JPH0628359B2 - Transmission system structure recognition method - Google Patents

Description

Description: FIELD OF THE INVENTION The present invention relates to a method for recognizing a system structure of a transmission system.

[Background of the Invention]

In the double loop transmission system with detour, the system structure is changing because the detour is configured according to the occurrence of a fault in the system. In the conventional double loop transmission system system (for example, Japanese Patent Application No. 54-115300), there is no means for recognizing under what structure the system is currently operating.
There was a problem in system maintenance.

[Object of the Invention]

An object of the present invention is to improve the maintainability of the system by enabling the recognition of the structure of the transmission system at any time in the transmission system.

[Outline of Invention]

In order to achieve such an object, the present invention provides an address from a transmission control device to a transmission medium in a transmission system in which a plurality of transmission control devices, each of which is assigned an address, are connected by a transmission medium to transmit data. Each transmission control device that has transmitted a train message and received this message sequentially sends its own address to the transmission medium, and the transmission control device that has received the message with these addresses added will receive the received message. Parse the address string of
It is characterized by recognizing the system structure.

Example of Invention

An embodiment of the present invention will be described below with reference to FIGS. FIG. 1 (a) shows the overall configuration of the loop transmission system. The system has loop transmission lines 1 and 2 that transmit information in opposite directions. There are transmission control devices (hereinafter, referred to as NCPs) 11 to 14 and 21 to 24 on the loop, and detour routes 41 to 44 and 51 to 5 are provided between the paired NCPs.
Connected with 4. Further, the host processing devices 31 to 34 have bidirectional transmission paths (61, 7) in each pair of NCPs.
1), (62, 72), (63, 73), (64, 7)
4). Further, in this example, the terminal 31
As a system tester of this system, a CRT terminal 3010 for displaying the structure of the system is connected. FIG. 1 (b) is a diagram showing an example of a transmitted message. FC52 is a function code that corresponds to the content and function of the data. SA53 is the address (source address) of the NCP that created and sent the message,
Data 54 is information to be processed. FCS55
Is error detection data, and F51 and F55 are flags indicating the beginning and end of a message.

Now, as shown in FIG. 2 (a), between the NCPs 22 and 23,
It is assumed that transmission between the NCPs 12 and 13 has become impossible.
(Fault A) If the NCP 21 sends a message to Loop 2 at this time, this message is returned to NCP 2 by Fault A.
It doesn't come back to 1. Since the message sent by itself does not return, the NCP 21 detects that there is an abnormality on the transmission path, and sends the small loop check signal 301 as the sender. Further, it requests the NCP 11 to send the small loop check signal 303. N
NCP that received a small loop check signal from CP21
22 sends the signal to the NCP 12 and emits a small loop check signal 302 by itself as a transmission source, but due to the fault A, this signal does not return to the NCP 22. Similarly, the small loop check 30 emitted by NCP13
7 also does not return to NCP13.

By the above process, N which detected the abnormality on the small loop
The CPs 22 and 13 form the detours 42 and 53, and thereafter,
Send the message to the detour. In addition, this NCP22,1
In order to check whether or not the failure has been recovered, 3 periodically generates a small loop check signal and a large loop check signal that bypasses any NCP and is not transmitted.

Next, as shown in FIG. 2 (b), consider the case where transmission between the NCPs 22 and 23 becomes impossible. Also at this time, the NCPs 22 and 13 form a detour, just as in the above process. However, thereafter, in the NCP 13, the large loop check signal 401 for recovery detection returns, and the bypass 53 is released.

According to the failure detection / recovery function described above, the data flow of this loop transmission system is classified into the three patterns shown in FIG. 3 (when the NCP 21 is the source). Hereinafter, the structure of FIG. 3 (a) is called a complete loop type, FIG. 3 (b) is called a perfect detour type, and FIG. 3 (c) is called an imperfect detour type.

Hereinafter, a method for recognizing the structure of this loop transmission system will be described with reference to FIGS. This structure recognition is performed by the system tester 31 shown in FIG.

The system tester 31 sends data to its own NCP in order to recognize the system structure. Here is my NCP
Refers to the NCP connected to the system tester. (FIG. 4) Hereinafter, this data will be called an address train. Specifically, the data having the function code FCadr indicating the address train in the FC portion of the data is sent to both NCPs 21 and 11.
(201, 101). Next, each of the NCPs 21 and 11 receiving this data sends FCa to the FC section.
Data having own NCP addresses N ₁ and M ₁ in the dr and Data parts is sent out on the transmission path (2010, 1010).

FIG. 5 shows the processing of the NCP which has received the address train. First, the own NCP address is added to the end of the received data Data section (901). Furthermore, when this data is self-transmitted and there are two or more own NCP addresses in the Data section, it is sent to the host processor (90
4) otherwise, depending on the NCP state, the data is sent to the transmission line or the detour (906, 907).

After all, the address train is a source N of one round on the transmission path.
Return to CP (Fig. 6 (a)). The contents of the address train data Data section received by the host processor are as shown in FIG. 6 (b).

Next, the processing of the system tester after receiving the address train will be described with reference to FIGS. Fig. 7
(a) is the data area in the system tester, Fig. 7 (b)
[Fig. 3] is a diagram showing a processing flow.

The received address train is first stored in the reception data area 802 (850). Next, the own NCP address area 801 is referred to. A of this 801 is an area of loop A, and B is an area of loop B. Except when data is entered in both of these areas, it is considered that the own NCP address has not been confirmed, and the last NCP address of the received address train Data is set in the own NCP address area (852). At this time, for convenience, the loop to which the previously received NCP belongs is referred to as loop A and the other loop is referred to as loop B.
After the processing 852, when only the own NCP address of the loop A is confirmed, the processing by this reception address train is temporarily suspended there and stored in the data storage area 803.

If both the own NCP address are confirmed, first, it is judged which of the patterns in FIG. 3 (a) to (c) the received address train belongs to (855), and the structure confirmation is performed according to the pattern. Then, the result is stored in the structure area 804 (857).

At this time, when the structure pattern is a perfect loop type,
Only information about the one-sided loop is available. Therefore, the old structure area 805 is used to overlap the complete loop type structure (FIG. 7 (c)). Specifically, complete loop structure data is stored in the corresponding loop area of the old structure area 805 (860), and the contents of the old structure area 805 are stored in the structure area 804 (86).
1) Perform processing. If the structure is not the complete loop type structure, the old structure area 805 is reset (859).

After the above structure confirmation processing is completed, the system tester displays the contents of the structure area 804 on the CRT terminal connected to itself (862). Furthermore, the data storage area 803
If there is data for which processing has been suspended due to unconfirmed own NCP address, the above process is repeated for that data, and the structure is recognized and displayed.

Next, the pattern classification of the process 855 in FIG. 7B will be described with reference to FIGS.

FIG. 8 shows an address train D corresponding to each structural pattern.
It shows the characteristics of the contents of the ata part.

Considering the system of FIG. 8 (a), the addresses of the NCPs (own NCPs) 21 and 11 connected to the system tester 31 are A and B. At this time, the address train Dat
The pattern of the own NCP address appearing in part a is uniquely determined by the system structure (FIGS. 8 (b) to (d)). From this, the system structure can be classified by focusing on its own NCP address. FIG. 9 shows this processing. That is, among the own NCP addresses appearing in the address train Data part, the structural patterns are classified according to whether the first and the second match (921) or the first and the third match (922). Is.

Next, a structure recognition process (FIG. 7 (b) 856) executed according to the structure pattern determined by the above process will be described with reference to FIG.

(1) Complete loop type FIG. 10 (a) shows a complete loop type system structure and an address train Data part. In the case of the complete loop type, the system structure is obtained by the address string 700 between the first own NCP address 600 and the next own NCP address 601.

(2) Complete detour type FIG. 10 (b) shows the complete detour type system structure and address train Data part. In the case of the complete detour type, the first own NCP address 603 to the second own N
Two NCPN _i and N _j occupying the middle of the address sequence up to the CP address 604 form a detour.
P pair. Similarly, NCP N _k and N _l , which occupy the middle between the second own NCP 604 and the third own NCP 605, are also NCP pairs forming a detour.

From the above, the system structure is obtained from A ... N _i (701), N ₁ ... N _n (704) B ... N _j (702), N _h ... N _m (703).

(3) Imperfect detour FIG. 10 (c) shows an incomplete detour type system structure and an address train Data part. Even in the case of the non-complete detour type, the first own NC as in the case of the complete detour type
Second own NCP address 607 from P address 606
2 NCP N occupying the middle of the address sequence between
_i and N _j are NCP pairs forming a detour. Second own NCP address 607 and third own NCP address 6
The address sequence 706 between 08 and 08 is the address sequence of the other loop. From the above, the system structure is obtained by A ... N _i (705) B ... N _m (706).

Specifically, the system tester performs the following processing according to each structural pattern.

(i) In the complete loop type structure The second to the last address string of the received address train Data is used as it is as the system structure.

(ii) In the case of the complete detour type structure: Search for the own NCP address position in the NCP address string of the received address train Data part.

When The NCP of is defined as a detour configuration NCP.

The address string of is the system structure.

(iii) In the case of the non-complete detour type structure: Search for the own NCP address position in the NCP address string of the received address train Data.

When Let the second NCP be a detour configuration NCP.

The address string of is the system structure.

According to the methods described so far, no matter what the structure of the system is, the system tester knows the system structure at that time by sending the address train and analyzing the feedback data. It is possible.

In this embodiment, the host processing device 31 (see FIG.
Although (a)) has been described as performing structure recognition, this method allows structure recognition by any host processor.
It is also possible for multiple host processors to recognize the structure.

〔The invention's effect〕

According to the present invention, it is possible to recognize at what point under what structure the transmission system is currently operating, so that maintenance personnel can grasp the system state and maintainability of the system is improved. improves.

[Brief description of drawings]

1 to 3 are explanatory diagrams of a loop transmission system, and FIGS. 4 to 10 are explanatory diagrams of an embodiment of the present invention.

Claims (3)

[Claims] 1. A plurality of transmission control devices, each of which is assigned an address, are connected by a transmission medium, and are configured so that data can be transmitted in a circulating manner through at least two transmission paths. A method for recognizing a structure of a transmission system for changing data according to a transmission path, wherein each of the transmission control devices transmits an address train message to the transmission medium and receives the message. Is a transmission control device that sequentially adds its own address to the received message and sends it to the transmission medium, and receives the message to which the address is added,
A structure recognition method for a transmission system, characterized in that the address sequence is analyzed based on the address of the own transmission control device appearing in the address sequence in the received message to recognize the structure pattern of the transmission system. 2. The structure recognition method for a transmission system according to claim 1, wherein the address sequence is analyzed based on the recognition result of the structure pattern to recognize the structure of the transmission system. 3. A plurality of processing devices comprising two loop transmission lines for mutually performing reverse direction data transmission, and a transmission control device provided in pair with the two loop transmission lines, and the pair. In a structure recognizing method of a double loop transmission system having a detour for transmitting data between the transmission control devices, a message called an address train is transmitted from any of the transmission control devices, and each of the transmission control devices When the message is received, its own address is added to the data part of the message and the message is sent to the transmission line or detour,
The processing device, which has received the message to which the address of each transmission control device on the transmission path is added by the transmission control device, analyzes the address string of the data part of the message, and its own transmission control device in the address string. A method for recognizing a structure of a loop transmission system, wherein the structure pattern of the loop transmission system is classified based on the appearance pattern of the address, and the structure of the loop transmission system is recognized based on the classification result.