JP2004173309A - Terminal station equipment, and supervisory and control method, in wdm communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To avoid a signal error caused by fluctuation of light power on a WDM communication system. <P>SOLUTION: A light wavelength of WDM is transmitted to the downstream via a light wavelength demultiplexing apparatus 44, a monitor 31, an EDFA 22, a monitor 32, and a light wavelength multiplexing apparatus 45. In the light wavelength demultiplexing apparatus 44, a wavelength λs carrying a supervisory and control signal is demultiplexed and applied to a supervisory and control signal transmitting/receiving circuit 49. An AGC circuit 43 controls an amplifier 22 based upon an output 42 (upstream transmission power information) of the supervisory and control signal transmitting/receiving circuit 49, an output 27 (level of received signal, signal level before amplification) of the monitor 31, and an output 28 (level of transmitting signal, signal level after amplification) of the monitor 32, so that the circuit 43 fixes a gain of the optical amplifier 22. <P>COPYRIGHT: (C)2004,JPO

Description

  The present invention relates to a terminal device and a monitoring control method in a WDM communication system.

2. Description of the Related Art In recent optical transmission communication, optical transmission using WDM (Wavelength Division Multiplexing) technology is being put to practical use. FIG. 1 shows an example of the system configuration. (A) A simple case, (B) an ADM (Add Drop Multiplexer) is mixed, and (C) a ring configuration.
(A) In a simple case, the transmitting terminal 101 multiplexes (WDM) a transmission signal, transmits the multiplexed signal to an optical cable, and the relay devices 102 to 104 relay the signal, and transmit the signal to the receiving terminal 105. .
(B) When ADMs coexist, the ADMs 108 and 113 interconnect the (a) WDM communication system and the (b) WDM communication system. The ADM 108 branches or inserts a part of the signal from the transmitting terminal 106 to the ADM 113 and the signal from the ADM 113 to the receiving terminal 110. The ADM 113 branches or inserts a signal from the transmitting terminal 111 into the ADM 108 and a part of the signal from the ADM 108 into the receiving terminal 115. This enables mutual communication between the (a) WDM communication system and the (b) WDM communication system.
(C) In the case of adopting a ring configuration, the network is composed of nodes 116 to 119 to which terminal devices can be connected and ADMs 120, ADM121, ADM123 and 124 in a ring shape.

  Although the transmitting terminal device and the receiving terminal device are shown as the terminal devices, one terminal device may be a transmitting / receiving terminal device having the functions of the transmitting terminal device and the receiving terminal device. Good. FIG. 2 is a configuration example of a terminal device of a WDM communication system. The terminal station 119 performs WDM on a signal from a device 120 to 122 such as an SDH (Synchronous Digital Hierarchy) or SONET (Synchronous Optical NETwork) terminal multiplexing device, transmits the WDM signal to a transmission line 135, and transmits a signal on the transmission line 136 to a wavelength. Separate and transmit to devices 120-122. In the terminal station 119, the wavelengths λ1 to λn are wavelength-multiplexed by the transmission-side wavelength multiplexing device 125 via the variable optical attenuator 124, further amplified by the transmission-side multi-wavelength amplifier 127, and transmitted to the transmission transmission line 135. Is output. The WDM signal on the reception transmission line 136 is amplified by the reception-side multi-wavelength amplifier 133, separated into respective wavelengths by the reception-side wavelength separation device 131, and transmitted to the devices 120 to 122. The dispersion compensating fiber modules 126 and 134 are modules for compensating the dispersion of the optical cable, and the boosters 128 and 132 are booster units of the additional pumping light source. The analyzer 129 is a spectrum analyzer unit.

  FIG. 3 is a configuration example of a relay device without an ADM. The signal from the upstream is transmitted on the transmission line 152, amplified by the multi-wavelength amplifier 143, and transmitted downstream by the transmission line 153. Similarly, the signal transmitted by the transmission path 154 is amplified by the multi-wavelength amplifier 146 and transmitted downstream by the transmission path 155. A monitoring control device 151 is connected to the multi-wavelength amplifiers 143 and 146, and performs monitoring control of the WDM communication system.

  FIG. 4 is a configuration example of a relay device having an ADM. The signal from the upstream is transmitted on the transmission line 152, amplified by the multi-wavelength amplifier 159, the ADM 158, and the multi-wavelength amplifier 161, and transmitted downstream by the transmission line 153. Similarly, the signal transmitted by the transmission path 154 is amplified by the multi-wavelength amplifier 162, the ADM 158, and the multi-wavelength amplifier 160, and transmitted downstream by the transmission path 155. The wavelength λa of the transmission line 156 is added by the ADM 158, and the wavelength λd is extracted from the transmission line 157.

  FIG. 5 shows a configuration example of a (passive) ADM having no switch circuit. The wavelength-multiplexed signal on the transmission line 163 is wavelength-separated by the wavelength separation device 164. Among the separated wavelengths, the wavelength λd is extracted (DROP). Further, the wavelength λa is newly added to the wavelength multiplexing device 165 (ADD). Each wavelength including the wavelength λa is wavelength-multiplexed by the wavelength division multiplexer 165 and output to the transmission line 166.

  FIG. 6 shows a configuration example of an ADM provided with a switch circuit (active). The configuration is the same as that of FIG. 5 except that the wavelengths to be dropped are selected by using the optical gate switches 172 to 177. FIG. 7 shows a configuration example of the monitoring control device. The monitoring control signals of 1 to n channels are converted into electricity by the optical / electrical converter 183 via the transmission line 181. The received data is subjected to serial / parallel conversion by a serial / parallel conversion circuit 187 via a frame terminating unit 186 to obtain a supervisory control signal 193 for 1 to n channels. The monitoring control signals 194 of the 1 to n channels are converted into serial signals by a parallel / serial conversion circuit 189, a frame for synchronization is added by a frame generation unit 188, and the optical signals are transmitted through an electric / optical converter 184. Is transmitted through the transmission line 182.

  The received clock from the optical / electrical converter 183 is applied to the frame synchronization circuit 185, and the frame pulse from the frame synchronization circuit 185 is applied to the frame termination unit 186. Further, the reception clock from the optical / electrical converter 183 is also applied to the selector 192 on the transmission side. One of the reception clock from the optical / electrical converter 183, the output of the oscillator 191 or the reception clock 195 is selected by the selector 192 and applied to the pulse generation unit 190, and the output of the pulse generation unit 190 is converted into parallel / serial data. It is applied to the circuit 189 and the frame generator 188.

  FIG. 8 shows the WDM system in the simple case of FIG. 1A further simplified and expressed in terms of wavelength. The modulated plurality of wavelength lights ([lambda] 1 to [lambda] 4) are multiplexed and transmitted to one optical fiber 4 by the transmitting side terminal equipment 1. A relay device is provided in the optical fiber transmission line 4, and an optical amplifier (optical amplifier) 2 is provided therein. The optical amplifier 2 collectively amplifies a plurality of wavelength lights (λ1 to λ4) and transmits the amplified light to the terminal device 3 on the receiving side. The multiplexed signal is distributed and received for each wavelength (λ1 to λ4) in the terminal device 3 on the receiving side.

  However, since the multi-wavelength optical amplifier 2 amplifies light as it is, normally, the output level is controlled to be constant by ALC (Automatic Level Control: automatic level control). By the way, when .lambda.2 is cut off, there is an ALC, so that it operates to keep the whole output level constant, and the other wavelengths .lambda.1, .lambda.3 and .lambda.4 are amplified more strongly. As a result, the wavelengths λ1, λ3, λ4 are amplified more than necessary, and the interference between the respective wavelengths is strengthened, or the reception level in the receiver causes a sudden change, so that the transmission information is erroneously received. In particular, since the former interference between wavelengths occurs continuously, communication becomes difficult when the interference is severe.

  In order to solve such a problem in control using the ALC technology, the conventional technology includes a method of providing a monitor PD (Photo Diode: Photodiode) in an optical amplifier for each wavelength and detecting a break in the wavelength. is there. However, in this method, it is necessary to provide monitors for the number of wavelength multiplexes, so that it is necessary to provide monitors for the number of wavelength multiplexes at the final stage in the design stage in anticipation of future expansion. There is a problem that as the number increases, it becomes uneconomical.

  There is also a method of putting a monitoring signal for each wavelength. That is, frequency modulation different from signal modulation is applied to each wavelength, and a different frequency is assigned to each frequency for the frequency modulation. In an optical amplifier, there is also a method in which one PD is provided, all wavelengths are received by the PD, the applied frequency is decomposed by a filter, and a frequency modulation wave is demodulated to detect a break in each wavelength. Also in this case, there is a problem that the filter circuit must be designed in advance by assuming the number of accommodated wavelengths.

  Against this background, in WDM communication, a method using an optical monitoring line has been adopted as a gain control method of an optical amplifier. In other words, an optical wavelength for supervisory control is provided separately from the signal transmission line, a supervisory control signal is transmitted to this supervisory line, signal information inputted at that time is notified to each optical amplifier, and each optical amplifier receives this information. Is performed based on the gain.

  In this case, even if the number of optical wavelengths accommodated is changed during the operation, the information is notified to each optical amplifier by the monitoring line, and each optical amplifier receives a new optical wavelength based on the information. A transition can be made to the gain control state corresponding to the number. Further, if a certain wavelength is interrupted during operation, the terminal device on the transmitting side monitors it and detects the interruption. The terminal device notifies the optical amplifier of this fact via the monitoring line. Each optical amplifier performs gain control based on this information.

  Further, as shown in FIGS. 4 to 6, an optical ADM function utilizing optical wavelength selectivity can be provided to an optical amplifier, which is used in a ring network or the like. FIG. 9 shows an example in which an optical amplifier A15 obtained by adding an ADM function to an optical amplifier is inserted in a stage preceding the optical amplifier B16. The optical amplifier A15 pulls in a part of the wavelength 5 from the optical transmission line 17 (DROP) and further adds a new optical wavelength 6 (ADD). Therefore, the number of wavelengths in the optical amplifier B is the sum of the number of ADDs 6 in the optical amplifier A and the number of through wavelengths 7 of the transmission wavelength from the transmitting terminal equipment A.

By the way, in the related art in which the monitoring control signal of the optical amplifier is transmitted on the monitoring line to perform the gain control, there are the following problems.
(1) When the number of accommodated optical wavelengths is changed by extension, the information is notified to each optical amplifier via a monitoring line. Each optical amplifier makes a transition to a gain control state corresponding to the new number of accommodated optical wavelengths based on the information. However, at this time, if the added optical wavelength reaches the optical amplifier before the information indicating the addition is notified to each optical amplifier, the power of each optical wavelength decreases due to the influence of the ALC control. Although this period is instantaneous, it causes a burst error.
(2) If a certain wavelength is cut off, the transmitting-side terminal device notifies the optical amplifier of this fact via the monitoring line. Each optical amplifier performs gain control based on this information. However, after the wavelength is cut, a certain time is required for the terminal device to detect the cut and notify the optical amplifier via the monitoring line. During this period, since each optical amplifier is not aware of the interruption of a certain wavelength, the power of the optical wavelength increases due to the influence of the ALC control. This period is also momentary, but causes a burst error.
(3) When an optical amplifier is provided with an optical ADM function utilizing optical wavelength selectivity, the number of optical wavelengths input to the optical amplifier does not necessarily match the number of wavelengths transmitted from the terminal station device. Not exclusively. For this reason, the number of wavelengths is managed at key points in each network, and information such as the number of wavelengths input to each optical amplifier is notified via a monitoring line. In the case of FIG. 9, for example, if the ADD wavelength from the optical amplifier A15 is cut off, the number of wavelengths input to the optical amplifier B naturally changes. However, since the transmitting-side terminal device A manages only the number of its own transmitting wavelengths, the disconnection of the ADD wavelength in the optical amplifier A cannot be transmitted. For this reason, the power of the optical wavelength in the optical amplifier B increases due to the influence of the ALC control, and a transmission error occurs.

  The present invention has been made in view of the above problems, and has as its object to avoid a signal error due to a fluctuation in optical power in a WDM communication system.

  In order to solve the above problems, the present invention employs means for solving the problems having the following features.

  According to a first aspect of the present invention, in the supervisory control method in the WDM communication system, in the case of adding a wavelength, all light passing through the additional wavelength is transmitted by a supervisory control signal while the light source of the wavelength to be added is kept OFF. The present invention is characterized in that current reception power information and amplification limit value information of an amplifier are collected, and the light source is turned on if expansion is possible, and otherwise, the expansion is refused.

  According to the first aspect of the present invention, in the case of wavelength addition, the current reception power information and amplification of all the optical amplifiers through which the additional wavelength passes are supplied by the monitoring control signal while the light source of the wavelength to be added is kept OFF. Limit value information is collected, and if the extension is possible, the light source is turned ON. Otherwise, the extension is refused. Therefore, it is possible to prevent the wavelength extension from being performed excessively. AGC function can be properly exhibited.

  According to a second aspect of the present invention, in the supervisory control method in the WDM communication system, when the terminal station device is added, the added optical wavelength is gradually strengthened and transmitted, and each relay device transmits the optical signal of the relay device. The amplification limit of the amplifier is set to a small value, and when the received power exceeds the amplification limit, a warning is automatically issued in all directions by the monitoring control signal. Is characterized in that power is promptly reduced and expansion is stopped.

  According to the second aspect of the present invention, at the time of the extension, the terminal station device gradually increases the transmitted optical wavelength and transmits the signal, and each relay device sets the amplification limit of the optical amplifier of the relay device to a small value. In the meantime, when the received power exceeds the amplification limit, a warning is automatically issued in all directions by the monitoring control signal, and in the terminal device, when the warning is received, the power is promptly reduced, By canceling the extension, even if it is not clear which route the wavelength to be extended passes, it is possible to prevent the wavelength extension from being performed excessively, and the relay device can always properly perform the AGC function. It becomes possible.

  According to a third aspect of the present invention, in the terminal device of the WDM communication system, the terminal device has a supervisory control signal transmitting / receiving circuit, and the supervisory control signal transmitting / receiving circuit includes a light source to be added when the wavelength is added. While the switch is OFF, the monitor control signal is used to collect the current reception power information of the optical amplifiers of all the repeaters through which the additional wavelength passes and the amplification limit value information of the optical amplifier in each repeater. The transmission / reception circuit judges from the reception power information and the amplification limit value information of the optical amplifier of each relay device, and turns on the added light source if expansion is possible, and otherwise stops the expansion. And According to a third aspect of the present invention, there is provided a terminal device used in the monitoring control method according to the first aspect.

  According to a fourth aspect of the present invention, in the terminal device of the WDM communication system, the terminal device of the WDM communication system gradually strengthens the light source to be added while receiving the monitoring control signal from each relay device. When transmitting and receiving a monitoring control signal including a warning indicating that addition is impossible, which is issued from one relay device, the power of the light source to be added is quickly reduced and the addition is stopped. According to a fourth aspect of the present invention, there is provided a terminal device used in the monitoring control method according to the second aspect.

  According to the present invention, it is possible to avoid a signal error due to a fluctuation in optical power in a WDM communication system.

  In particular, according to the first aspect of the present invention, in the case of adding a wavelength, the current reception power information of all the optical amplifiers through which the additional wavelength passes is supplied by the monitoring control signal while the light source of the wavelength to be added is kept OFF. And amplification limit value information, and if the extension is possible, the above light source is turned on. Otherwise, the extension is refused. The device can properly exhibit the AGC function.

  According to the second aspect of the present invention, at the time of extension, the terminal device gradually increases the added optical wavelength and transmits the signal, and each relay device reduces the amplification limit of the optical amplifier of the relay device. If the received power exceeds the amplification limit, a warning is automatically issued in all directions by the monitoring control signal, and the terminal device immediately reduces the power when the warning is received. By suspending the addition, even if it is not clear which path the wavelength to be added passes, it is possible to prevent the wavelength from being excessively added, and the relay device always properly performs the AGC function at all times. It becomes possible.

  Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows an example of a customer support system of the present invention.

Next, embodiments of the present invention will be described with reference to the drawings.
(1) Principle of Solving the Problem The reason why the ALC control is performed by the optical amplifier (optical amplifier) is that the intervals of the optical repeater sections are not equal, and the loss varies due to the surrounding environment. If these relay intervals are equal and there is no variation in loss, each optical amplifier can be controlled by an AGC (Automatic Gain Control: automatic gain control) circuit. Even if the number of input wavelengths changes, the output power of each wavelength does not fluctuate because the gain of each optical amplifier is controlled to be constant. Thus, the configuration in which each optical amplifier is controlled by the AGC circuit is as shown in FIG. In FIG. 10, the input power of the optical amplifier 22 (EDFA: Erbium Doped Fiber Amplifier) is monitored by the monitor 31, and the output power is monitored by the monitor 32. The AGC circuit 23 controls the amplifier 22 based on these monitor outputs to make the gain of the optical amplifier 22 constant.

  Next, ignoring the fluctuation of the loss due to the surrounding environment of the optical fiber for the time being, consider a multistage relay using an optical amplifier in a transmission line having different relay intervals (L1 to L5) as shown in FIG. Each optical amplifier amplifies the input optical power so as to have a constant level. The gain of each of the optical amplifiers 32 to 35 always compensates for only the loss (α1 to α5) of the preceding relay interval. That is, the optical amplifier 32 amplifies only by α1 (G1 = α1), and the optical amplifier 35 amplifies by α4 (G4 = α4). As a result, the output power of the transmission device 30 and the output power of the optical amplifier 35 become the same.

The loss (α1 to α5) of the preceding relay interval can be determined from the information of the transmission power of the preceding relay device of each of the optical amplifiers 32 to 35 and the information of its own input power. Therefore, the gain of each optical amplifier may be determined so as to compensate for this loss. In this case, even if a new wavelength is added or removed by the transmitting device, the output of each optical amplifier is kept constant, and power fluctuation on the receiving side does not occur.
(2) Configuration of AGC Control Unit of the Present Invention (Part 1)
FIG. 12 shows a configuration example of the AGC control unit in the WDM communication system of the present invention based on the above principle. The WDM optical wavelength on the transmission line 20 is transmitted downstream via the optical wavelength separation device 44, the monitor 31, the EDFA 22, the monitor 32, and the optical wavelength multiplexing device 45. The optical wavelength separation device 44 separates the wavelength λs on which the supervisory control signal is present from the received WDM optical wavelength, and applies the wavelength λs to the supervisory control signal transmission / reception circuit 49. The monitor 31 is a monitor for detecting the level of the received signal, which is also the signal before being amplified by the optical amplifier. The EDFA 22 is an optical amplifier. The monitor 32 is a monitor for detecting the level of a signal that is a signal after being amplified by the optical amplifier and is also a transmission signal. The optical wavelength multiplexing device 45 is a device that performs optical wavelength multiplexing in order to put its own station transmission power information from the supervisory control signal transmitting / receiving circuit 49 on the wavelength λs or the like.

  The operation of FIG. 12 will be described. The AGC circuit 43 outputs the output 42 (upstream transmission power information) of the monitor control signal transmission / reception circuit 49, the output 27 of the monitor 31 (the level of the received signal, the signal level before amplification), and the output 28 of the monitor 32 (the transmission signal level). The amplifier 22 is controlled based on the level and the signal level after amplification, and the gain of the optical amplifier 22 is kept constant.

  The transmission output power information of the preceding stage from the upstream is put on the wavelength λs for monitoring and control. This wavelength λs is split by the optical wavelength demultiplexer 44 and applied to the supervisory control signal transmitting / receiving circuit 49. The monitor control signal transmission / reception circuit 49 obtains the transmission output power value of the preceding stage from the digital information 8 carried on the wavelength λs, and transmits the information 42 to the AGC circuit 43. On the other hand, the output (received signal level) 27 of the monitor 31 is applied to the AGC circuit 43. Therefore, the AGC circuit 33 obtains the transmission path loss α at the preceding stage from both values.

  The AGC circuit 33 can determine the gain of the EDFA from the output 27 of the monitor 31 (the signal level before amplification) and the output 28 of the monitor 32 (the signal level after amplification). The AGC circuit 33 controls 46 so that the loss value = the gain of the optical amplifier. As a result, the optical amplifier 22 compensates for the loss, and the output becomes constant. The digital value of the output power value of the optical amplifier 22 is transmitted from the AGC circuit 43 to the monitor control signal transmitting / receiving circuit 49. The supervisory control signal transmission / reception circuit 49 puts the digital value of the output power value 9 on the wavelength λs and is notified downstream via the optical wavelength multiplexing device 45.

Originally, the transmission power monitor and the reception power monitor are indispensable for the AGC control, and even if the method of the present invention is adopted, the cost can be reduced because it can be realized without adding a new monitor. Further, even when there is a change in the loss due to the surrounding environment of the transmission line optical fiber, the gain of the optical amplifier is determined based on the difference between the upstream transmission power and the reception power, so that this fluctuation is absorbed.
(3) Configuration of the AGC Control Unit of the Present Invention (Part 2) (In the following description, the parts that are the same as the previously described parts will be omitted.)
Each wavelength has a different power depending on whether the modulation signal is “H” or “L”. Therefore, the levels of the transmission power and the reception power are not constant but fluctuate according to the modulation signal. On the other hand, when the fluctuation frequency of the surrounding environment of the optical fiber becomes high and the fluctuation frequency is about the fluctuation due to the modulation signal, it becomes impossible to accurately measure the level fluctuation of the transmission power and the reception power based on the environmental change.

  Therefore, as shown in FIG. 13, this problem is solved by providing a DC light source 50 for measuring the optical fiber loss (wavelength λk) and detecting this downstream. That is, the measurement direct-current light source 50 whose transmission power (p) is known is superimposed on a signal and transmitted, and this is detected downstream. The attenuation in the transmission line is calculated from the known transmission level value (p) and the reception level value of the wavelength λk, and the gain of the optical amplifier is determined so as to compensate for the attenuation. In this case, there is no need to notify the transmission power by the monitoring control signal. The known measuring DC light source 50 is not used commonly in each relay section, but is provided independently for each relay section. If the measurement DC light source 50 is commonly used in each relay section, if a difference between the actual transmission level and a known level value occurs, the error is accumulated and a problem occurs. The problem is solved by providing each relay section independently. If there is “variation” in the output power of the measurement light source, the power of the measurement light source may be monitored, and the transmission level value may be notified downstream by a monitoring control signal.

In FIG. 13, the AGC circuit 53 calculates the amount of attenuation in the transmission line. However, another circuit may calculate the amount of attenuation in the transmission line, and the AGC circuit 53 may use the result.
(4) Configuration of AGC Control Unit of the Present Invention (Part 3)
However, even with the configuration of the AGC control unit of the present invention (Part 2), it is necessary to provide a monitoring control signal of another wavelength in the optical amplifier repeater, and the configuration of the AGC control unit of the present invention (Part 2). As described above, adding a light source for measurement further increases the cost. Therefore, the wavelength for the supervisory control signal is used. In this case, the wavelength for the monitoring control signal may be provided independently for each relay section, or may be commonly used for each relay section. FIG. 14 shows an example of the configuration. It is assumed that the transmission level before the wavelength λs for the supervisory control signal is known. The power measurement circuit 631 of the AGC circuit 63 calculates the attenuation of the repeater section from the known transmission level of the wavelength λs and the level of the wavelength λs of the transmission line 641 actually received, and compensates for the optical attenuation so as to compensate for this attenuation. Determine the gain of the amplifier.

  Also, since the information transmission speed of the supervisory control signal is usually low, the level fluctuation due to the information "H" and "L" is small, so that the power must be measured from the wavelength λs for the supervisory control signal. No problem. However, when the amount of information to be transmitted increases due to the supervisory control signal, the communication speed also increases, and a problem arises in measuring the power from the wavelength λs for the supervisory control signal. In such a case, the monitoring control signal is as shown in FIG. The monitoring control signal is divided into two, and an area A for inputting information and an area B having a constant level are set. The level of the wavelength λs is measured by measuring the level of the constant level area B of the monitoring control signal.

Further, the power of the output of the wavelength λs for the supervisory control signal on the transmitting side may be monitored, and the transmission level value may be notified downstream by the supervisory control signal.
(5) Configuration of AGC Control Unit of the Present Invention (Part 4)
In the modification of the configuration (part 3) of the AGC control unit of the present invention, the monitor control signal in FIG. 15 is configured using an RZ code, and FIG. 16 illustrates the configuration (part 4) of the AGC control unit. FIG. Since the RZ code always has "0" in each code, if the reception level is measured based on the "0" level, accurate measurement independent of information can be performed. FIG. 17 shows the monitoring control signal. An information area A and a "0" area B having a constant level. In this case, in order to measure the reception level, it is necessary to treat the area A and the area B separately. Therefore, it is necessary to create a synchronization signal for distinction. The synchronization signal is shown in the lower part of FIG. T1 is the time during which a certain level exists. The monitor control signal transmission / reception circuit 79 generates this synchronization signal and passes it to the power measurement circuit 731 of the AGC circuit 73. The power measurement circuit 731 uses this synchronization signal to find a constant “0” region B and accurately measure the reception level of the wavelength λs for the supervisory control signal. Note that T is F = 1 / (2Fmax) from the sampling theorem, where Fmax is the maximum frequency of loss fluctuation in the optical transmission line.
It is better to make it shorter.

Alternatively, the transmission power of the wavelength λs for the supervisory control signal on the transmitting side may be monitored, and the transmission level value may be notified downstream by the supervisory control signal.
(6) Configuration of AGC control unit of the present invention (part 5)
In the configuration of the AGC control unit described above, if the monitoring control signal or the measurement light source is turned off, the gain of the optical amplifier cannot be determined, and the optical amplifier malfunctions, making communication of all wavelengths impossible. For this reason, it is necessary to design the transmission / reception unit of the monitoring control signal and the light source separately or to be replaceable. Therefore, in order to prevent the line from being affected even when the monitoring control signal or the measuring light source is cut off, each optical amplifier is connected to the same circuit when the monitoring control signal or the measuring light source is cut off. State was maintained. FIG. 18 shows an example of the configuration. A storage unit 832 is provided in the AGC circuit 83 to constantly update and store the AGC control information value based on the monitoring control signal and the measurement light source. If the optical signal is interrupted or an abnormality is detected, The monitoring control signal transmission / reception circuit 89 receives the monitoring control signal abnormality detection signal 81 and transmits it downstream, and the AGC circuit 83 operates the AGC circuit 83 based on the information stored in the storage unit 832.

The monitoring control signal abnormality detection signal 81 also includes mounting abnormality information of the monitoring control signal transmission / reception circuit 89. In addition, by doing so, even if the monitor control signal transmission / reception circuit 89 is pulled out, the influence on the line can be eliminated. On the other hand, when the monitoring control signal transmitting / receiving circuit 89 is inserted, a time monitoring control signal abnormality detection signal 81 is generated until the monitoring control signal starts to operate normally. Thus, even when the monitoring control signal transmitting / receiving circuit 89 is inserted, the line is not affected.
(7) Specific configuration example of AGC control unit (part 1)
FIG. 19 shows a specific configuration example of the AGC control unit in the WDM communication system of the present invention. The WDM optical wavelength is transmitted downstream via the optical wavelength demultiplexer 201, optical coupler 202, optical isolator 203, EDFA 204, optical coupler 205, optical wavelength filter 206, optical coupler 207, and optical wavelength multiplexing device 208. The supervisory control signal light has a wavelength λs, and the wavelength λs is also a supervisory line.

  In the optical wavelength separation device 201, the optical wavelength λs is separated and applied to the monitoring control device 209. In the optical coupler 202, a part of the received light is branched and applied to the photodetector 215. The optical isolator 203 has a function of preventing the flow of the reverse light wavelength and preventing the EDFA excitation light from leaking to the photodetector 215 that detects the level of the received light. The EDFA 204 is an optical amplifier. The optical coupler 205 couples the EDFA excitation light source 216 to the EDFA 204. The optical wavelength filter 206 removes unnecessary wavelengths, and the optical coupler 207 splits a part of the transmission light and applies it to the photodetector 219. The optical wavelength multiplexing device 208 is a device that wavelength-multiplexes and transmits a supervisory control signal and the like.

  Upon receiving the light wavelength λs separated by the light wavelength separation device 201, the monitoring control device 209 obtains the upstream transmission power from the digital information in the monitoring control signal, and passes the value to the loss calculation circuit 210. The output of the analog-to-digital converter 213 is applied to the other input terminal of the loss calculation circuit 210. An electric signal corresponding to the level of the received light detected by the photodetector 215 is applied to the analog-to-digital converter 213 via an amplifier 214. Therefore, the upstream transmission power value and the digital output value corresponding to the level of the received light are applied to the loss calculation circuit 210. The loss calculation circuit 210 obtains the difference between the values to determine the loss of the signal from the upstream.

  A part of the optically amplified optical signal is applied to the photodetector 219 by the optical coupler 207. The photodetector 219 performs a light-to-electric conversion to detect a transmission level. The output of the light detector 219 is applied to the difference calculation circuit 220 via the amplifier 217. To the other input terminal of the difference calculation circuit 220, a signal corresponding to the level of the received light, which is the level of the signal before optical amplification, is applied. Therefore, the gain of the optical amplifier 226 is obtained from the output of the difference calculation circuit 220.

  Here, control is performed so that the loss value of the loss calculation circuit is equal to the gain of the optical amplifier 204. That is, a signal corresponding to the loss of the loss calculation circuit and a signal corresponding to the gain of the optical amplifier 204 are applied to the difference amplifier 211. The difference value between the two is obtained from the difference amplifier 211, and the difference value is applied to the laser diode drive circuit 222. The laser diode drive circuit 222 increases / decreases the output of the EDFA excitation light source 216 in accordance with the difference value, and makes the transmission line loss value and the gain of the optical amplifier 204 the same.

An electric signal corresponding to the transmission level detected by the photodetector 219 is applied to an analog / digital converter 218 via an amplifier 217. The output of the analog-to-digital converter 218 is applied to the supervisory control signal device 221 and the transmission level information is inserted into the supervisory control signal and transmitted downstream. In FIG. 19, the excitation light source of the EDFA is backward excitation, but may be forward excitation or both excitation.
(8) Specific configuration example of AGC control unit (part 2)
In FIG. 19, the intensity of the excitation light source is adjusted to control the loss value of the loss calculation circuit and the gain of the optical amplifier 226 to be the same. However, as shown in FIG. A variable optical attenuator 230 may be provided, and the amount of attenuation may be controlled by the output of the laser diode drive circuit 222. Thus, it is possible to eliminate a change in gain tilt due to the strength of the pump laser diode.
(9) Configuration example of AGC control unit of optical amplifier having ADM function (part 1)
As shown in FIG. 21, the AGC control unit of the optical amplifier having the ADM function transmits the WDM signals from the upstream transmission lines 301, 304, and 306 to the downstream transmission lines 302, 303, and 305. At this time, the optical amplifier having the ADM function branches and inserts the signal, and a WDM signal different from the WDM signal from the upstream flows to the downstream.

  The signals on the transmission path 301 and the signal on the transmission path 304 are multiplexed by the multiplexers 344 by the ADMs 360 and 391 and transmitted to the transmission path 305. Further, the signals on the transmission path 306 are demultiplexed by the demultiplexer 343 by the ADMs 360 and 391 and transmitted on the transmission path 302 and the transmission path 303. The WDM optical wavelengths on the transmission paths 301, 304, and 306 are the optical wavelength demultiplexers 325 to 327, the monitors 350, 353, 356, the optical amplifiers 308 to 310, the monitors 351, 354, 355, the ADMs 360, 391, and the monitor 352. 359 and the optical wavelength division multiplexers 340-342. The optical wavelength separation devices 325 to 327 separate the monitoring light wavelength λs on which the monitoring control signal sv is superimposed from the received WDM optical wavelength, and apply them to the monitoring control signal transmission / reception circuits 315 to 317. The monitors 350, 353, and 356 are monitors for detecting the level of the received signal, which is also a signal before being amplified by the optical amplifier. The monitors 351, 354, and 355 are monitors for detecting the level of the signal after amplification by the optical amplifier. The ADMs 360 and 391 have the configurations shown in FIGS. 4, 5 and 6, and add / drop wavelengths. The monitors 352 and 359 are monitors for detecting the level of the signal actually transmitted after being dropped and inserted by the ADMs 360 and 391. The optical wavelength multiplexing devices 340 to 343 are devices for wavelength multiplexing the supervisory control signals sv and the like from the supervisory control signal transmitting and receiving circuits 315 to 317.

  The basic operation is the same as the operation in FIG. The AGC circuits 320 to 322 output the monitoring control signal transmitting and receiving circuits 315 to 317 (upstream transmission power information), the outputs of the monitors 350, 353, and 356 (the level of the received signal, the signal level before amplification) and the monitor 351. The AGC control of the amplifiers 308 to 310 is performed based on the outputs of the signals 354 and 355 (the signal levels after amplification), and the gains of the optical amplifiers 308 to 310 are made constant.

  The transmission output power information of the preceding stage from the upstream is included in the monitoring control signal sv and is superimposed on the monitoring light wavelength λs. The monitoring light wavelength λs carrying the monitoring control signal sv is branched by the optical wavelength separation devices 325 to 327 and applied to the monitoring control signal transmitting / receiving circuits 315 to 317. The monitoring control signal transmission / reception circuits 315 to 317 obtain upstream transmission output power values from digital information in the monitoring control signal sv carried on the monitoring light wavelength λs, and transmit the information to the AGC circuits 320 to 322. On the other hand, outputs (received signal levels) of the monitors 350, 353, and 356 are applied to AGC circuits 320 to 322. Therefore, the AGC circuits 320 to 322 obtain the loss α of the transmission line in the preceding stage from the values of both.

  The gains of the EDFAs 308 to 310 are obtained by the AGC circuits 320 to 322 from the outputs of the monitors 350, 353, 356 (the signal levels before amplification) and the outputs of the monitors 351, 354, 355 (the signal levels after amplification). Can be. The AGC circuits 320 to 322 control the optical amplifiers 308 to 310 so that the loss value is equal to the gain of the optical amplifier. As a result, the optical amplifiers 308 to 310 compensate for the loss of the upstream transmission path, and the output becomes constant. The digital value of the transmission output power A value of the monitors 352 and 359 is transmitted to the monitoring control signal transmission / reception circuits 315 and 316. The supervisory control signal transmission / reception circuits 315, 316 include the digital value of the output power value in the supervisory control signal sv, put it on the supervisory light wavelength λs, and are notified downstream via the optical wavelength multiplexing devices 340, 341. You.

Although the configuration of the optical amplifier having the ADM function is shown as a T-shaped configuration, the configuration is not limited to this, and an ADM having a star configuration may be used.
(10) Configuration Example of AGC Control Unit of Optical Amplifier Having ADM Function (Part 2)
FIGS. 22 and 23 are partially modified configurations of the AGC control unit in FIG. 21, and compensate for loss in a transmission section using supervisory control signal light or measurement light.

  The configuration example of FIG. 22 is an example in which AGC is performed using the level of the supervisory control signal light wavelength λs. The supervisory control signal lightwave λ length s carrying the supervisory control signal sv is branched by the optical wavelength separation devices 325 to 327 and applied to the supervisory control signal transmission / reception circuits 366 to 368. The supervisory control signal transmission / reception circuits 366 to 368 calculate the loss in the transmission section from the reception level of the supervisory control signal light wavelength λs, which is a known transmission level, and apply it to the AGC circuits 360 to 362. The AGC circuits 360 to 362 determine the gains of the optical amplifiers 308 to 310 from the outputs of the monitors 350, 353, 356 (the signal levels before amplification) and the outputs of the monitors 351, 354, 355 (the signal levels after amplification). Then, the AGC circuits 360 to 362 control the optical amplifiers 308 to 310 so that the loss value is equal to the gain of the optical amplifier. As a result, the optical amplifiers 308 to 310 compensate for the loss of the upstream transmission path, and the output becomes constant. Note that the transmission line loss may be calculated by the AGC circuits 360 to 362. In addition, although the configuration of the optical amplifier having the ADM function is shown as a T-shaped configuration, the configuration is not limited to this, and an ADM having a star configuration may be used.

  The configuration example of FIG. 23 is an example in which AGC is performed using the level of the measuring light wavelength λk. This is an example in which the configuration of FIG. 13 is applied to an AGC control unit of an optical amplifier having an ADM function. The measurement light wavelength λk (its transmission level is known) from the measurement DC light source generator 400 is wavelength-multiplexed by the wavelength multiplexing devices 401 to 403 and transmitted downstream. The method of AGC control is the same as that in FIG. 13, and the description is omitted. In addition, although the configuration of the optical amplifier having the ADM function is shown as a T-shaped configuration, the configuration is not limited to this, and an ADM having a star configuration may be used.

  As described above, according to the present invention, it is possible to construct a WDM communication system that does not affect other wavelengths even if signal disconnection or addition or removal of wavelengths is performed. However, if the expansion is performed indefinitely, sometime, the gain of the optical amplifier will be saturated. In such a case, it becomes impossible to further increase the gain of the optical amplifier by the AGC control. In other words, if the number of wavelengths increases due to the extension, the lowest gain per wavelength in the optical amplifier cannot be secured, which is the limit of the extension. Therefore, when adding an optical amplifier, it is necessary to confirm that all the optical amplifiers on the relay path can be added without any problem by the addition. For the confirmation, the terminal device needs to see the input information, which is the reception power of each optical amplifier, and the information of the amplification limit that can be guaranteed for each optical amplifier by the monitoring control signal.

  In the present invention, each optical amplifier has amplification limit information that can guarantee amplification in the optical amplifier, and always monitors the power of the input signal of its own device. Check when adding. In other words, when an extension is performed in the transmission unit of the terminal device, the current input level value of the optical amplifier and the optical amplifier can be compensated for all the optical amplifiers that pass through the path to the terminal device that receives the signal. The terminal device is notified of the limit information. Whether or not expansion is possible depends on whether or not the optical amplifier of the repeater can secure the minimum gain per wavelength for the loss of the transmission path. Each terminal device determines whether or not the addition can be performed based on whether or not the minimum gain per wavelength can be secured, based on the input level and the number of additional pumping light sources.

  FIG. 24 shows an example of the terminal equipment. The terminal device includes a supervisory control signal transmission / reception circuit 511, light sources 501 to 504, a transmission unit 513, a reception unit 512, a wavelength multiplexing device 510, and a wavelength separation device 513. The transmission unit 513 includes switches 505 to 508 for selecting a light source and an optical multiplexer 509. The monitoring control signal transmission / reception circuit 511 transmits the state of the optical amplifier to the optical amplifier in the path using a multi-frame as shown in FIG. FTOP is a signal indicating the start of a frame, and data is loaded on TS1 to TS24. FIG. 26 shows the contents of TS1 to TS24. FIGS. 27 and 28 show the definitions of OPCODE and FLG which constitute a part of the data. AIS is a flag indicating a monitoring control signal abnormality (notifying an upstream abnormality), and AIS-LB is a flag indicating a monitoring control signal abnormality in the opposite direction (notifying a downstream abnormality). ID is a signal that specifies the optical amplifier. Thus, each optical amplifier notifies the terminal device of the input level value of the optical amplifier, information on the limit that can be compensated by the optical amplifier, the presence / absence of addition, and the like.

  However, in a complicated network employing the ADM, it is difficult to manage what route the wavelength passes through. For example, when multi-bender optical amplifiers are mixed, the configurations of the optical amplifiers are different. In such a case, the limit value of each optical amplifier is set to a small value in advance, and when the expansion is performed, the optical power is gradually increased. At this time, each optical amplifier issues a warning to all terminal devices when the limit value having a margin is reached. Upon receiving this warning, the terminal device lowers the power. As a result, even in a complicated network employing the ADM, it is possible to reliably prevent each optical amplifier from being saturated by the addition. FIG. 29 shows the terminal equipment. Attenuators 605 to 608 are provided instead of the switches in FIG. 24, and are controlled by the output of the monitor control signal transmission / reception circuit 611.

FIG. 2 is a diagram for describing a configuration of a WDM communication system. FIG. 2 is a diagram for describing a configuration of a terminal device of a WDM communication system. FIG. 2 is a diagram for explaining a configuration of a relay device of the WDM communication system (without an ADM function). FIG. 2 is a diagram for explaining a configuration (with an ADM function) of a relay device of a WDM communication system. FIG. 2 is a diagram illustrating a configuration of a passive ADM of the WDM communication system. FIG. 3 is a diagram for explaining a configuration of an active ADM of the WDM communication system. FIG. 2 is a diagram illustrating a configuration of a monitoring control device of the WDM communication system. FIG. 2 is a diagram for describing one mode of a WDM communication system. FIG. 2 is a diagram for describing a configuration example of a WDM communication system using an optical amplifier having an ADM function. FIG. 3 is a diagram for explaining a simple configuration of an optical amplifier controlled by AGC. FIG. 3 is a diagram for explaining a loss in a WDM communication system. FIG. 4 is a diagram for explaining a configuration (part 1) of an AGC-controlled optical amplifier of the present invention. FIG. 4 is a diagram for explaining a configuration (part 2) of an AGC-controlled optical amplifier according to the present invention. FIG. 7 is a diagram for explaining a configuration (part 3) of an AGC-controlled optical amplifier of the present invention. FIG. 4 is a diagram for describing a configuration example of a monitoring control signal. FIG. 9 is a diagram for explaining a configuration (part 4) of an AGC-controlled optical amplifier according to the present invention. FIG. 4 is a diagram for describing a configuration example of a synchronization signal. FIG. 9 is a diagram for explaining a configuration (part 5) of an AGC-controlled optical amplifier according to the present invention. FIG. 3 is a diagram for describing a configuration (part 1) of an AGC control unit. FIG. 9 is a diagram for describing a configuration (part 2) of an AGC control unit. FIG. 9 is a diagram for describing a configuration (part 1) of a relay device in an ADM (in the case of a T-shape). FIG. 9 is a diagram for explaining a configuration (part 2) of a relay device in an ADM (in the case of a T-shape). FIG. 11 is a diagram for describing a configuration (part 3) of a relay device in an ADM (in the case of a T-shape). FIG. 2 is a diagram for describing a configuration of a terminal device (part 1) in a WDM communication system. FIG. 4 is a diagram for describing an example of a monitoring control signal. FIG. 3 is a diagram for explaining the contents of a TS. It is a figure for explaining the definition of OPCODE. It is a figure for explaining the definition of FLG. FIG. 4 is a diagram for describing a configuration of a terminal device (part 2) in a WDM communication system.

Explanation of reference numerals

22, 204, 308, 309, 310 EDFA (optical amplifier)
43, 5363, 73, 83, 320, 321, 322, AGC circuit 49, 69, 79, 89, 315, 316, 317 Monitoring control signal transmitting / receiving circuit

Claims (4)

In the monitoring and control method in the WDM communication system, in the case of adding a wavelength, the current reception power information and the amplification limit of all the optical amplifiers through which the additional wavelength passes are supplied by the monitoring control signal while the light source of the wavelength to be added is kept OFF. A monitoring and control method in a WDM communication system, wherein value information is collected and the light source is turned on if expansion is possible, otherwise the expansion is refused. In the monitoring and control method in the WDM communication system, the terminal device transmits the added optical wavelength gradually intensified at the time of expansion, and each relay device sets the amplification limit of the optical amplifier of the relay device to a relatively small value. When the received power exceeds the amplification limit, a warning is automatically issued in all directions by the supervisory control signal.In the terminal device, when the warning is received, the power is promptly reduced, and the power is increased. Monitoring and control method in a WDM communication system, wherein the method is stopped. In a terminal device of a WDM communication system, the terminal device has a supervisory control signal transmitting / receiving circuit, and the supervisory control signal transmitting / receiving circuit receives a supervisory control signal while a light source to be added when a wavelength is added is kept OFF. Collecting the current reception power information of the optical amplifiers of all the relay devices through which the additional wavelengths pass and the amplification limit value information of the optical amplifiers in each of the relay devices, and the monitoring control signal transmitting and receiving circuit transmits the reception power information and Judging from amplification limit value information of the optical amplifier of the repeater, if the expansion is possible, the light source to be added is turned on; otherwise, the light source to be added is not turned on. Terminal equipment. In a terminal device in a WDM communication system, while receiving a monitoring control signal from each relay device, a light source to be added is gradually strengthened and transmitted, and a monitoring control including a warning from the one relay device that expansion is impossible is issued. A terminal device in a WDM communication system, wherein when a signal is received, the power of a light source to be added is rapidly reduced and the addition is stopped.

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