DE4433031A1 - Switched changeover between optical data transmission lines - Google Patents

Abstract

An optical fibre data transmission system has a bidirectional facility in which a number of lines (9,10,11 and 12,13,14) can be selectively connected between transmitters (5,7) and receivers (6,8). The transmitters and receivers selectively access the lines with the aid of optical switches (1-4) operated by control units (17,18). The latter detect any faults, e.g. line faults, and an alarm is signalled. Simultaneously, change-over between lines used for transmitting data is initiated.

Description

State of the art

The invention is based on a method for switching an optical data transmission line of the type of the main claim. It is already with Wu, "Strategies and Technologies for planning a cost effective survivable fiber Network Architecture Using Optical Switches ", Journal of Lightwave Technology, Vol. 8, No. 2, Feb. 1990, a Process for switching an optical Data transmission line described, two Transmission stations via a first optical Data transmission line are interconnected. In addition to the first optical data transmission line is a second optical data transmission line between arranged the transmission stations. The Transmission stations can each have an optical Switch from the first optical data transmission line switch to the second optical data transmission line. Each transmission station has a control unit, which monitors the receipt of the data. Recognize one Control unit an interruption of data transmission that  the control unit generates a predetermined time an alarm control signal sent to the second Transfer station is transmitted. The second The transmission station evaluates the alarm control signal and in turn sends an alarm control signal to the first Transmission station. In this way, information exchanged about the failure of the data transmission and the Transfer stations are on the second Data transmission line switched.

Advantages of the invention

The inventive method with the features of Claims 1 and 2 have the advantage that not special alarm control signals generated, evaluated and need to be transferred, but by a simple Switching method a switch to the second optical Data transmission line is carried out. With that the Transfer station cheaper because of the control unit generate, evaluate and no special alarm control signal must send. Because the switching process is simple safe functioning is guaranteed.

By the measures listed in the subclaims advantageous developments and improvements in Claim 1 and 2 specified switching method possible.

It is particularly advantageous to switch the transmitter before switching on the second optical data transmission line turn off and after switching to the second optical Data transmission line to switch the transmitter on again. This means that the time in which a sender receives data about a sends an interrupted optical data transmission line,  minimized. The security to operate optical This increases data transmission lines.

When using an optical coupler on the Receiver side or the transmitter side of the optical Data transmission line eliminates the need to Receiver side or the transmitter side with each switch. This simplifies the process and the Tax expense is lower, making a higher one Reliability is achieved.

drawing

An embodiment of the invention is in the drawing shown and in the following description explained. Show it

Fig. 1 shows an optical data transmission path with two transfer stations,

Fig. 2 an optical coupler,

Fig. 3 is a bidirectional data transmission and

Fig. 4 shows a schematic program flow.

Fig. 1 shows a first transfer station 15 having a first control unit 17, which is connected via a first control line 25 with a first transmitter 5. The first control unit 17 is also connected to the first receiver 6 by a first data line 26 . The first transmitter 5 is coupled to a first optical switch 1 . The first optical switch 1 is connected to a first, a second and a third optical data transmission line 9 , 10 , 11 . The first optical switch 1 switches through the first or the second or the third optical data transmission line 9 , 10 , 11 to the first transmitter 5 .

The first, second and third optical data transmission lines 9 , 10 , 11 are routed to a second transmission station 16 . The second transmission station 16 has a second optical switch 2 , which is connected to the first, second and third optical data transmission lines 9 , 10 , 11 . The second optical switch 2 switches through either the first or the second or the third optical data transmission line 9 , 10 , 11 to a second receiver 8 . The second receiver 8 is connected to a second control unit 18 via a second data line 27 . The second control unit 18 is connected to a second transmitter 7 via a second control line 28 . The second transmitter 7 is guided to a third optical switch 3 . The third optical switch 3 is connected to fourth, fifth and sixth optical data transmission lines 12 , 13 , 14 . Depending on the position of the optical switch 3 , the second transmitter 7 is connected to the fourth or fifth or sixth optical data transmission line 12 , 13 , 14 . The fourth, fifth and sixth optical data transmission lines 12 , 13 , 14 are led to a fourth optical switch 4 . Depending on the switch position, the fourth optical switch 4 connects the fourth or the fifth or the sixth optical data transmission line 12 , 13 , 14 to the first receiver 6 . The first control unit 17 is connected to the first optical switch 1 via a third control line 29 . Furthermore, the first control unit 17 is connected to the fourth optical switch 4 via a fourth control line 30 .

The second control unit 18 is connected to the second optical switch 2 via a fifth control line 31 . In addition, the second control unit 18 is connected to the third optical switch 3 via a sixth control line 32 .

The first and second control units 17 , 18 consist, for example, of a microprocessor with a memory and the corresponding control programs. The first transmitter 5 and the second transmitter 7 are represented, for example, by laser diodes. The first receiver 6 and the second receiver 8 are preferably designed as photodiodes. The optical data transmission lines 9 , 10 , 11 , 12 , 13 , 14 are designed, for example, as fibers, in particular as glass fibers. The number of optical data transmission lines to be used must be adapted to the corresponding case and is not limited to the number described.

Fig. 2 shows a second receiver 8 which via an optical coupler 33 with the first, second and third optical data transmission lines 9, 10, 11 is connected. The optical coupler 33 is designed such that the first, the second and the third optical data transmission lines 9 , 10 , 11 are routed together to the second receiver 8 . Analogously, the first receiver 6 can be connected to the fourth, fifth and sixth optical data transmission lines 12 , 13 , 14 in this way. If the first and second receivers 6, 8 are coupled to the optical data transmission lines with couplers, there is no need to switch over the first and second receivers 6 , 8 . Accordingly, an optical coupler 33 can advantageously be used on the transmitter side if an optical switch is arranged on the receiver side.

As optical switches z. B. thermo-optical switches, preferably thermo-optical switches based on polymers, electro-optical switches or mechanical fiber switches be used.

FIG. 3 shows the first transmission station 15 , which is constructed in accordance with FIG. 1, but the fourth optical switch 4 and the fourth control line 30 are not arranged. The first transmitter 5 and the first receiver 6 are not shown explicitly for the sake of clarity. The first transmitter 5 and the first receiver 6 of the first transmission station 15 are connected to the second receiver 8 and the second transmitter 7 of the second transmission station 16 by means of the first optical switch 1 via the first optical data transmission line 9 and via the second optical switch 2 . The bidirectional data exchange takes place e.g. B. over a time division multiplex method or over different wavelengths for the different transmission directions. The second transmission station 16 is constructed according to FIG. 1, but the third optical switch 3 and the third control line 32 are omitted. Switching from the first optical data transmission line 9 to the second optical data transmission line 10 takes place via the first and second optical switches 1 , 2 .

In this example, data is transmitted in both directions via the first optical data transmission line 9 . As a replacement line, the second optical data transmission line 10 is arranged between the first and the second transmission station 15 , 16 , to which it is switched if the first optical data transmission line is interrupted.

FIG. 4 shows a schematic program sequence for switching the optical data transmission lines between two transmission stations corresponding to FIG. 1. At program point 40 , data is transmitted from the first transmission station 15 to the second transmission station 16 . The first transmitter 5 sends data to the second receiver 8 via the first optical data transmission line 9 . The first optical switch 1 and the second optical switch 2 are controlled so that the first transmitter 5 and the second receiver 8 are connected to the first optical data transmission line 9 . The second and the third optical data transmission lines 10 , 11 are arranged as replacement lines, and when the first optical data transmission line 9 is interrupted, a switch is made to one of the replacement lines.

At the same time, the second transmission station 16 sends data to the first transmission station 15 . The second transmitter 7 sends data to the first receiver 6 via the fourth optical data transmission line 12 . The third and the fourth optical switch are controlled so that the second transmitter 7 and the first receiver 6 are connected to the fourth optical data transmission line 12 . The fifth and the sixth optical data transmission lines 13 , 14 are arranged as replacement lines, and when the fourth optical data transmission line 12 is interrupted, a switch is made to one of the replacement lines.

If, at program point 41, the second control unit 18 determines that no data has been received by the second receiver 8 for a defined period of time, the second control unit 18 switches the third optical switch 3 to the fifth optical data transmission line 13 . At the same time, the second control unit 18 switches the second optical switch 2 to the second optical data transmission line 10 .

At program point 42 , the first control unit 17 now recognizes that no data has been received by the first receiver 6 for a fixed period of time. This causes the first control unit 17 to switch the first optical switch 1 to the second optical data transmission line 10 . At the same time, the first control unit 17 switches the fourth optical switch 4 to the fifth optical data transmission line 13 .

A further embodiment of the switching method is that the first or the second control unit 17 , 18 immediately switches off the first or the second transmitter 5 , 7 upon detection of an interruption in the data transmission which lasts for a fixed period of time (automatic laser protection shutdown ALS) and then switches the optical switches 1, 2, 3, 4 to the second or fifth optical data transmission line 10 , 13 and then switches the first transmitter 5 and the second transmitter 7 on again.

If the transmitters are switched off before the switchover, optical couplers 33 can be used on the side of the receivers 8 , 6 instead of the optical switches 2 , 4 . The optical coupler 33 connects all the optical data transmission lines connected to the optical coupler 33 to the receiver connected to the optical coupler. This eliminates the need to switch receivers 6, 8 when using the optical coupler.

If it is not possible to receive data despite multiple switching of the transmitters 5 , 7 and the receivers 8 , 6 , the first control unit 17 and the second control unit 18 switch off the first transmitter 5 and the second transmitter 7 .

The switching method described is correspondingly to be applied to the bidirectional data transmission via an optical data transmission line in accordance with FIG. 3, wherein when the first or the second optical switch 1 , 2 is switched over, the receiver and the transmitter of the first or the second transmission station 15 , 16 of the first to the second optical data transmission line 9 , 10 are switched.

One of the two switches 1, 2 in FIG. 3 can be replaced by a coupler 33 . In the arrangement according to FIG. 3, program steps 41 and 42 take place simultaneously and independently of one another. This procedure also works without switching off the transmitter (ALS) and is particularly simple and reliable.

Claims (5)

1. A method for switching an optical data transmission line ( 9 ) to a replacement line ( 10 ), two transmission stations ( 15 , 16 ) for bidirectional data exchange via the optical data transmission line ( 9 ) being connected to one another and at least one replacement line ( 10 ) between the two transmission stations ( 15 , 16 ) is arranged, the first transmission station ( 15 ) having a first transmitter ( 5 ), a first receiver ( 8 ) and a first control unit ( 17 ) and the second transmission station ( 16 ) having a second transmitter ( 7 ), a second receiver ( 8 ) and a second control unit ( 18 ) and the first transmitter ( 5 ) and the first receiver ( 6 ) have a first optical switch ( 1 ) and the second transmitter ( 7 ) and the second receiver ( 8 ) are connected to the optical data transmission line ( 9 ) via a second optical switch ( 2 ) and with the aid of the first or the second opti The switch ( 1 , 2 ) can be connected to the replacement line ( 10 ), the reception of the data being monitored by each control unit ( 17 , 18 ) and, upon detection of an interruption in data reception which exceeds a predetermined time period, by the first control unit ( 17 ) the first optical switch ( 1 ) or from the second control unit ( 18 ) the second optical switch ( 2 ) is immediately switched to the replacement line ( 10 ). 2. Method for switching an optical data transmission line ( 9 , 12 ) to a replacement line ( 10 , 13 ), wherein a first and a second transmission station ( 15 , 16 ) for data exchange for a first transmission direction via a first optical data transmission line ( 9 ) and for the second transmission direction is connected to one another via a fourth optical data transmission line ( 12 ) and at least one replacement line ( 10 , 13 ) is arranged for each transmission direction, the first transmission station ( 15 ) via a first transmitter ( 5 ) and a first receiver ( 6 ) and a first control unit ( 17 ), and the second transmission station ( 16 ) has a second transmitter ( 7 ), a second receiver ( 8 ) and a second control unit ( 18 ) and the first and second transmitters ( 5, 7 ) and the first and second receivers ( 6, 8 ) via an optical switch ( 1 , 2 , 3 , 4 ) with the first and with the fourth optical D, respectively Data transmission line ( 9 , 12 ) are connected and can be connected to the corresponding replacement line ( 10 , 11 , 13 , 14 ) using the optical switches ( 1 , 2 , 3 , 4 ), with the control units ( 17 , 18 ) receiving the data is monitored and by the first or by the second control unit ( 17 , 18 ) upon detection of an interruption in data reception which exceeds a predetermined period of time, the first or the second transmitter ( 5 , 7 ) and the first or the second receiver ( 6 , 8 ) can be switched to the corresponding replacement line ( 10 , 13 ). 3. The method according to claim 1, characterized in that the first or the second transmission station ( 15 , 16 ) via an optical coupler ( 33 ) with the first optical data transmission line ( 9 ) and with the replacement line ( 10 , 11 ) are connected simultaneously . 4. The method according to claim 2, characterized in that upon detection of the interruption of data reception, the first or second transmitter ( 5 , 7 ) is switched off, and that after switching to the corresponding replacement line ( 10 , 13 ) the first or the second transmitter ( 5 , 7 ) is switched on again. 5. The method according to claim 4, characterized in that the first and / or the second receiver ( 6, 8 ) via an optical coupler ( 33 ) with the first and the fourth optical data transmission line ( 9 , 12 ) and with the corresponding Spare line ( 10 , 11 , 13 , 14 ) are connected at the same time.