocol converter is provided in the B-channel packet handler module, and packets received by the B-channel packet handler module are transferred to the D-channel packet handler module. As a result, even when the packet switching equipment cannot perform packet switching using the B channel, it is possible to perform packet switching processing using the D channel, so that the packet switching service can be smoothly performed.

Other Embodiments> In the above embodiment, the central control unit (CC) 107 controls the PHMB 104 and P) (MD1
However, as shown in the block diagram of FIG.
control bus 311 and X that control 04 and PHMD105,
It is also possible to directly connect the transfer path 113 of the 25PLP and share the transfer path and the control bus.

Further, in the above embodiment, when packet exchange using the B channel is impossible, packet exchange processing using the D channel is performed, but conversely, by providing a protocol conversion function in the D channel packet handler module, the D When packet exchange on a channel becomes impossible, packet exchange processing using the B channel may be performed as an alternative.

[Effects of the Invention] As described above, according to the present invention, packet data is transferred and the packet is transmitted using the D channel as a process for handling failures and busy states when transmitting packets using the B channel. It has the effect of being able to

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of a packet switch that is an embodiment of the present invention, FIG. 2 is a flowchart showing the processing procedure of the packet switch in this embodiment, and FIG. 3 is a packet switch according to another embodiment. FIG. 4 is a block diagram showing the structure of a conventional packet switch. In the figure, 100... packet switch, 101... central office line 15DN-next group interface (PRT) 102...
Central office line l5DN basic interface (BRT), 103・
・・Inner II I S D N basic interface (BR
I), 104... B channel packet handler module (PHMB), 105... D channel packet handler module (PHMD) 106... Communication path switch, 107... Central controller (CC), 108...
・Protocol converter, 111...transmission path, 112, 1
14,311...Control bus, 113...Transfer path, 1
20...15DN, 121...DTE. Patent applicant Canon Co., Ltd.

Claims (1)

[Scope of Claims] A packet switch that supports ISDN packet switching services, comprising B channel switching means for storing and forwarding B channel packets, D channel switching means for storing and forwarding D channel packets, and a B channel data link. The present invention further includes a protocol converting means for mutually converting a protocol and a D channel data link protocol, and a means for mutually transferring layer 3 information of a packet between the B channel switching means and the D channel switching means. Characteristic packet switching equipment.