FR2775357A1 - Optical path switching monitoring system for wavelength multiplexing light transmission system optical path switching of signal light, monitoring light - Google Patents

Abstract

An optical switch (101) simultaneously switches the optical paths of signal light and monitoring light. Optical receiver (104) detects monitoring light output based on which switch control monitoring unit (106) monitors optical path switching operation.DETAILED DESCRIPTION - An INDEPENDENT CLAIM is also included for monitoring procedure of optical path switching

Description

SWITCHING MONITORING SYSTEM AND METHOD
OPTICAL PATH
BACKGROUND OF THE INVENTION 1. Field of the Invention
The present invention relates to an optical communication system and, in particular, to a method and a system for monitoring optical path switching.

2. Description of the related art
In recent years, a wavelength division multiplex transmission system has been the subject of intense research and has been developed due to the wider bandwidth of fiber optic amplifiers. In the wavelength division multiplex transmission system, the wavelength division multiplex transmission light is directly subjected to optical amplification and the transmission distance is extended by online amplification repeaters. In particular, the technique of optical addition / removal (insertion / connection) necessary to form a flexible network attracts attention. Various optical ADM (add / remove multiplexer) systems have been proposed.

 Typically, an optical ADM system is provided with an optical switch for each wavelength.

When the optical switch is open, an input light signal of a predetermined wavelength is output as is. When the optical switch is closed, the input light signal is removed and then a new light signal of the same wavelength is added. Therefore, whether the optical switch for performing the optical add / remove operation is closed or open, the wavelength of the output light is the same as that of the input light. It is therefore difficult to determine whether these optical switches are functioning properly. Therefore, monitoring of optical switches is considered important.

As an example of an optical matrix switch monitoring system, a spatial distribution optical matrix switch having a failure monitoring function is presented in the
Japanese Patent Application Put in Public Inspection N "64-59220. In the example of the prior art, the surveillance light is divided into two parts.

One part is used as reference light and the other part is passed through the entire matrix optical switch with spatial distribution and output from a monitoring output terminal. By comparing the monitoring output light with the reference light, failure monitoring or the like can be performed in the matrix switch.

 However, the prior art monitoring method described above attempts to detect a failure by letting the monitoring light flow through the spatial distribution matrix switch. It is not intended to determine whether the light signal is really switched correctly by the respective optical switches.

Regardless of whether ADD / REMOVE is performed, the wavelength of the input light is the same as that of the output light in the optical ADM system as described above. It is therefore extremely difficult to really determine whether the respective switches are switched normally.

SUMMARY OF THE INVENTION
It is an object of the present invention to provide a monitoring system and method capable of monitoring the optical path switching operation reliably.

 Another object of the present invention is to provide a monitoring system and method capable of monitoring the optical path of the light signal reliably without affecting the light signal in the optical ADM system.

 According to the present invention, an optical switch switches between first and second path states in accordance with a switch control signal, wherein a first light having a first wavelength passes through an optical path and a second light having a second wavelength passes through another optical path. The optical path switching of the optical switch is monitored by detecting the second light which has come out of the optical switch in accordance with the switch control signal.

 Since the optical path switching of the first light can be monitored by detecting the optical path switching of the second light which is performed in synchronization with the optical path switching of the first light, the optical path switching of the optical switch can be reliably monitored.

BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a block diagram showing an embodiment of an optical switch monitoring system according to the present invention
Fig. 2A is a diagram showing a connection state at a time when an optical switch 101 is in the open state
Figure 2B is a diagram showing a connection state at a time when an optical switch 101 is in the closed state
FIG. 3 is a diagram for describing an optical path at a time when the optical switch is in the open state in the present embodiment
FIG. 4 is a diagram for describing an optical path at a time when the optical switch is in the closed state in the present embodiment; and
Figure 5 is a block diagram showing another embodiment of a monitoring system according to the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to Figure 1, an optical switch 101 has four input terminals IP1-IP4 and four output terminals OP1-OP4 and is selectively positioned in an open state (normal state) and in a closed state in accordance to a switch control signal. As described later, when the optical switch 101 is in the open state, the input terminals IP1 and IP4 are, respectively, optically connected to the output terminals OP1 and OP4, an input terminal IP2 is connected so optically to an output terminal OP3 and an input terminal IP3 is, respectively, optically connected to an output terminal OP2. On the other hand, when the optical switch 101 is in the closed state, the input terminal IP1 is optically connected to the output terminal OP4, the input terminal IP4 is optically connected to the output terminal OP1 output and the IP2 and IP3 input terminals are, respectively, optically connected to the OP2 and OP3 output terminals.

At the input terminal IP1 of the optical switch 101, an input light signal having a predetermined wavelength X1 is input. At the input terminal IP3, a surveillance light is input from a surveillance light source 102. At the input terminal IP4, an add light signal having the wavelength Xl is input at from an optical transmitter 103. On the other hand, from the output terminal OP1 of the optical switch 101, either the input light signal or the addition light signal delivered by the optical transmitter 103 is output. At the exit terminal
OP2, a monitoring light receiver 104 is connected. At the output terminal OP4, an optical receiver 105 is connected. In this case, the input terminal IP2 and the output terminal OP3 of the optical switch 101 are not used.

 The switching operation of the optical switch 101 is performed in accordance with the switch control signal supplied by a switch control and monitoring section 106. In addition, the switch control and monitoring section 106 determines whether the switching of the switch Optical 101 was performed normally by monitoring an output signal from the monitoring light receiver 104.

 In the normal state, in which an optical add / remove operation is not performed, the optical switch 101 is set to the open state and the input light signal is transferred as it is as a light signal. exit. At the same time, a surveillance light is entered into the surveillance light receiver 104. If the optical add / remove operation is to be performed, then the optical switch 101 is set to the closed state and then a station 107 receives a withdrawal signal from the optical receiver 105 and outputs a new addition signal to the optical transmitter 103. Hereinafter, the operation of the present embodiment will be described in detail.

 As shown in FIG. 2A, when the optical switch 101 is in the open state, the input terminals IP1 and IP4 are, respectively, optically connected to the output terminals OP1 and OP4, the input terminal IP2 is optically connected to the output terminal OP3 and the input terminal IP3 is, respectively, optically connected to the output terminal OP2. An input light signal, entered into the input terminal IP1, therefore appears at the output terminal OP1 as it is and is output.

 In addition, the surveillance light from the surveillance light source 102, entered into the input terminal IP3, appears at the output terminal OP2 and is entered into the surveillance light receiver 104. If it is assumed that the monitoring light receiver 104 outputs a voltage depending on the intensity of the incident light, the switch control and monitoring section 106 can know that the optical switch 101 is in the normal open state by monitoring the output voltage of the surveillance light receiver 104. In other words, in the case where the switch control and monitoring section 106 has positioned the optical switch 101 in the open state, it is possible to judge whether the optical switch 101 has established the path optical normally, provided that the output voltage of the monitoring light receiver 104, at this instant, is at the same voltage level indicating the open state.

As shown in Fig. 2B, when the optical switch 101 is in the closed state, the input terminal IP1 is optically connected to the output terminal OP4, the input terminal IP4 is, respectively, connected optically to the output terminal OP1 and the input terminals IP2 and IP3 are, respectively, optically connected to the output terminals OP2 and OP3. The input light signal having the wavelength k1, entered in the input terminal IP1, therefore appears at the output terminal
OP4 and entered the optical receiver 105.

In other words, the input light signal is converted into an electrical signal and the electrical input signal is output to the station 107. Conversely, a transmission signal output from the station 107 is converted into a light signal having the length d wave B1 by the optical transmitter 103 and the light signal is entered at the input terminal IP4 of the optical switch 101 as an add light signal. This addition light signal appears at the output terminal OP4 and is output as an output signal.

 At the same time, the surveillance light entered into the IP3 input terminal does not appear at the OP2 output terminal, but appears at the OP3 output terminal. The monitoring light is therefore not entered into the monitoring light receiver 104. As a result, the output voltage of the monitoring light receiver 104 decreases. As a result, the switch control and monitoring section 106 can know whether the optical switch 101 is correctly in the closed state. In other words, after switching the optical switch 101 to the closed state, the switch control and monitoring section 106 can judge whether the optical switch 101 has switched its optical path normally, provided that the output voltage of the light receiver monitoring 104, at this instant, ie at the same voltage level indicating the closed state.

 In addition, the wavelength of the monitoring light is selected so as not to coincide with the wavelength of the input light signal. In particular, it is desirable to provide an optical bandpass filter to allow only the wavelength band of the surveillance light to pass through the input stage of the surveillance light receiver 104.

 Hereinafter, this will be described more concretely with reference to Figures 3 and 4. Figure 3 shows an optical path at the time when the optical switch is in the open state and Figure 4 shows an optical path at the time at which the optical switch is in the closed state. As shown in Figures 3 and 4, an example of the optical switch 101 used in this embodiment is composed of four 2 x 2 matrix optical switches 201 to 204 and the monitoring light receiver 104 is composed of a pass filter -optical strip 205 and an optical receiver 206.

 In the optical switch 101, an upper input terminal of the matrix optical switch 201 is optically connected to the input terminal IP1 of the optical switch 101 and a lower input terminal of the matrix optical switch 201 is optically connected to the input terminal IP2 of the optical switch 101. Likewise, an upper input terminal of the matrix optical switch 202 is optically connected to the input terminal IP3 of the optical switch 101 and an input terminal of the optical matrix switch 202 is optically connected to the input terminal IP4 of the optical switch 101.

 In addition, an upper input terminal of the optical matrix switch 203 is optically connected to an upper output terminal of the optical matrix switch 201 and a lower input terminal of the optical matrix switch 203 is optically connected to a terminal output switch of the matrix optical switch 202. An upper input terminal of the matrix optical switch 204 is optically connected to a lower output terminal of the matrix optical switch 201 and a lower input terminal of the matrix optical switch 204 is connected optically to a lower output terminal of the matrix optical switch 202.

 An upper output terminal of the matrix optical switch 203 is optically connected to the output terminal OP1 of the optical switch 101 and a lower output terminal of the optical matrix switch 203 is, respectively, optically connected to the output terminal OP2 of the optical switch 101. Likewise, an upper output terminal of the optical matrix switch 204 is optically connected to the output terminal OP3 of the optical switch 101 and a lower output terminal of the optical matrix switch 204 is, respectively, optically connected to the output terminal OP4 of the optical switch 101.

 These 2 x 2 matrix optical switches 201 to 204 are positioned in the same connection state in accordance with the switch control signal. More specifically, when the optical switch 101 is in the open state, each of the matrix optical switches 201 to 204 is in a bar state in which the upper input terminal is optically connected to the upper output terminal and the lower input terminal is optically connected to the lower output terminal, as shown in Figure 3. As a result, the input light signal, entered into the input terminal IP1, appears at the output terminal OP1 via the optical matrix switches 201 and 203. The monitoring light, entered into the IP3 input terminal, appears at the output terminal OP2 via the optical matrix switches 201 and 203. The monitoring light output from the output terminal OP2 is input to the optical receiver 206 via the optical bandpass filter 204 and is output to the switch control and monitoring section 106 as a detection signal surveillance light having a high output voltage level.

 On the other hand, when the optical switch 101 is in the closed state, each of the matrix optical switches 201 to 204 is in a cross state in which the upper input terminal is optically connected to the output terminal lower and the lower input terminal is, respectively, optically connected to the upper output terminal, as shown in Figure 4. As a result, the input light signal, entered at the input terminal IP1, appears to the output terminal OP4 via the matrix optical switches 201 to 204 as a withdrawal light signal. The addition light signal, entered at the input terminal IP4, appears at the output terminal OP1 via the matrix optical switches 202 and 203.

 In addition, the surveillance light, input to the input terminal IP3, appears at the output terminal OP3 via the matrix optical switches 202 and 204.

Since the monitoring light has not left the output terminal OP2, the light intensity entered into the optical receiver 206, via the optical bandpass filter 205, becomes extremely low. As a result, the monitoring light detection signal having a low voltage level is output to the switch control and monitoring section 106.

 By thereby detecting the high / low voltage level of the monitoring light detection signal, the switch control and monitoring section 106 can monitor the switching state of the optical switch 101 with certainty.

 FIG. 5 shows an example of application of the present invention to a transmission system with wavelength multiplexing in which a plurality of wavelengths (Xl to k5) are multiplexed.

 A fiber optic transmission line 301 is connected to an input terminal of an optical demultiplexer 302. The output terminals corresponding respectively to the plurality of wavelengths (X1 to k5) are, respectively, connected to five terminals corresponding input of an optical multiplexer 303 via five optical switches SW1 to SW5. An output terminal of the optical multiplexer 303 is connected to a transmission line by optical fibers 304. Each of the optical switches SW1 to SW5 corresponds to the optical switch 101 described above and has the same configuration and function as those of the optical switch 101.

Demultiplexed input optical signals (each having a different wavelength among the wavelengths Xî to k5) are respectively input into the input terminals IP1 of the optical switches
SW1 to SW5. Respective output terminals OP1 of the optical switches SW1 to SW5, output light signals, each having the same wavelength as the input light signal, are respectively output to the input terminals of the optical multiplexer 303.

A monitoring light is generated by an optical path monitoring transmitter 305 and is output to the respective input terminals IP3 of the optical switches SW1 to SW5. The wavelength of the monitoring light is selected so as not to coincide with any of the wavelengths R1 to X5 of the light signal. At the respective input terminals
IP4 of the optical switches SW1 to SW5, the respective addition light signals having corresponding wavelengths are respectively input from optical transmitters for the addition light signal, TADD1 to TAUDS. Each of the optical transmitters TADD1 to TADD5 corresponds to the optical transmitter 103, as shown in FIG. 1.

 In addition, optical receivers for optical path monitoring, Rsl to Rs5 r are, respectively, connected to the output terminals OP2 of the optical switches SW1 to SW5. Each of the optical receivers Rs1 to Rs5 corresponds to the surveillance light receiver 104, as shown in FIG. 1.

Finally, at the respective output terminals OP2 of the optical switches SW1 to SW5, optical receivers for the withdrawal light signal, RDROP1 to RDROP5, r are, respectively, connected. Each of the RDROP1 to RDROPS optical receivers corresponds to the optical receiver 105, as shown in FIG. 1.

 In such an optical ADM system, the switch control and monitoring section 106 can determine with certainty whether the respective optical switches normally perform switching operations by detecting a change in the voltage level, up / down, of each of the signals. for detecting surveillance light input from the optical receivers Rsi to Rus5.

 In the case where pumping light, having a wavelength of 1480 nm or 980 nm for pumping a fiber optic amplifier, is also used as monitoring light, it becomes unnecessary to provide the monitoring light source 102 or the optical transmitter 305.

 As described above, according to the present invention, the optical path of the monitoring light is switched in synchronization with the switching of the optical path of the light signal. Therefore, by detecting the switching of the optical path of the monitoring light, the switching of the optical path of the light signal can be monitored with high reliability without affecting the light signal.

 Of course, the invention is not limited to the embodiments described above and shown, from which we can provide other modes and other embodiments, without departing from the bounds of the invention.

Claims (16)

 1. System for monitoring optical path switching in an optical transmission system, characterized in that it comprises  an optical switch (101) for switching between first and second optical path states in accordance with a switch control signal, wherein a first light having a first wavelength passes through an optical path and a second light having a second wavelength passes through another optical path; and  a monitoring device for monitoring the optical path switching of the optical switch (101) by detecting the second light which is output from the optical switch (101) in accordance with the switch control signal.  2. System according to claim 1, characterized in that the second light is output from the optical switch (101) when the optical switch (101) is in the first optical path state and is not output when the optical switch (101 ) is in the second optical path state.  3. System according to claim 1, characterized in that the optical switch (101) has a first input terminal (IP1), a first output terminal (OP1) and a second output terminal (OP2), in which the second light is received at the first input terminal (IP1) and is output from a terminal selected from the first and second output terminals according to the switch control signal.  4. System according to claim 3, characterized in that the monitoring device comprises  an optical receiver (105) optically connected to a predetermined output terminal among the first and second output terminals, for receiving the second light to produce a light detection signal; and  a monitor controller for determining whether the optical path switching of the optical switch (101) is performed normally, based on the light detection signal.  5. System according to claim 1, characterized in that the optical switch (101) has first to fourth input terminals (IP1 to IP4) and first to fourth output terminals (OP1 to OP4), in which  when the optical switch (101) is in the first optical path state, the first and fourth input terminals (IP1, IP4) are, respectively, optically connected to the first and fourth output terminals (OP1, OP4) and the second and third input terminals (IP2, IP3) are, respectively, optically connected to the third and second output terminals (OP, OP2); and  when the optical switch (101) is in the second optical path state, the first and fourth input terminals (IP1, IP4) are, respectively, optically connected to the fourth and first output terminals (OP4, OP1) and the second and third input terminals are, respectively, optically connected to the second and third output terminals (OP2, OP3).  6. System according to claim 5, characterized in that the second light is received at the third input terminal (IP3) and is output from an output terminal selected from the second and third output terminals (OP2, OP3) based on the switch control signal.  7. System according to claim 6, characterized in that the monitoring device comprises  an optical receiver (105) optically connected to the second output terminal (OP2) for receiving the second light to produce a light detection signal; and  a monitor controller for determining whether the optical path switching of the optical switch (101) is performed normally, based on the light detection signal.  8. System according to claim 1, characterized in that the optical switch (101) comprises  a first switch for switching an optical path for the first light in accordance with the switch control signal; and  a second switch for switching an optical path for the second light in synchronization with the first switch in accordance with the switch control signal.  9. System according to claim 1, characterized in that the optical switch (101) comprises a plurality of 2 x 2 matrix optical switches.  10. System for monitoring the optical path switching in an optical add / remove circuit for a first light having a first wavelength (ho), characterized in that it comprises  a light source (102) for producing a second light having a second wavelength (k2) different from the first wavelength (hl);  an optical switch (101) for switching between an open add / remove state and a closed add / remove state in accordance with an add / remove control signal, wherein the first light passes through an optical path and the second light goes through another optical path  a detector for detecting the second light which is output from the optical switch (101) in accordance with the add / remove control signal to produce a light detection signal; and  a monitor for monitoring the optical path switching of the optical switch (101) based on the light detection signal.  11. System according to claim 10, characterized in that the optical switch (101) has an input terminal (IP1) where the second light is entered and two output terminals, in which the second light is output from a terminal output selected from the output terminals in accordance with the add / remove control signal and the detector is optically connected to a predetermined output terminal among the output terminals.  12. System according to claim 11, characterized in that the second light is output from one of the output terminals when the optical switch (101) is in the open add / remove state and the second light is output from the other of the output terminals in the closed add / remove state.  13. System according to claim 10, characterized in that the monitoring device also controls the optical switch (101) in order to monitor the switching of the optical path by comparing the add / remove command signal with the signal of detection of light received from the detector.  14. Method for monitoring optical path switching in an optical transmission system, characterized in that it comprises the steps consisting in:  causing an optical switch (101) to switch between first and second optical path states in accordance with a switch control signal, wherein a first light having a first wavelength passes through an optical path and a second light having a second wavelength passes through another optical path; and  monitoring the optical path switching of the optical switch (101) by detecting the second light which is output from the optical switch (101) in accordance with the switch control signal.  15. The method of claim 14, characterized in that the second light is output from the optical switch when the optical switch (101) is in the first optical path state and is not output when the optical switch (101) is in the second optical path state.  16. Method according to claim 14, characterized in that the optical switch has a first input terminal (IP1), a first output terminal (OP1) and a second output terminal (OP2), in which the second light is received at the first input terminal (IP1) and is output from an output terminal selected from the first and second output terminals according to the switch control signal.