JPH06244806A - Communication abnormality detecting method in optical communication system - Google Patents

Abstract

PURPOSE:To quickly and exactly detect a communication abnormality in an optical communication system. CONSTITUTION:A host communication controller 1 and slave communication controllers 2-1, 2-2,..., 2-n are connected by an optical fiber communication path 3. Communication information is transmitted in a bucket brigate system like the host 1 the slave machine 2-1 the slave machine 2-2 the slave machine 2-3, for instance, and when communication information (solid line arrow) is outputted from each communication device, an echo back signal (dot line arrow) is also outputted. Therefore, because the echo back signal is not outputted from the slave machine 2-2 and the slave machines 2-1 and 2-3 which are adjacent to the slave machine 2-2 do not receive the echo back signal when an abnormality occurs in the slave machine 2-2, for instance, it is judged that the abnormality occurs in the slave machine 2-2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is capable of promptly detecting a communication abnormality in an optical communication system which performs bidirectional communication on a single optical fiber communication path.

[0002]

2. Description of the Related Art FIG. 1 is a block diagram showing a recently developed optical communication system which realizes bidirectional communication through a single optical fiber communication path. As shown in the figure, this optical communication system includes a communication control device (hereinafter simply referred to as “host”) 1 that serves as a host, and a large number of communication control devices 2-1 and 2-2 that serve as terminal devices of the host 1. 2, 2-3, ..., 2-n
(Hereinafter simply referred to as “slave unit”). The host 1 and the slave units 2-1 to 2-n are connected in series by one optical fiber communication path 3. At this time, couplers 4-0, 4-1 and 4-for branching the optical signal are provided in the optical fiber communication path 3.
2, 4-3, ..., 4-n are the host 1 and the slave units 2-1 and 2-2.
It is arranged corresponding to -n.

The host 1 and the slave units 2-1 to 2-n respectively include optical signal transmitters 1a, 2a-1, 2a-2, 2a-.
3, ..., 2a-n and receiving units 1b, 2b-1, 2b-
2, 2b-3, ..., 2b-n, and CPUs 1c, 2c-1 and 2c that are signal processing units and each have a built-in memory.
, 2, 2c-3, ..., 2c-n. Also, natural number address numbers # 0, # 1, # 2, # 3, # 4, ..., #n that increase as the position of the host 1 increases.
Is given. The memory of the CPU 1c of the host 1 is
All address numbers # 0 to #n are stored as a list. CPU 2c-1 to 2c- of each child device 2-1 to 2-n
The n memory stores its own address numbers # 1 to #n, respectively.

FIG. 2 is an explanatory view conceptually showing the format of communication information used in the communication system.
As shown in the figure, in this format, a transmission source α, a transmission destination β and a relay unit γ are provided in the header, and a communication sentence δ is recorded in an area following the header.

In the communication system, when the communication control device receives the communication information, it performs the following processing based on the information in the header of the communication information.

When α ≦ γ <own address number <β or α ≧ γ> own address number> β, the address number of the relay unit γ of the received communication information is rewritten to the own address number, and the communication information Is output to the optical fiber communication path 3 as an optical signal and transmitted to the adjacent communication control device. When β = own address number, the message δ is fetched and processed. Do not do anything other than.

Therefore, for example, the slave unit 2-2 has α = #
When the communication information of 0, β = # n, γ = # 1 is received from the slave unit 2-1, the communication information is rewritten as γ = # 2 and is output to the optical fiber communication path 3 to output the slave unit 2. Send to -1, 2-3. As a result, the child device 2-1 determines that the above condition is satisfied, and does not perform any further transmission. On the other hand, child device 2-
In No. 3, it is determined that the above condition is satisfied, the predetermined processing as described above is performed, and the communication information is transmitted to the child device 2-2 (here, the condition here) and the child device 2-4 (here, the condition). Send to. In this way, the communication information is sequentially transmitted in the bucket brigade type. Then, in the child device 2-n, the above condition is satisfied and the communication message is fetched and processed.

In the above example, the communication information is sent from the smaller address number to the larger address number (in ascending order), but the communication information is also sent in the reverse direction (descending order). That is, for example, the child device 2-2 has α = # n, β = # 0, γ = # 3.
When the communication information is received from the slave unit 2-3, the communication information is rewritten as γ = # 2, output to the optical fiber communication path 3, and transmitted to the slave units 2-1 and 2-3. As a result, child device 2
In -3, it is determined that the above condition is satisfied, and further transmission is not performed. On the other hand, the child device 2-1 determines that the above condition is satisfied, performs the predetermined processing as described above, and transmits the communication information to the child device 2-2 (which is the condition here) and the host 1
Send to. In this way, the communication information is sequentially transmitted in the bucket brigade type. Then, in the host 1, the above condition is satisfied and the communication message is fetched and processed.

FIG. 4A is a schematic diagram of this optical communication system, FIG. 4B schematically shows a state in which communication information is transmitted in a bucket brigade manner in ascending order, and FIG. The state where the communication information is transmitted in the bucket brigade method in descending order is schematically shown. In FIGS. 4B and 4C, the arrow indicates the state in which the communication information is sent, but the dotted arrow indicates that the communication control device that received the above condition is satisfied and further transmission is not performed. Is shown. In this way, when the condition based on the communication information sent as an optical signal from the adjacent communication control device is satisfied and no further transmission is performed,
The received optical signal (communication information) is referred to as an echo back signal (information indicated by a dotted arrow in FIGS. 4B and 4C).

Thus, the adjacent host 1 and slave unit 2-
Bidirectional communication between the host 1 and the slave units 2-1 to 2-n is realized by one optical fiber communication path 3 by sequentially transmitting the communication information to the 1 to 2-n in a bucket brigade manner.

[0011]

However, in the above-mentioned optical communication system, even if an abnormality occurs in the communication control device or the optical fiber communication path, it cannot be detected quickly and accurately. In other words, when a person discovers that the whole system does not work well even if he / she communicates, he / she can know for the first time that some abnormality has occurred, and the abnormality detection is delayed. Further, in order to specify the abnormal portion, a person must inspect all the communication control devices and the optical fiber communication paths.

The present invention has been made in view of the above prior art, and an object of the present invention is to provide a communication abnormality detecting method for an optical communication system capable of detecting abnormality occurrence rapidly and accurately.

[0013]

SUMMARY OF THE INVENTION In order to solve the above problems, the present invention provides a communication control device as a host having an optical signal transmitter and receiver, and a CPU as a signal processor, and an optical signal transmitter. And a receiving unit and a CPU as a signal processing unit, and a plurality of communication control devices serving as terminal devices of the communication control device of the host are distributed by a coupler for branching an optical signal corresponding to each communication control device. A single optical fiber communication path is connected in cascade to give an address number that increases or decreases as the distance from the communication control device that is the host increases, and the transmission source α is included in the header of communication information sent as an optical signal. , The destination β and the address number of the relay unit γ are given, and when each communication control device receives the communication information, α ≦ γ <own address number <β or α ≧ γ> own address number> β When received When the address number of the relay section γ of the signal information is rewritten with its own address number, the communication information is output as an optical signal to the optical fiber communication path and transmitted to the adjacent communication control device, and when β = own address number, In an optical communication system having a function of taking in and processing a communication sentence in communication information, further outputting an optical signal to an optical fiber communication path, and doing nothing in cases other than the above,
When the optical signal returns from the adjacent communication control device within a predetermined time after the above conditions are satisfied and the optical signal is output, the optical fiber communication path connecting to the adjacent communication control device and the adjacent communication control device is established. It is characterized that it is normal, and when the optical signal does not return within a predetermined time, it is judged that there is an abnormality in the adjacent communication control device or the optical fiber communication path connecting to the adjacent communication control device.

[0014]

In the present invention, the communication information is transmitted in the bucket brigade type, and at this time, the echo back signal is also generated. Since the echo back signal does not occur when an abnormality occurs, it is determined that the abnormality occurs when the echo back signal is not received within a predetermined time after outputting the optical signal.

[0015]

EXAMPLES Examples of the present invention will be specifically described below.
It should be noted that parts having the same functions as those of the prior art are denoted by the same reference numerals, and overlapping description will be omitted.

The method of the present invention is applied to the optical communication system shown in FIG. 1, in which communication information in the format shown in FIG. 2 is transmitted. When the communication information is received, the host 1 and the slave devices 2-1, 2-2, ..., 2-n perform the following processing based on the information in the header of the communication information.

When α ≦ γ <own address number <β or α ≧ γ> own address number> β, the address number of the relay unit γ of the received communication information is rewritten to the own address number, and the communication information Is output to the optical fiber communication path 3 as an optical signal and transmitted to the adjacent communication control device. When β = own address number, the message δ is fetched and processed. Do nothing except when

The above-mentioned conditional processing is the same as the conventional one. When the condition of the present invention occurs, the echo back signal is output as an optical signal to the optical fiber communication path 3 and transmitted to the adjacent communication control device. In this case, the header information of the echo back signal is made equal to the header information of the optical signal that causes the condition of reception. Therefore, the communication control device adjacent to the communication control device that issued the echo back signal satisfies the condition that the echo back signal is received.

Further, according to the present invention, if the echo back signal is returned from the adjacent communication control device within a predetermined time after the condition is satisfied and the optical signal is output, the adjacent communication control device and the adjacent communication control device are connected. When it is determined that the optical fiber communication path 3 to be connected is normal and the echo back signal does not return within the predetermined time, there is an abnormality in the adjacent communication control apparatus or the optical fiber communication path 3 connecting to the adjacent communication control apparatus. The function of determining that is given to each communication control device 1, 2-1, 2-2, ..., 2-n.

Referring to FIG. 3, when the slave unit 2-2 has an abnormality, the slave unit 2-1 (in the ascending order) or the slave unit 2-3 (in the descending order) detects this abnormality. Explain that.

For example, when communication information is sent from the host 1 to the child device 2-n (in the ascending order), that is, α = # 0,
When β = # n, as shown in FIG. 3B, the communication information is sent from the host 1 to the child device 2-1 and then the communication information is sent from the child device 2-1 to the child device 2-2. At the same time, the echo back signal is sent from the child device 2-1 to the host 1. At this time, the host 1 determines that the slave device 1 is normal because the echo back signal returns within a predetermined time after outputting the communication information. On the other hand, the child device 2-2 receives the communication information, but does not output the communication information and the echo back signal because it is in an abnormal state. Therefore, the slave unit 2-1 determines that the adjacent slave unit 2-2 is abnormal because the echo back signal does not return within the predetermined time despite outputting the communication information.
This determination result is sent from the child device 2-2 to the host 1.

The same applies to the descending order. When the communication information is sent from the child device 2-4 to the child device 2-3, the communication information is sent from the child device 2-3 to the child device 2-2 and the child device. An echo back signal is sent from 2-3 to the child device 2-4. At this time, the child device 2-4 determines that the child device 2-3 is normal because the echo back signal returns within a predetermined time after outputting the communication information. On the other hand, the child device 2-2 receives the communication information, but does not output the communication information and the echo back signal because it is in an abnormal state. Therefore, the slave unit 2-3 determines that the adjacent slave unit 2-3 is abnormal because the echo back signal does not return within the predetermined time even though the communication information is output.

[0023]

As described above in detail with reference to the embodiments, according to the present invention, when an abnormality occurs in a communication control device or an optical fiber communication path, an optical signal is transmitted even if an optical signal is sent from an adjacent communication control device. Is not returned, this allows the adjacent communication control device to detect an abnormality.

[Brief description of drawings]

FIG. 1 is a block diagram showing an optical communication system to which the method of the present invention is applied.

FIG. 2 is an explanatory diagram showing a format of communication information.

FIG. 3 is an explanatory diagram showing a communication abnormality detection method according to the present invention.

FIG. 4 is an explanatory diagram showing a transmission state of communication information.

[Explanation of symbols]

 1 Communication Control Device (Host) 2-1 to 2-n Communication Control Device 3 Optical Fiber Communication Path 4-0 to 4-n Coupler

Front Page Continuation (72) Inventor Katsuya Yamashita 1-6, Uchisaiwaicho, Chiyoda-ku, Tokyo Nihon Telegraph and Telephone Corporation (72) Inventor Fumio Otsuki 1-6, Uchiyuki-cho, Chiyoda-ku, Tokyo Nihon Telegraph Phone Co., Ltd.

Claims (1)

[Claims] 1. A communication control device as a host having an optical signal transmitter and receiver and a CPU which is a signal processor, an optical signal transmitter and receiver, and a CPU which is a signal processor.
And a large number of communication control devices serving as terminal devices of the host communication control device by a single optical fiber communication path in which a coupler for branching an optical signal is arranged corresponding to each communication control device. Address numbers that are connected in cascade and increase or decrease with distance from the communication control device that serves as the host, and the source number α, destination β, and relay unit γ are included in the header of the communication information sent as an optical signal. When each communication control device receives the communication information, when α ≦ γ <own address number <β or α ≧ γ> own address number> β, the relay unit γ of the received communication information Rewrite the address number with your own address number,
The communication information is output as an optical signal to the optical fiber communication path and transmitted to the adjacent communication control device, and when β = own address number, the communication text in the communication information is captured and processed, and the optical signal is further transmitted to the optical fiber. In an optical communication system that has the function of outputting to the communication path and doing nothing in cases other than the above, after the optical signal is output from the adjacent communication control device after the above conditions are satisfied and the optical signal is output, within a predetermined time When it returns to, it is determined that the adjacent communication control device and the optical fiber communication path connecting to the adjacent communication control device are normal, and when the optical signal does not return within the predetermined time, the adjacent communication control device or the adjacent communication control device A communication abnormality detecting method for an optical communication system, comprising: determining that an optical fiber communication path connecting to a communication control device has abnormality.