JPH0837498A - Optical local area network - Google Patents

Abstract

PURPOSE:To obtain the optical local area network in which information is sent by utilizing a normal transmission control section to the utmost even on the occurrence of faults of plural parts of a transmission line. CONSTITUTION:On the occurrence of a fault at two positions of an active optical transmission line 28, a transmission control section conducts the control as follows; When the transmission control section 1 cannot receive an optical signal from the active optical transmission line 28, the control section 1 discriminates it that a fault takes place in the optical transmission line 28 and supplies power to a transmission line changeover section 21 to switch the active optical transmission line 28 to a standby optical transmission line 29. Furthermore, other transmission control sections 1 than the transmission control section 1 disconnected from the active optical transmission line 28 discriminate it that the disconnected transmission control section 1 is disconnected from the active optical transmission line 28 because no message comes from the transmission control section 1 and switches the transmission line in use into other standby optical transmission line 29 by a transmission line changeover section 21. As a result, the transmission of information among the transmission control sections 1 is made available.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical local area network for transmitting information by an optical fiber cable.

[0002]

2. Description of the Related Art In a conventional optical local area network (LAN), information of a computer or the like is converted into an optical signal and information is exchanged between the computers. The optical signal is as shown in FIG. Is transmitted through one optical transmission line. That is, the conventional optical local area network is connected to an information supply source such as a computer, converts the information into an optical signal, and controls the information transmission between the computers. It is composed of an optical transmission line 2 for transmitting an optical signal between them, and an optical switch unit 3 for disconnecting the transmission control unit 1 from the optical transmission line 2 when a failure occurs in the transmission control unit 1.

As shown in FIG. 5, the optical transmission line 2 uses a two-core optical fiber consisting of a regular optical fiber 10 and a loopback optical fiber 11, and an optical switch section 3
Both fibers 10 and 11 are connected to the transmission control unit 1 via the. The optical switch unit 3 includes a plurality of optical switches 1
2, and normally the normal system optical fiber 10 and the loopback system optical fiber 11 are connected to the transmission control unit 1 via the optical switch 12, but when the transmission control unit 1 fails due to a failure or the like, The optical switch 12 is switched to the bypass optical fiber side 9, and the transmission control unit 1 is separated from the regular system optical fiber 10 and the loopback system optical fiber 11.

The optical switch 12 is constructed as shown in FIG. 6, and its switching is performed by power supply from the transmission control unit 1, and the power supply is stopped by "optical switch bypass control".

That is, the optical switch 12 is shown in FIG.
As shown in FIG.
The movable range of the switch movable portion 14 is restricted by the stoppers 15a and 15b. Further, an electromagnet 16 is arranged below the switch movable portion 14, and the electromagnet 16 is
The switch movable portion 14 is moved by driving.
That is, the switch movable portion 14 is constantly given an upward force by a spring (not shown), and is displaced upward to contact the stopper 15a when the electromagnet 16 is not supplied with power. Stop. Then, when power is supplied to the electromagnet 16, the attracting force moves the switch movable portion 14 downward, abuts the stopper 15b, and stops. The switch movable unit 14 is provided with an IN fiber 17a connected to the optical transmission line 2 and a Tx (transmission side) fiber 17b connected to a signal transmission end of the transmission control unit 1. In this case, the Tx fiber 18a is provided above the IN fiber 17a at a predetermined interval. Further, the switch fixing unit 13 has an OUT fiber 17b connected to the optical transmission line 2 and an R connected to a signal receiving end of the transmission control unit 1.
An x (receiver) fiber 18b is provided. In the switch fixing portion 13, the OUT fiber 17b is provided above the Rx fiber 18b with a predetermined interval.

FIG. 6A shows a connection state at the time of normal operation, that is, power is supplied to the electromagnet 16 and the switch movable portion 1
4 shows the state when moving downward, IN
The fiber 17a and the Rx fiber 18b face each other, and the Tx fiber 18a and the OUT fiber 17b face each other. Therefore, from the optical transmission line 2 to the IN fiber 17
The information input to a is transmitted to the Rx fiber 18b and sent to the transmission control unit 1. In addition, from the transmission control unit 1 to T
The information output to the x fiber 18a is transmitted to the OUT fiber 17b and is output to the optical transmission line 2.

FIG. 6B shows a connection state at the time of bypass, that is, a state in which the power supply to the electromagnet 16 is stopped and the switch movable portion 14 moves upward.
IN fiber 17a and OUT fiber 17b face each other,
The Tx fiber 18a and the Rx fiber 18b are vertically displaced. Therefore, the information input to the IN fiber 17a from the optical transmission line 2 is the OUT fiber 17b.
Is transmitted to the optical transmission line 2. At this time Tx
Since the fiber 18a and the Rx fiber 18b are vertically displaced, information is not input / output to / from the transmission control unit 1, and the bypass operation is performed.

The power supply to the electromagnet 16 is stopped by detecting a serious failure when the power supply to the outside cannot be supplied due to a hardware failure of the transmission control unit 1 or by self-diagnosis of the transmission control unit 1. Occurs when the power supply to the optical switch 12 is forcibly stopped.

Further, in the conventional optical local area network, when a failure such as disconnection of the optical transmission line 2 occurs, the transmission line is reconfigured by loopback in the transmission control unit 1 as shown in FIG. . Optical transmission line 2 is 2
It is composed of the optical fiber of the core, and normally, the optical signal is transmitted only by using the optical fiber 10 of the common system. When the optical signal is not transmitted in the optical transmission line 2 due to disconnection or the like, the transmission control unit 1 at both ends of the fault location detects the fault, and the loopback optical fiber 1 in the transmission control unit 1 is detected.
1 is used to loop back to reconfigure the optical transmission line 2.

[0010]

In the conventional optical local area network shown in FIG. 4, when a failure occurs in two places in the transmission line, the transmission control unit 1 sandwiched between the failed parts is normal. However, there is a problem that it is disconnected from the optical transmission line as shown in FIG.

The present invention has been made in view of the above circumstances and has been made to solve the problem. Information transmission is performed by using a normal transmission control unit to the maximum even when there are failures in transmission lines at a plurality of locations. The present invention provides an optical local area network.

[0012]

An optical local area network according to the present invention is connected to an information supply source to convert information from the information supply source into an optical signal or to transfer the optical signal to the information supply source. A transmission control unit for converting information into a signal and controlling information transmission between the same information supply sources, and a common and loopback transmission line for transmitting an optical signal between the transmission control units. Two optical transmission lines for standby,
A transmission line switching unit that is connected to the transmission control unit and switches the connection of the transmission control unit to the optical transmission line of the other system when a failure occurs in the optical transmission line of the other system, and this transmission line switching unit is connected. And a plurality of optical switch units which are respectively connected to the optical transmission lines of the two systems and, when a failure occurs in the transmission control unit, disconnect the transmission control unit having the failure from the optical transmission line. It is characterized by having done.

[0013]

When a failure occurs in two places on the optical transmission line in use, the transmission control section performs the following control. That is,
When the optical signal cannot be received from the optical fiber of the optical transmission line being used, the transmission control unit determines that a failure has occurred in the optical transmission line and supplies power to the transmission line switching unit to use the optical transmission. Converts the line to a waiting optical transmission line.

Further, in the transmission control units other than the transmission control unit separated from the optical transmission line, since the message from the transmission control unit is not sent, the transmission control unit is disconnected from the current transmission line. It is determined that the transmission line switching unit is supplied with power, and the transmission line in use is switched to another standby optical transmission line. As described above, all the normal transmission control units are switched from the current optical transmission line to the standby optical transmission line, and information is transmitted using this standby optical transmission line.

[0015]

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of an optical local area network using conversion transmission lines according to an embodiment of the present invention.

The optical local area network according to the present invention comprises two optical transmission lines, a normal optical transmission line 28 and a standby optical transmission line 29, and a transmission line switching unit 21 for switching between the normal and standby optical transmission lines. It is characterized by having. The transmission line switching unit 21 has a function of switching and connecting the transmission control unit 1 to the optical switch unit 24 provided in the regular optical transmission line 28 or the optical switch unit 25 provided in the standby optical transmission line 29. Have The optical switch units 24, 25
Has the same configuration as the conventional one shown in FIG. The transmission control unit 1 is connected to an information supply source such as a computer and converts information from the information supply source into an optical signal or converts the optical signal into a signal to the information supply source, and the information supply source. Controls information transmission between each other. The common optical transmission line 28 and the standby optical transmission line 29 are optical fibers each including a pair of common and loopback transmission lines.

The transmission line switching unit 21 for switching the above optical transmission line is constructed as shown in FIG. That is, the transmission line switching unit 21 includes a transmission line conversion optical switch 30 for switching the regular optical fiber 10 and the loopback optical fiber 11 to the regular optical transmission line 28 or the standby optical transmission line 29, and the optical transmission line 28. Switch unit 24 and standby optical transmission line 2
The bypass control unit 22 supplies power to the optical switch unit 25 of No. 9 and performs optical switch bypass control.
Transmission line switching control for the transmission line switching optical switch 30 and the bypass control 22 is performed by an electric signal from the transmission control unit 1. Further, the bypass control unit 22 includes the optical switch units 24 and 2 for the regular optical transmission line 28 and the standby optical transmission line 29.
Only the control signal from the transmission control unit 1 is distributed so that any of the 5 can be controlled.

As shown in FIG. 3, the transmission line conversion optical switch 30 includes a switch fixing portion 31 and a switch movable portion 32, and the movable range of the switch movable portion 32 is the stopper 3.
It is regulated by 3a and 33b. Further, an electromagnet 34 for switching to the standby optical transmission line 29 side is provided above the switch movable portion 32, and an electromagnet 35 for switching to the normal optical transmission line 28 side is disposed below the electromagnets 34, 35.
The switch movable portion 32 is displaced upward or downward by driving the switch. That is, the switch movable unit 32 is
When power is supplied to the upper electromagnet 34, it is displaced upward due to its attractive force and comes into contact with the stopper 33a to stop. Further, when power is supplied to the lower electromagnet 35, the switch movable portion 32 moves downward due to its attractive force, contacts the stopper 33b, and stops.

A transmission control unit side fiber 36 connected to the transmission control unit 1 is provided in the switch movable unit 32. On the other hand, the switch fixing unit 31 has a regular optical transmission line fiber 37 connected to the optical switch unit 24 of the regular optical transmission line 28 and a standby optical transmission line fiber 38 connected to the optical switch unit 25 of the standby optical transmission line 29. Are provided above and below with a predetermined interval. That is, the switch movable portion 3
By displacing 2 upward or downward, the transmission control unit side fiber 36 is arranged to face the standby optical transmission line fiber 38 or the regular transmission line fiber 37.

FIG. 3 shows the transmission control unit 1 to the electromagnet 3 below.
5 shows a state in which power is supplied to 5 and the switch movable part 32 is displaced downward, and the transmission control unit side fiber 36 faces the regular transmission path side fiber 37. Therefore, in this state, the transmission control unit 1 is switched and connected to the regular optical transmission line 28 side.

In the state shown in FIG. 3, when power is supplied from the transmission control section 1 to the upper electromagnet 34, the switch movable section 32 is displaced upward due to its attractive force and comes into contact with the stopper 33a to stop. . Therefore, in this state, the fiber 36 on the transmission control side is connected to the fiber 38 on the standby optical transmission line side.
, The transmission control unit 1 is switched to the standby optical transmission line 29 side.

Next, the overall operation of the above embodiment will be described.
Normally, the transmission line switching unit 21 is switched to the regular optical transmission line 28 side by a command from the transmission control unit 1, and the transmission control unit 1 uses the regular optical transmission line 28 to transmit information. ing.

When the transmission control unit 1 stops its function including power supply due to its own hardware failure, the failure is detected by self-diagnosis or the like, and the power supply to the optical switch units 24 and 25 is forced. When stopped, the optical switch unit 24 in the normal optical transmission line 28 is used by using it as in the conventional case.
Optical switch is connected to the bypass side. The bypass control unit 22 of the transmission path switching unit 21 is interposed between the transmission control unit 1 and the optical switch.
Distributes the power supply from the transmission control unit 1, and the control is the same as directly connecting the transmission control unit 1 and the optical switch.

When a failure such as disconnection of the regular optical transmission line 28 occurs, the transmission line is reconfigured by loopback in the transmission control unit 1 as described with reference to FIG. That is, normally, the optical signal is transmitted only by using the conventional optical fiber 10. When an optical signal is no longer transmitted in the optical transmission line 2 due to a disconnection or the like, the transmission control unit 1 at both ends of the fault location detects the fault and the transmission control unit 1
The optical fiber 11 of the loopback system is used for loopback to reconfigure the regular optical transmission line 28.

In addition, when a failure occurs in two places in the service optical transmission line 28 and the normal transmission control unit 1 sandwiched between the failure points is disconnected from the service optical transmission line 28, the transmission control unit 1 concerned.
And the other transmission control unit 1 performs the following control.

(1) When an optical signal cannot be received from the optical fiber of the transmission line being used, the transmission control unit 1 judges that the transmission line is faulty and supplies a power source for switching the transmission line to the transmission line switching unit. 21 to the optical path switching optical switch 30. That is, when the transmission control unit 1 is disconnected from the transmission line while using the regular optical transmission line 28, the excitation power is supplied to the electromagnet 34 of the transmission line conversion optical switch 30 shown in FIG. From the common optical transmission line 28 to the standby optical transmission line 2
Switch to 9.

(2) A transmission control unit 1 other than the transmission control unit 1 of the above (1) in which information transmission is recovered by loopback.
Then, since the message from the transmission control unit 1 of (1) is not sent, it is determined that the transmission control unit 1 of (1) is disconnected from the current transmission line, and the transmission line conversion optical switch 30 The power supply for excitation is supplied to the electromagnet 34 to convert the used transmission line from the regular optical transmission line 28 to the standby optical transmission line 29.

When the message is not transmitted due to the failure of the transmission control unit 1 of the above (1), it is bypassed by the optical switch units 24 and 25 from any of the transmission lines, and the other It does not affect the signal transmission of the transmission control unit 1.

The normal transmission control unit 1 as described above is
All can be switched from the regular optical transmission line 28 to the standby optical transmission line 29, and information can be transmitted using this standby optical transmission line 29. Then, the failure of the regular optical transmission line 28 is restored while the information is transmitted using the standby optical transmission line 29.

If a failure occurs in the transmission controller 1 or the standby optical transmission line 29 while the standby optical transmission line 29 is being used, the optical transmission is performed in the same manner as the case of the regular optical transmission line 28. Bypass control of the optical switch in the switch section 25 and switching control to the regular optical transmission line 28 side are performed.

Transmission line switching unit 21 and optical switch units 24, 2
The connection with 5 is the same as that of the transmission control unit 1 of the conventional optical local area network, both optical and electrical.
Since the optical connection between the transmission path switching unit 21 and the transmission control unit 1 is the same as that of the conventional optical switch unit 3, the bypass function and the transmission line by the optical switches 24 and 25 when the transmission control unit 1 fails. The loopback function by the transmission control unit 1 when a failure occurs in one of the above can be realized by the same technique as the conventional one.

[0032]

As described in detail above, according to the present invention, it is possible to realize bypass when a failure occurs in the transmission path control unit and loopback when a failure occurs at one location of the transmission path, and It is possible to realize an optical local area network having resilience and reliability against failures, having a function of reconstructing information transmission by switching transmission paths in the event of occurrence of failure in the transmission path at more than one place.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an optical local area network according to an embodiment of the present invention.

FIG. 2 is a configuration diagram of a transmission path switching unit in the embodiment.

FIG. 3 is a configuration diagram of a transmission line conversion optical switch according to the same embodiment.

FIG. 4 is a block diagram of a conventional optical local area network.

5 is a configuration diagram of an optical switch unit in FIG.

6 is a configuration diagram of the optical switch in FIG.

FIG. 7 is an explanatory diagram of a loopback function when a transmission line failure occurs in a conventional optical local area network.

FIG. 8 is an explanatory view when a failure occurs at two transmission lines in the conventional optical local area network.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Transmission control part 10 Normal use optical fiber 11 Loopback type optical fiber 21 Transmission line switching part 22 Bypass control part 24 Regular optical transmission line side optical switch part 25 Standby optical transmission line side optical switch part 28 Regular optical transmission line 29 Standby optical transmission line 30 Transmission line conversion optical switch 31 Switch fixed part 32 Switch movable part 33a, 33b Stopper 34, 35 Electromagnet

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification number Office reference number FI technical display location H04L 12/437 H04L 11/00 331

Claims (1)

[Claims] 1. An information transmission source is connected to convert information from the information supply source into an optical signal, or convert the optical signal into a signal to the information supply source, and transmit information between the information supply sources. A transmission control unit for controlling the optical transmission line, and two optical transmission lines for normal use and standby, which form a set of two types of transmission lines for normal use and loopback for transmitting an optical signal between the transmission control units, and the transmission control And a transmission line switching unit that switches the connection of the transmission control unit to the optical transmission line of the other system when a failure occurs in the optical transmission line of one system, and connects to this transmission line switching unit, and And a plurality of optical switch units that are respectively connected to the optical transmission lines of the two systems and that, when a failure occurs in the transmission control unit, disconnect the transmission control unit having the failure from the optical transmission line. Characteristic optical local area network.