JPH0831874B2 - Route switching method - Google Patents

Description

Description: (a) Technical Field of the Invention The present invention relates to a packet multiplexing device for packetizing and transmitting cyclically sent measurement quantities and binary state signals, and
In a packet switching network in which a first relay path is provided between one of the packet switching apparatuses and a second relay path is connected between the other, there is less delay when transmitting a packet from the packet multiplexing apparatus. The present invention relates to a route switching method for selecting or switching a relay path so that the relay path is used.

(B) Conventional Technology and Problems FIG. 1 is a block diagram of an example of a packet conversion network, and FIG. 2 is a block diagram centering on a packet multiplexer of the conventional example, and each block in PMX1 has required functions. A processor (not shown) controls the operation between the blocks in each area of the memory of the program that fulfills.

In the figure, 1 and 2 are packet multiplexers (hereinafter referred to as PMX) and 3
8 to 8 are packet switching devices (hereinafter referred to as PS), 9 to 12 are relay paths, 9 and 11 are first relay paths, and 10 and 12 are second relay paths. 1
3 is a terminal data input unit, 14 is a packet assembly unit, 15 is a packet buffer, 16 is a route switching unit, 17 and 18 are transmission buffers, 19 and 20 are transmission control units, 21 and 22 are reception control units, and 23 is a relay. Reference numeral 24, 25 is a receiving buffer, 26 is a packet disassembling unit, and 27 is a terminal data output unit.

Referring to FIG. 1, PMX1 and PMX2 are the first relay paths 9 and 11, respectively.
The second relay paths 10 and 12 are connected to PS7, 3, 8 and 6, respectively, and PM
Between X1 and X2 is the first relay line 9, PS7, transmission line, PS8, first relay line 11 and second relay line 10, PS3, transmission line, PS4, transmission line, PS5, transmission line, PS
6, are connected via a second relay path 12, for example, a second view of the terminal a ₁ ~a eg voltage is transmitted cyclically from _n, current, power measurements and breaker ON OFF status signal Of 2
The value status signal is packetized by PMX1 or 2 and the first relay path 9,
A route including 11 or a route including the second relay paths 10 and 12 is sent to the PMX 2 or 1 of the other party and is sent to, for example, the terminals b _{1 to} b _n in FIG.

Next, the operation of the PMX will be described with reference to FIG.
For example, voltage transmitted cyclically from terminals a _{1 to} a _n ,
The measured current and power values and the circuit breaker ON / OFF state signal are input to the terminal data input unit 13, assembled into packets by the packet assembly unit 14, and queued in the packet buffer 15. As a conventional route switching system performed by the route switching unit 16, there are a route alternate switching system and a route not switching back system. The alternate route switching method is a method in which a relay path for transmitting a packet is alternately selected and switched between the first relay path, the second relay path, and the first relay path for each packet transmission. This is a method in which once the first relay path or the second relay path is selected, another relay path is not selected unless the selected relay path becomes an obstacle.

Therefore, the route switching unit 16 selects a relay path by any of the route switching methods and queues it in the transmission buffer 17 or 18. The packet queued in the transmission buffer 17 or 18 is transmitted to the PS 7 or 3 via the transmission control unit 19 or 20 and the first relay path 9 or the second relay path 10.

Hereinafter, the operation of the receiving side will be described with the PMX1 of FIG. 2 as the receiving side PMX2. Packets sent from PS7 or 3 are PMX
2 is input to the reception control unit 21 or 22 and the reception buffer 24 or 2
Queued to 5. The packet decomposition unit 26 decomposes the packet in the reception buffer 24 or 25 into terminal-oriented data, and the terminal data output unit 27 outputs the terminal data to the terminals b _{1 to} b _n .

The communication states of the first relay path 9 and the second relay path 10 that transmit a packet to the partner PMX via the first relay path 9 and the second relay path 10 are, for example, normal status and congestion if the delay amount of the packet is listed in ascending order. There are state, detour-disabled state, and transmission line failure state. The congestion state is the period from the reception of the congestion notification packet by the network control packet to the receipt of the congestion release notification packet from the belonging PS7, 3, and the detour-disabled state. Is the case where the detour-notification notification packet is received as the network control packet from the belonging PS 7,3. The line failure status is the line blocking status, the line failure status, the data link failure, the busy continuation, or the queue length over sending has occurred. When all the statuses are cleared, the transmission path failure status is released. .

The transmission control units 19 and 20 transmit the packets, but recognize the normal state and the transmission line failure state of the relay line, and the relay line state management unit
Notify 23. Further, the reception control units 21 and 22 notify the relay path state management unit 23 of the reception of the congestion notification packet, the congestion release notification packet, and the detour impossible notification packet. Relay status management unit
Although 23 notifies the above-mentioned state to the route switching unit 16, the route switching unit 16 conventionally performs the route switching by the alternate route switching system or the route without failback system except the transmission line failure state. Therefore, in the alternate route switching method, there are two types of data routes in the network, and in the case of FIG. 1, the number of PS that a packet sent earlier through the second relay path 10 than PMX1 passes is large. There is a drawback that a packet sent via the first relay path 9 sent may be overtaken. In the route non-revertive method, if a relay path with a large amount of delay is selected, this relay path continues to be selected. There is a drawback that a long delay continues.

(C) Object of the invention In view of the above drawbacks, the object of the present invention is to select or switch to always use a relay path with a small delay amount when transmitting a packet according to the communication state of the first relay path and the second relay path. There is a route switching method.

(D) Structure of the Invention In order to achieve the above-mentioned object, the present invention provides a PMX with a first structure.
The expected communication states of the relay path and the second relay path are combined according to the delay amount, and the relay path with the smaller delay amount is selected for each combination, and then the relay path with the smaller delay amount is transmitted to the specific destination. In the case where either the first relay path or the second relay path is designated as the relay path and the communication state of the first relay path and the second relay path is given, the designated relay path is selected. A table showing each relay path is prepared in advance so that it can be identified whether to switch to another relay path or not, and the route switching unit that controls the switching of routes,
The communication status information of the first relay path and the second relay path recognized in the own packet multiplexer and / or the communication status information of the first relay path and the second relay path received from the packet switching apparatus is the relay path status. When notified via the management unit, the contents of the designated relay route in the table are referred to, and the designated relay route is selected or selected according to the contents shown in the table for the communication state. It is characterized in that means for switching to another relay path is provided.

(E) Embodiment of the Invention An embodiment of the present invention will be described below with reference to the drawings.

FIG. 3 is a block diagram centering on the PMX of the embodiment of the present invention, and FIG. 4 is a diagram showing a relay path which is selected or switched depending on the communication state of the route switching condition matrix table 28 of FIG.

In FIG. 3, those having the same functions as those in FIG. 2 are indicated by the same symbols.
Reference numeral 1'is a PMX corresponding to PMX1 in FIG. 2, 16 'is a route switching unit, 23' is a relay state management unit, and 28 is a route switching condition matrix table.

Hereinafter, assuming that the PMX1 ′ shown in FIG. 3 is installed at the position PMX1 in FIG. 1 and the packet is transmitted to the PMX having the same configuration as the PMX1 ′ installed at the position PMX2 in FIG. explain. A table showing the relay paths that are selected or switched depending on the communication state of the first and second relay paths shown in FIG. 4 and has a small delay amount is prepared in advance and provided in the route switching condition matrix table 28. In the upper part of Fig. 4, a specific destination from PMX1 ',
For example, the relay path to be selected or switched when the first relay path 9 is designated as the relay path when transmitting a packet to the PMX installed at the position PMX2 in FIG. , The second relay line 10 is also on the bottom.
The relay path to be selected or switched when is specified. The relay path to be selected and switched is determined by the communication status of the first relay path 9 and the second relay path 10. However, in the figure, when the designated relay path is selected, only the number of the relay path is designated. When switching from to another relay route, the number of the relay route is marked with a circle.

For example, in FIG. 1, the first relay path 9 and the second relay path 10
If any of the above is in a normal state, the delay amount is smaller in the first relay path 9 having a smaller number of PS to relay, so when the first relay path 9 is designated, the first relay path 9 is selected. This is shown as "9" in the upper part of FIG. Also,
When the second relay path 10 is designated, the first relay path 9 having a small delay amount even if the second relay path 10 is designated as shown by "9" with a circle in the lower part of FIG. It is shown that it can be switched to. In this state, if the first relay path 9 becomes congested, if the first relay path 9 is designated, it switches to the second relay path 10 with a smaller delay amount and designates the second relay path 10. If it is, it is indicated that the designated second relay path 10 is switched back (the second relay path 10 is selected). That is, according to this table, it is possible to select or switch to use a relay path with a small delay amount.

The difference between FIG. 3 and FIG. 2 is that there is no detour impossible notification because there is no notification of a release signal for the detour impossible notification and there is no choice but to judge whether or not a detour impossible notification packet comes when data is sent. And a route switching condition matrix table 28 is provided and a route switching condition matrix table 28 is provided from the relay state management unit 23 'after a certain period of time. The point is to select or switch to use the relay path with the smaller delay amount according to the communication status of the first relay path and the second relay path notified from the relay path status management unit 23 '.

That is, according to the normal state, the congestion state, the detour impossible state, and the relay path failure state of the first relay path 9 and the second relay path 10 notified from the relay path state management section 23 ', the route switching section 16' is set to the state shown in FIG. If the communication state is the same according to the route selection switching condition of the route switching condition matrix table 28 shown in, the first relay path 9 is selected, and if the communication state of the second relay path 10 has a smaller delay amount, the first relay path 9 is selected. 2 Select the relay path 10 and switch to the relay path with the smaller delay amount when the communication state changes. Therefore, a relay path with a small delay amount is always used.

Therefore, later packets do not overtake earlier packets.

(F) Effects of the Invention As described in detail above, according to the present invention, a table for selecting or switching to use a relay path with a small delay amount according to the communication state of the first relay path and the second relay path is created in advance. Accordingly, the PMX selects the relay path, so that there is an effect that the packet transmitted first is not overtaken by the packet transmitted later, and the relay path with a small packet delay can always be used.

[Brief description of drawings]

FIG. 1 is a block diagram of an example of a packet switching network, and FIG. 2 is a block diagram centering on a conventional packet multiplexer.
FIG. 3 is a block diagram centering on the packet multiplexer of the embodiment of the present invention, and FIG. 4 is a diagram showing a relay path which is selected or switched according to the communication state of the route switching condition matrix table of the embodiment of the present invention. . In the figure, 1, 1'and 2 are packet multiplexers, 3 to 8 are packet switching devices, 9 and 11 are first relay paths, 10 and 12 are second relay paths, 13 is a terminal data input section, and 14 is a packet. Assembling unit, 15 is a packet buffer, 16 and 16 'are route switching units, 17 and 18 are transmission buffers, 19 and 20
Is a transmission control unit, 21 and 22 are reception control units, 23 and 23 'are relay path state management units, 24 and 25 are reception buffers, 26 is a packet disassembly unit, 27 is a terminal data output unit, and 28 is a route switching condition matrix. Show table.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hiroshi Irie 1 Higashi-shinmachi, Higashi-ku, Nagoya, Aichi Chubu Electric Power Co., Inc. (72) Inventor Masashi Kishida 1015 Kamiodanaka, Nakahara-ku, Kawasaki-shi, Kanagawa Fujitsu Limited (72) Inventor Hideo Aoyama 5-33-1 Shiba, Minato-ku, Tokyo Inside NEC Corporation (56) References JP-A-56-140744 (JP, A) JP-A-56-129456 (JP, A) JP-A-49-95502 (JP, A) JP-A-54-137906 (JP, A)

Claims (1)

[Claims] 1. A first relay path between a packet multiplexer for packetizing a cyclically sent measurement quantity and a binary state signal for transmission and one of two packet converters,
In a packet conversion network in which a second relay path is provided between the other, in the packet multiplexing device, the expected communication states of the first relay path and the second relay path are combined according to the delay amount, and each combination is combined. After selecting a relay path with a small delay amount,
Either the first relay path or the second relay path is designated as the relay path for transmitting a packet to a specific destination, and the relay path with the small delay amount is specified.
When the communication status of the relay path is given, a table is created in advance for each relay path so that it is possible to identify whether to select the specified relay path or switch to another relay path. To the route switching unit for controlling the communication state information of the first relay path and the second relay path recognized in the own packet multiplexer and / or the first relay path and the first relay path received from the packet converter. 2 When the communication status information of the relay path is notified via the relay path status management unit, refer to the contents of the specified relay path in the table,
A route switching system comprising means for selecting a designated relay path or switching to another relay path according to the contents shown in the table for the communication state.