JP2007086809A - Optical communication device and optical branching/inserting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To allow an optical communication device which transmits a wavelength-multiplexed optical signal to stably operate without reference to whether there is input light or a modulated signal to be sent out. <P>SOLUTION: An optical branching/inserting device of the optical communication device of the present invention outputs input light from an input port to an output port through an optical branching means 10, an optical modulating means 11, and an optical branching means 12. A branched optical signal branched by the optical branching means 12, on the other hand, is made incident on an operation point control means 13 of controlling the operation point of the optical modulating means 11. The light intensity of branched input light branched by the optical branching means 10 is detected by an optical detecting means 15, which outputs a signal corresponding to the light intensity. This signal is input to a control means 14, which controls the operation of the operation point control means 13 so that the operation point of the operation point control means 13 can stably be maintained. Consequently, the operation point control means 13 can stably operates even in the absence of the input light etc. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an optical communication apparatus that transmits wavelength-multiplexed signal light, and stabilizes the operation regardless of the presence of input light or a modulated signal to be transmitted, and uses the optical communication apparatus as an insertion apparatus. The present invention relates to an optical add / drop device.

Aiming at the construction of a future multimedia network, ultra-long distance and large capacity optical communication devices are required. As a method for realizing this large capacity, a wavelength-division multiplexing method has been intensively studied from the viewpoint that it can effectively use the broadband and large capacity of an optical fiber.
In particular, research is being conducted on wavelength division multiplexing optical branching / insertion devices and optical modulators used in the insertion units of the optical branching / insertion devices, which are required at each node on the optical wave network.
A Mach-Zehnder type optical modulator (hereinafter abbreviated as “MZ modulator”) used as an optical modulator of a conventional optical communication apparatus is capable of stabilizing an optical signal output against temperature fluctuations and changes with time. is necessary. Therefore, an operating point control circuit for controlling the operating point of the MZ modulator is disclosed in Japanese Patent Laid-Open No. 3-251815.

FIG. 20 is a block diagram of an MZ modulator provided with this conventional operating point control circuit.
In FIG. 20, light emitted from a light source 310 such as a laser diode (hereinafter abbreviated as “LD”) enters an MZ modulator 311. Also, the modulation signal including the information to be transmitted and the low frequency signal of the predetermined frequency f 0 output from the low frequency oscillator 324 are input to the variable gain amplifier 313. The variable gain amplifier 313 superimposes and outputs a low frequency signal having a predetermined frequency f0 on the modulated signal. This output signal is input to one modulation input terminal of the MZ modulator 311 via an amplifier 314 that obtains a predetermined signal level and a coupling capacitor 315. In addition, a bias T circuit including an inductor 316 and a capacitor 317 and a resistor 318 are connected to the other modulation input terminal of the MZ modulator 311. A portion including the amplifier 314, the coupling capacitor 315, the bias T circuit, and the resistor 318 corresponds to a drive circuit for the MZ modulator 311.

The MZ modulator 311 modulates the light from the light source 310 with the signal given from the drive circuit and outputs the modulated light.
A part of the optical output from the MZ modulator 311 is branched and extracted by the optical branching unit 312. This branched optical output is detected by a photoelectric converter 319 such as a photodiode (hereinafter abbreviated as “PD”), and this detection signal is amplified and multiplied by a buffer amplifier 320 that selectively amplifies the frequency component of f0. Input to the device 321. The multiplier 321 receives a low-frequency signal output from the low-frequency oscillator 324, compares the phase of the input signal from the buffer amplifier 320 with the low-frequency signal from the low-frequency oscillator 324, and determines the phase difference. A corresponding signal is output.

Therefore, the multiplier 321 can detect the low frequency signal of the predetermined frequency f0 superimposed by the variable gain amplifier 313.
The output signal of the multiplier 321 is input to one input terminal of the differential amplifier 323 via a low-pass filter (hereinafter abbreviated as “LPF”) 322 that passes a frequency equal to or lower than a predetermined frequency f 0. . On the other hand, the other input terminal of the differential amplifier 323 is grounded. The output of the differential amplifier 323 is input to the inductor 316 of the bias T circuit as an error signal for moving the operating point of the MZ modulator 311, and the bias value is variably controlled so as to correct this operating point. .

In the MZ modulator having such a configuration, when the bias value is optimum, a low-frequency signal having a frequency f0 superimposed on the output light does not appear.
FIG. 21 is a waveform diagram for explaining the operation when drift occurs at the operating point in the MZ modulator having such a circuit configuration. FIG. 21A shows the input / output characteristics of the MZ modulator, and curve B in FIG. 21 is the input / output characteristics when the operating point drifts to the high voltage side with respect to curve A, and curve C in FIG. These are the input / output characteristics when the operating point drifts to the low voltage side with respect to the curve A. FIG. 21 (b) shows the waveform of the input signal, and FIGS. 21 (c), (c1) and (c2) show the waveform of the output optical signal for each input / output characteristic.

  As shown in FIG. 21, when the operating point drifts to the high voltage side or the low voltage side, the low frequency signal of the frequency f0 superimposed on the output light has its phase inverted by 180 degrees according to the difference in drift direction. appear. For this reason, since the bias voltage can be controlled by the signal from the multiplier 321, the drift of the operating point can be compensated.

Thus, the drift of the operating point is compensated by extracting the low frequency signal from the output light obtained by modulating the input light with the modulation signal and the low frequency signal and comparing the phase with the original low frequency signal. Therefore, such an operating point control circuit can stably control the operating point when input light (output light) and a modulated signal are present.
On the other hand, FIG. 22 is a block diagram of a conventional optical add / drop device.

  In FIG. 22, the wavelength-multiplexed signal light transmitted through the optical transmission line is amplified to a predetermined light intensity, and then enters an OADM (Optical Add-Drop Multiplexer) node unit 350 that branches and inserts the wavelength-multiplexed signal light. Is done. The signal light having a predetermined wavelength is branched by the OADM node unit 350 and is received and processed by the optical branching units 352 corresponding to the number of signal lights branched via the optical coupler 351. The signal light inserted by the OADM node unit 350 is generated by the optical insertion unit 355. The optical insertion units 355 are prepared for each wavelength by the number of signal lights to be inserted in the OADM node unit 350. The inserted signal light and the signal light transmitted without being branched by the OADM node unit 350 are wavelength-multiplexed, amplified, and transmitted to the optical transmission line.

  In the optical add / drop unit 355 of this optical add / drop device, the light from the LD 360 that generates light of a specific wavelength is amplified by the optical amplifier 361, and the output light of the optical amplifier 361 includes the above-described operating point control circuit. Modulated by the optical modulator 362. The modulated optical signal is amplified by the optical amplifier 363 and enters the optical coupler 354. This optical coupler 354 is inserted into the OADM node unit 350 together with optical signals generated by the same configuration of other wavelengths.

Incidentally, in the MZ modulator 311 shown in FIG. 20, in the case of a momentary interruption in which the input light incident on the MZ modulator 311 temporarily disappears and recovers again, the following state occurs.
When the input light disappears, the optical output branched by the optical branching device 312 disappears, and the operating point becomes indefinite. That is, in FIG. 21B, when the bias voltage Vb is (1) a voltage of 0 or less, (2) a voltage of greater than 0 and less than Vp, and (3) a voltage of Vp or more. It is in a state where it is unknown which voltage it is.

When the input light recovers in such an indefinite state, the operation of the bias T circuit results in an optimum operating point in the case of (2), but in the case of (1), Vb becomes 0, ( In the case of 3), Vb is Vp
It will not stick to the optimal operating point.
For this reason, when input light incident on the MZ modulator 311 is momentarily interrupted, there is a problem in that an optimum operating point cannot always be obtained.

  Conventionally, the MZ modulator 311 is used for a terminal station or the like and there is no case where input light is momentarily interrupted. However, when the MZ modulator 311 is used as the optical adder 355 of the optical add / drop device shown in FIG. 22, the light to be inserted into a wavelength not used in the wavelength multiplexed signal transmitted through the optical transmission line. Since it is necessary to switch the wavelength, there is always a state where the input light disappears during the switching of the wavelength. For this reason, the above problems are particularly serious.

  On the other hand, in the optical add / drop device shown in FIG. 22, when there is no input light in the optical modulator 362, an ASE (Amplified Spontaneous Emission) which is a noise level naturally generated by the optical amplifiers 361 and 363 is an optical transmission line. There is a problem of being sent to. Further, there is not always a modulation signal to be inserted in the optical insertion unit 355. When there is no such modulation signal, there is a problem that not only ASE but also input light that is not modulated by the modulation signal is sent to the optical transmission line.

Further, in the optical communication network, failure assessment of the optical communication network is performed based on the presence / absence of light intensity. Therefore, failure assessment cannot be performed when input light that is not modulated by the ASE and modulation signals described above is sent to the optical transmission line. There is a problem.
Accordingly, the invention according to any one of claims 1 to 5 provides an optical communication apparatus that stably maintains the operating point of the optical modulation means even when the optical communication apparatus temporarily has no input light or modulation signal. With the goal.

According to the sixth to ninth aspects of the present invention, there is provided an optical communication apparatus that does not output ASE and input light that is not modulated by the modulation signal even when the optical communication apparatus temporarily has no input light or modulation signal. For the purpose.
In the optical communication device according to any one of claims 10 to 15, the operating point of the optical modulation means is stably maintained even when the input light or the modulation signal is temporarily absent from the optical communication device, and the ASE and the modulation signal are used. An object of the present invention is to provide an optical communication apparatus that does not output unmodulated input light.

  In the optical add / drop device according to claim 16, even when there is an unused insertion device, the operating point of the optical modulation means in the insertion device is stably maintained, and the ASE and the modulation signal are transmitted from the insertion device. It is an object of the present invention to provide an optical add / drop device in which unmodulated input light is not inserted.

  Hereinafter, means for solving the problem will be described with reference to the drawings.

(Claims 1 and 3)
FIG. 1 is a block diagram of an optical communication apparatus according to claims 1 and 3.
In FIG. 1, the optical communication apparatus includes optical branching means 10 and 12, optical modulation means 11, operating point control means 13, control means 14, and light detection means 15.
The input light input to the input port is branched by the light branching means 10 that splits the light into two. The first branched input light branched by the optical branching means 10 is modulated by the optical modulation means 11 according to the modulation signal to be transmitted. The modulated optical signal from the light modulating means 11 is branched by the light branching means 12 that splits the light into two.

The first branched optical signal branched by the optical branching means 12 is output to the output port.
On the other hand, the second branched optical signal branched by the optical branching unit 12 enters the operating point control unit 13 that controls the operating point of the optical modulation unit 11.
The operating point control unit 13 can optimally maintain the operating point of the light modulating unit 11 when a part of the optical signal output from the light modulating unit 11 is incident.

  On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detecting means 15, and the light detecting means 15 outputs a signal corresponding to the light intensity. For example, the light detection means 15 outputs a signal when the light intensity becomes a predetermined value or less. Alternatively, the light detection means 15 outputs a signal when the light intensity becomes zero. The signal corresponding to the light intensity is input to the control unit 14 that controls the operation of the operation point control unit 13 so that the operation point control unit 13 can stably maintain the operation point.

When the control unit 14 receives a signal from the light detection unit 15, the control unit 14 performs control to stop the operation point control unit 13. Alternatively, the point creation control means 13 performs control so as to maintain the operating point within a certain range.
In this way, it is possible to detect whether or not the input light is below a predetermined light intensity by the light detection means 15. For this reason, when the input light is less than or equal to a predetermined light intensity, the control unit 14 can control the operating point control unit 13 so that the operating point is stably maintained according to the output of the light detecting unit 15. Therefore, in the optical communication device having such a configuration, the operating point is stably maintained even when there is no input light temporarily.

Of course, when the input light is larger than the predetermined light intensity so as to use the light modulation means 11, no signal is output from the light detection means 15. Therefore, the operating point control means 13 optimally controls the operating point only by the output of the light modulation means 11 incident through the light branching means 12.
(Claims 2 and 3)
FIG. 2 is a block diagram of the optical communication apparatus according to claims 2 and 3.

In addition, about the structure same as Claim 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.
In FIG. 2, the optical communication apparatus includes an optical modulation unit 11, an optical branching unit 21, an operating point control unit 13, a control unit 14, and a light detection unit 23.
The input light input to the input port is modulated by the light modulator 11. This modulated optical signal is branched by the optical branching means 21 that splits the light into three.

  The first branched optical signal branched by the optical branching means 21 is output to the output port. On the other hand, the second branched optical signal branched by the optical branching unit 21 enters the operating point control unit 13.

  On the other hand, the light intensity of the third branched input light branched by the light branching means 21 of the modulated optical signal is detected by the light detecting means 23, and the light detecting means 23 outputs a signal corresponding to the light intensity. For example, the light detection unit 23 outputs a signal when the light intensity of the modulated optical signal becomes a predetermined value or less. Alternatively, the light detection means 23 outputs a signal when the light intensity becomes zero. A signal corresponding to the light intensity is input to the control means 14.

  In this way, when the input light is less than or equal to the predetermined light intensity, the modulated optical signal output from the light modulation means 11 is also less than or equal to the predetermined light intensity. For this reason, it is possible to detect whether or not the input light is below the predetermined light intensity by detecting the light intensity of the modulated optical signal by the light detecting means 23. Therefore, the control unit 14 can control the operating point control unit 13 so that the operating point is stably maintained according to the output of the light detecting unit 23. Therefore, in the optical communication apparatus having such a configuration, the operating point is stably maintained even when there is no input light temporarily.

Of course, when the input light is larger than the predetermined light intensity so as to use the light modulation unit 11, no signal is output from the light detection unit 23. Therefore, the operating point control means 13 optimally controls the operating point only by the output of the light modulation means 11 incident through the light branching means 21.
(Claims 4 and 5)
FIG. 3 is a block diagram of the optical communication apparatus according to claims 4 and 5.

In addition, about the structure same as Claim 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.
In FIG. 3, the optical communication apparatus includes an optical modulation unit 11, an optical branching unit 12, an operating point control unit 13, a control unit 25, and a modulation signal detection unit 26.
The input light input to the input port is modulated by the optical modulation means 11, and the modulated optical signal thus modulated is branched by the optical branching means 12.

The first branched optical signal branched by the optical branching means 12 is output to the output port. On the other hand, the second branched optical signal branched by the optical branching unit 21 enters the operating point control unit 13.
On the other hand, the modulation signal to be transmitted is input not only to the optical modulation means 11 but also to the modulation signal detection means 26. The modulation signal detecting means 26 detects the signal intensity of the modulation signal and outputs a signal corresponding to the signal intensity. For example, the modulation signal detection unit 26 outputs a signal when the signal intensity becomes a predetermined value or less. Alternatively, the modulation signal detecting means 26 outputs a signal when the signal intensity becomes zero. A signal corresponding to the signal strength is input to the control means 25.

The control means 25 performs control to stop the operation of the operating point control means 13 when receiving a signal from the modulation signal detection means 26. Alternatively, the point creation control means 13 performs control so as to maintain the operating point within a certain range.
In this way, it is possible to detect whether or not the modulation signal is equal to or lower than the predetermined signal intensity by the modulation signal detection means 26. For this reason, when the modulation signal is equal to or lower than the predetermined signal strength, the control means 25 can control the operating point control means 13 so as to maintain the operating point stably according to the output of the modulation signal detecting means 26. . Therefore, in the optical communication apparatus having such a configuration, the operating point is stably maintained even when there is no modulation signal temporarily.

Of course, when there is information to be communicated and the modulation signal to be transmitted becomes larger than a predetermined signal strength, no signal is output from the modulation signal detection means 26. Therefore, the operating point control means 13 optimally controls the operating point only by the output of the light modulation means 11 incident through the light branching means 12.
(Claim 6)
FIG. 4 is a block diagram of the optical communication apparatus according to the sixth aspect.

In FIG. 4, the optical communication apparatus includes an optical branching unit 10, an optical modulation unit 11, an optical attenuation unit 31, an attenuation amount control unit 32, and an optical detection unit 33.
FIG. 4 shows a configuration in which the first branched input light output from the optical branching unit 10 is output to the output port via the optical attenuating unit 31 and the optical modulation unit 11. On the other hand, the configuration output to the output port via the light modulation means 11 and the light attenuation means 31 is indicated by the broken line in FIG. Further, the same components as those in claim 1 are denoted by the same reference numerals, and the description thereof is omitted.

The input light input to the input port is branched by the light branching means 10. The first branched input light branched by the light branching means 10 enters the light modulating means 11 via the light attenuating means 31 and is modulated thereby. The modulated optical signal modulated from the optical modulation means 11 is output to the output port.
The light attenuating means 31 transmits input light that is transmitted or attenuated to a predetermined light intensity (including 0) and outputs the light. Alternatively, the light attenuating means 31 is a 1-input multiple-output optical switch. When the light attenuating means 31 is an optical switch, one output terminal is connected to the light modulating means 11 and nothing is connected to another output terminal.

  On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detection means 33, and the light detection means 33 outputs a signal corresponding to the light intensity. For example, the light detection unit 33 outputs a signal when the light intensity becomes a predetermined value or less. Alternatively, the light detection means 33 outputs a signal when the light intensity becomes zero. A signal corresponding to the light intensity is input to the attenuation amount control means 32.

  The attenuation amount control means 32 controls the light attenuation means 31. That is, the attenuation amount control means 32 controls the light attenuation means 31 so as to attenuate the input light to a predetermined light intensity according to the signal of the light detection means 33. Alternatively, when the light attenuation means is an optical switch, the attenuation amount control means 32 switches the input light to an output terminal to which nothing is connected in accordance with the signal of the light detection means 33 and sends it out.

  In this way, it is possible to detect whether or not the input light has a predetermined light intensity or less by the light detection means 33. Therefore, when the input light is less than or equal to the predetermined light intensity, the attenuation amount control means 32 attenuates the input light to the predetermined light intensity by controlling the light attenuation means 31 according to the output of the light detection means 33. Can be input to the light modulation means 11. Alternatively, it can be sent to a terminal not connected to the light modulation means 11. Therefore, the optical communication apparatus having such a configuration does not send ASE to the output port when there is no input light.

Of course, when the input light is larger than the predetermined light intensity so as to use the light modulation unit 11, no signal is output from the light detection unit 33. At this time, the attenuation amount control means 32 controls the light attenuation means 31 so that the input light is transmitted or switched to a terminal connected to the light modulation means 11.
(Claim 7)
FIG. 5 is a block diagram of an optical communication apparatus according to a seventh aspect.

In FIG. 5, the optical communication apparatus includes an optical branching unit 10, an optical modulation unit 11, an optical detection unit 33, and a modulation control unit 35.
In addition, about the structure same as Claim 1 or Claim 6, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
The input light input to the input port is branched by the light branching means 10. The first branched input light branched by the optical branching means 10 is modulated by the optical modulation means 11, and the modulated modulated optical signal is output to the output port.

On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detecting means 33, and a signal corresponding to the light intensity is output. A signal corresponding to the light intensity is input to the modulation control means 35.
The modulation control unit 35 controls the light modulation unit 11. That is, the modulation control means 35 controls the light modulation means so as to attenuate the input light to a predetermined light intensity according to the signal of the light detection means 33. For example, the output can be eliminated by not supplying energy to the light modulation means 11. Alternatively, in the case of an MZ modulator, the output can be eliminated by shifting the phases of input light branched into two optical waveguides in the MZ modulator to create a phase difference of 180 degrees. Alternatively, in the case of a light modulation means using an acoustooptic effect, the output can be eliminated by applying an RF signal that selects a wavelength other than the wavelength of the input light.

  In this way, it is possible to detect whether or not the input light has a predetermined light intensity or less by the light detection means 33. For this reason, when the input light is below a predetermined light intensity, the modulation control means 35 can eliminate the output by controlling the light modulation means 11 according to the output of the light detection means 33. For this reason, the optical communication apparatus having such a configuration does not output the input light that is not modulated by the ASE and the modulation signal to the output port even when there is input light and no modulation signal.

Of course, when the input light is larger than the predetermined light intensity so as to use the light modulation unit 11, no signal is output from the light detection unit 33. At this time, the optical modulation unit 11 does not receive a signal from the modulation control unit 35 and thus operates normally as a modulation unit. (Claim 8)
FIG. 6 is a block diagram of an optical communication apparatus according to an eighth aspect.

In FIG. 6, the optical communication apparatus includes an optical attenuator 31, an optical modulator 11, an attenuation control unit 41, and a modulation signal detector 42.
FIG. 6 shows a configuration in which the input light input to the input port is output to the output port via the light attenuating means 31 and the light modulating means 11. On the other hand, the configuration output to the output port via the light modulation means 11 and the light attenuation means 31 is indicated by the broken line in FIG.

Further, the same components as those in claim 1 or claim 6 are designated by the same reference numerals, and the description thereof is omitted.
The input light input to the input port enters the light modulation means 11 via the light attenuation means 31 and is modulated thereby. The modulated optical signal from the optical modulation means 11 is output to the output port.

  On the other hand, the modulation signal to be transmitted is input not only to the optical modulation means 11 but also to the modulation signal detection means 42. The modulation signal detecting means 42 detects the signal intensity of the modulation signal and outputs a signal corresponding to the signal intensity. For example, the modulation signal detection means 42 outputs a signal when the signal intensity becomes a predetermined value or less. Alternatively, the modulation signal detecting means 42 outputs a signal when the signal intensity becomes zero. A signal corresponding to the signal intensity is input to the attenuation amount control means 41.

  The attenuation amount control unit 41 controls the light attenuation unit 31. That is, the attenuation amount control unit 41 controls the light attenuation unit 31 so as to attenuate the input light to a predetermined light intensity according to the signal of the modulation signal detection unit 42. Alternatively, when the light attenuation means 31 is an optical switch, the attenuation amount control means 41 switches the input light to an output terminal to which nothing is connected in accordance with the signal of the light detection means 33 and sends it out.

  In this way, it is possible to detect whether or not the modulation signal is equal to or lower than the predetermined signal intensity by the modulation signal detection means 42. For this reason, when the modulation signal is equal to or lower than the predetermined signal strength, the attenuation amount control unit 41 controls the attenuation unit 31 according to the output of the modulation signal detection unit 42 to transmit the input light to the light modulation unit 11. The light intensity can be attenuated and input. Alternatively, it can be sent to a terminal not connected to the light modulation means 11. Therefore, the optical communication apparatus having such a configuration does not send ASE to the output port when there is no input light. Furthermore, even when there is input light and no modulation signal, input light that is not modulated by the ASE and the modulation signal is not output to the output port.

Of course, when there is information to be communicated and the modulation signal to be transmitted becomes larger than a predetermined signal strength, no signal is output from the modulation signal detecting means 42. At this time, the attenuation amount control means 32 controls the light attenuation means 31 so that the input light is transmitted or switched to a terminal connected to the light modulation means 11.
(Claim 9)
FIG. 7 is a block diagram of an optical communication apparatus according to a ninth aspect.

In FIG. 7, the optical communication apparatus includes an optical modulation unit 11, a modulation signal detection unit 42, and a modulation control unit 45.
In addition, about the structure same as Claim 1 or Claim 8, the same code | symbol is attached | subjected and description is abbreviate | omitted.
The input light input to the input port is modulated by the light modulation means 11, and the modulated optical signal that has been modulated is output to the output port.

On the other hand, the modulation signal to be transmitted is input not only to the optical modulation means 11 but also to the modulation signal detection means 42. The modulation signal detection means 42 outputs a signal corresponding to the signal strength, and the output signal is input to the modulation control means 45.
The modulation control unit 45 controls the light modulation unit 11. That is, the modulation control means 45 controls the light modulation means so as to attenuate the input light to a predetermined light intensity according to the signal of the modulation signal detection means 42. For example, the output can be eliminated by not supplying energy to the light modulation means 11. Alternatively, in the case of an MZ modulator, the output can be eliminated by shifting the phases of input light branched into two optical waveguides in the MZ modulator to create a phase difference of 180 degrees. Alternatively, in the case of a light modulation means using an acoustooptic effect, the output can be eliminated by applying an RF signal that selects a wavelength other than the wavelength of the input light.

  In this way, it is possible to detect whether or not the modulation signal is equal to or lower than the predetermined signal intensity by the modulation signal detection means 42. For this reason, when the modulation signal is equal to or lower than the predetermined signal strength, the modulation control means 45 can eliminate the output by controlling the light modulation means 11. For this reason, the optical communication apparatus having such a configuration does not output the input light that is not modulated by the ASE and the modulation signal to the output port even when there is input light and no modulation signal.

Of course, when there is information to be communicated and the modulation signal to be transmitted becomes larger than a predetermined signal strength, no signal is output from the modulation signal detecting means 42. At this time, the optical modulation unit 11 does not receive a signal from the modulation control unit 45, and thus operates normally as a modulation unit.
(Claim 10)
FIG. 8 is a block diagram of an optical communication apparatus according to claim 10 in which an optical attenuating unit is added to claim 1. In the tenth aspect, the light attenuating means is attached to either one of the input or the output of the light modulating means in any one of the first, second, and fourth aspects. It is a block diagram of an optical communication apparatus when an optical attenuating means is attached to an input of an optical modulating means.

Hereinafter, the structure of Claim 10 in this case will be described, and the description of other cases will be omitted. Further, the same components as those in claim 1 are denoted by the same reference numerals, and description thereof is omitted.
In FIG. 8, this optical communication apparatus comprises optical branching means 10, 12, optical attenuation means 50, optical modulation means 11, operating point control means 13, control means 14, and optical detection means 15.

  The input light input to the input port is branched by the optical branching unit 10, and the branched first branched input light is input to the optical attenuating unit 50. The output light from the light attenuating means 50 is modulated by the light modulating means 11. The modulated modulated optical signal is branched by the optical branching means 12. The first branched optical signal branched by the optical branching means 12 is output to the output port. On the other hand, the second branched optical signal branched by the optical branching unit 12 enters the operating point control unit 13.

The light attenuating means 50 transmits the input light according to the intensity of the input light or attenuates it to a predetermined light intensity (including 0) and outputs it. Alternatively, the optical attenuating means 50 is a 1-input multiple-output optical switch. When the optical attenuating means 50 is an optical switch, one output terminal is connected to the optical modulation means 11 and nothing is connected to another output terminal.
On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detecting means 15, and the light detecting means 15 outputs a signal corresponding to the light intensity. A signal corresponding to the light intensity is input to the control means 14.

Such an optical communication apparatus not only operates in the same manner as the optical communication apparatus described in claim 1, but also does not send ASE to the output port when there is no input light.
That is, the light attenuating means 50 determines whether or not the input light has a predetermined light intensity or less and attenuates the input light. For this reason, when the intensity of the input light is equal to or lower than the predetermined light intensity, the input light is attenuated to the predetermined light intensity and output. Alternatively, when the light attenuating means 50 is an optical switch, when the intensity of input light is equal to or lower than a predetermined light intensity, the input light is switched to an output terminal to which nothing is connected and transmitted. Therefore, the optical communication apparatus having such a configuration does not send ASE to the output port when there is no input light.

Of course, when the input light becomes greater than a predetermined light intensity to use the light modulation means 11, the light attenuation means 50 transmits the input light and outputs it. Alternatively, when the light attenuating means 50 is an optical switch, it is switched to a terminal connected to the light modulating means 11 and transmitted.
(Claim 11)
FIG. 9 is a block diagram of an optical communication apparatus according to claim 11 in which the optical modulation means of claim 1 is controlled according to the modulation signal. In addition, although Claim 11 comprises an optical communication apparatus so that an optical modulation means may be controlled according to a modulation signal in any one of Claims 1, 2, and 4, FIG. FIG. 2 is a block diagram of an optical communication device when the optical modulation means is controlled according to a modulation signal.

Hereinafter, the structure of Claim 11 in this case will be described, and the description of other cases will be omitted. Further, the same components as those in claim 1 are denoted by the same reference numerals, and description thereof is omitted.
In FIG. 9, the optical communication apparatus includes optical branching means 10 and 12, optical modulation means 55, operating point control means 13, control means 14, and light detection means 15.

The input light input to the input port is branched by the optical branching means 10, and the branched first branched input light is modulated by the optical modulation means 55 according to the modulation signal to be transmitted. The modulated modulated optical signal from the light modulating means 55 is branched by the light branching means 12 that branches the light into two.
The light modulation means 55 controls whether or not to output according to the signal intensity of the modulation signal or the input light intensity.

The first branched optical signal branched by the optical branching means 12 is output to the output port. On the other hand, the second branched optical signal branched by the optical branching unit 12 enters the operating point control unit 13.
On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detecting means 15, and the light detecting means 15 outputs a signal corresponding to the light intensity. This signal is input to the control means 14.

Such an optical communication apparatus not only operates in the same manner as the optical communication apparatus described in claim 1, but also does not send ASE to the output port when there is no input light.
The light modulation means 55 determines whether or not the input light to be input is below a predetermined light intensity. Alternatively, it is determined whether the signal strength of the modulation signal is equal to or lower than a predetermined signal strength. As a result, when the input light is less than or equal to the predetermined light intensity, or when the signal intensity of the modulation signal is less than or equal to the predetermined signal intensity, the light modulation means 55 eliminates the output. For example, the output can be eliminated by not supplying energy to the light modulation means 55. Alternatively, in the case of an MZ modulator, the output can be eliminated by shifting the phases of input light branched into two optical waveguides in the MZ modulator to create a phase difference of 180 degrees. Alternatively, in the case of a light modulation means using an acoustooptic effect, the output can be eliminated by applying an RF signal that selects a wavelength other than the wavelength of the input light. For this reason, the optical communication apparatus having such a configuration does not output the input light that is not modulated by the ASE and the modulation signal to the output port even when there is input light and no modulation signal.

Of course, when the input light becomes larger than the predetermined light intensity to use the light modulation means 55 or the modulation signal becomes larger than the predetermined signal intensity, the light modulation means 55 normally operates as the modulation means.
(Claim 12)
FIG. 10 is a block diagram of an optical communication apparatus according to a twelfth aspect.

In FIG. 10, this optical communication apparatus includes optical branching means 10 and 12, optical modulation means 11, operating point control means 13, control means 14, light detection means 15, optical attenuation means 31, attenuation control means 41, and modulation signal. The detection means 42 is comprised.
FIG. 10 shows a configuration in the case where the light detection means 15 detects input light and the light attenuation means 31 is inserted between the light branching means 10 and the light modulation means 11. On the other hand, the configuration in the case where the light detection means 15 detects the output light is illustrated by a broken line in FIG. The configuration in the case where the optical attenuating means 31 is connected between the optical modulating means 11 and the optical branching means 12 is illustrated by a broken line in FIG. And about these cases, the description is abbreviate | omitted.

Further, the same components as those in claim 1 or claim 8 are given the same reference numerals, and description thereof is omitted.
The input light input to the input port is branched by the light branching means 10, and the branched first branched input light is incident on the light modulating means 11 via the light attenuating means 31. The incident light is modulated by the light modulator 11, and the modulated modulated optical signal is branched by the light splitter 12.

The first branched optical signal branched by the optical branching means 12 is output to the output port. On the other hand, the second branched optical signal branched by the optical branching unit 12 enters the operating point control unit 13.
On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detection means 15, and a signal corresponding to the light intensity is output. A signal corresponding to the light intensity is input to the control means 14.

Further, the modulation signal to be transmitted is not only input to the optical modulation means 11, but also input to the modulation signal detection means 42, whereby the signal strength of the modulation signal is detected. A signal corresponding to the signal strength is output. This output signal is input to the attenuation amount control means 41.
In this way, it is possible to detect whether or not the input light is below a predetermined light intensity by the light detection means 15. For this reason, when the input light is less than or equal to a predetermined light intensity, the control unit 14 can control the operating point control unit 13 so that the operating point is stably maintained according to the output of the light detecting unit 15. Therefore, in the optical communication device having such a configuration, the operating point is stably maintained even when there is no input light temporarily.

Of course, when the input light is larger than the predetermined light intensity so as to use the light modulation means 11, no signal is output from the light detection means 15. Therefore, the operating point control means 13 optimally controls the operating point only by the output of the light modulation means 11 incident through the light branching means 12.
Furthermore, it is possible to detect whether or not the modulation signal is below a predetermined signal intensity by the modulation signal detection means 42. For this reason, when the modulation signal is equal to or lower than the predetermined signal strength, the attenuation amount control unit 41 controls the attenuation unit 31 according to the output of the modulation signal detection unit 42 to transmit the input light to the light modulation unit 11. The light intensity can be attenuated and input. Alternatively, it can be sent to a terminal not connected to the light modulation means 11. Therefore, the optical communication apparatus having such a configuration does not send ASE to the output port when there is no input light. Furthermore, even when there is input light and no modulation signal, input light that is not modulated by the ASE and the modulation signal is not output to the output port.

  Of course, when there is information to be communicated and the modulation signal to be transmitted becomes larger than a predetermined signal strength, no signal is output from the modulation signal detecting means 42. At this time, the attenuation amount control unit 41 controls the optical attenuation unit 31 so that the input light is transmitted or switched to a terminal connected to the optical modulation unit 11.

(Claim 13)
FIG. 11 is a block diagram of an optical communication apparatus according to a thirteenth aspect.
In FIG. 11, this optical communication apparatus comprises optical branching means 10 and 12, optical modulation means 11, operating point control means 13, control means 14, light detection means 15, modulation signal detection means 42, and modulation control means 45. Is done.

FIG. 11 shows a configuration when the light detection means 15 detects input light. On the other hand, the configuration in the case where the light detection means 15 detects the output light is indicated by a broken line in FIG.
Further, the same components as those in claim 1 or claim 9 are denoted by the same reference numerals, and the description thereof is omitted.

The input light input to the input port is branched by the optical branching means 10, and the branched first branched input light is incident on the light modulating means 11. The incident light is modulated by the light modulation means 11, and the modulated optical signal that has been modulated is branched by the light branching means 12.
The first branched optical signal branched by the optical branching means 12 is output to the output port. On the other hand, the second branched optical signal branched by the optical branching unit 12 enters the operating point control unit 13.

On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detection means 15, and a signal corresponding to the light intensity is output. A signal corresponding to the light intensity is input to the control means 14.
Further, the modulation signal to be transmitted is input not only to the optical modulation means 11 but also to the modulation signal detection means 42. The modulation signal detection means 42 outputs a signal corresponding to the signal strength, and the output signal is input to the modulation control means 45.

  In this way, it is possible to detect whether or not the input light is below a predetermined light intensity by the light detection means 15. For this reason, when the input light is less than or equal to a predetermined light intensity, the control unit 14 can control the operating point control unit 13 so that the operating point is stably maintained according to the output of the light detecting unit 15. Therefore, in the optical communication device having such a configuration, the operating point is stably maintained even when there is no input light temporarily.

Of course, when the input light is larger than the predetermined light intensity so as to use the light modulation means 11, no signal is output from the light detection means 15. Therefore, the operating point control means 13 is the optical branching means 1.
The operating point is optimally controlled only by the output of the light modulation means 11 incident through the light source 2.
Furthermore, it is possible to detect whether or not the modulation signal is below a predetermined signal intensity by the modulation signal detection means 42. For this reason, when the modulation signal is equal to or lower than the predetermined signal strength, the modulation control means 45 can eliminate the output by controlling the light modulation means 11. For this reason, the optical communication apparatus having such a configuration does not output the input light that is not modulated by the ASE and the modulation signal to the output port even when there is input light and no modulation signal.

Of course, when there is information to be communicated and the modulation signal to be transmitted becomes larger than a predetermined signal strength, no signal is output from the modulation signal detecting means 42. At this time, the optical modulation unit 11 does not receive a signal from the modulation control unit 45, and thus operates normally as a modulation unit.
(Claim 14)
FIG. 12 is a block diagram of an optical communication apparatus according to a fourteenth aspect.

In FIG. 12, this optical communication apparatus includes optical branching means 10, 12, optical modulation means 11, operating point control means 13, control means 14, light detection means 15, optical attenuation means 31, attenuation control means 61, and modulation signal. The detection means 42 is comprised.
FIG. 10 shows a configuration in the case where the light detection means 15 detects input light and the light attenuation means 31 is inserted between the light branching means 10 and the light modulation means 11. On the other hand, the configuration in the case where the light detection means 15 detects the output light is illustrated by a broken line in FIG. The configuration in the case where the optical attenuating means 31 is connected between the optical modulating means 11 and the optical branching means 12 is illustrated by a broken line in FIG. And about these cases, the description is abbreviate | omitted.

Further, the same components as those in claim 1 or claim 8 are given the same reference numerals, and description thereof is omitted.
The input light input to the input port is branched by the light branching means 10, and the branched first branched input light is incident on the light modulating means 11 via the light attenuating means 31. The incident light is modulated by the light modulation means 11, and the modulated optical signal is branched by the light branching means 12.

The first branched optical signal branched by the optical branching means 12 is output to the output port. On the other hand, the second branched optical signal branched by the optical branching unit 12 enters the operating point control unit 13.
On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detection means 15, and a signal corresponding to the light intensity is output. A signal corresponding to the light intensity is input to the control unit 14 and the attenuation amount control unit 61.

Further, the modulation signal to be transmitted is not only input to the optical modulation means 11, but also input to the modulation signal detection means 42, whereby the signal strength of the modulation signal is detected. An output signal corresponding to the signal strength is input to the attenuation amount control means 61.
The attenuation amount control unit 61 controls the light attenuation unit 31. That is, the attenuation amount control means 61 takes the sum of the signal from the light detection means 15 and the signal from the modulation signal detection means 42 and controls the light attenuation means 31 to attenuate the input light to a predetermined light intensity. Alternatively, when the light attenuation means 31 is an optical switch, the attenuation amount control means 41 switches the input light to an output terminal to which nothing is connected in accordance with the signal of the light detection means 33 and sends it out.

  In this way, it is possible to detect whether or not the input light is below a predetermined light intensity by the light detection means 15. Therefore, when the input light is below a predetermined light intensity, the control unit 14 can control the operating point control unit 13 so as to maintain the operating point stably in accordance with the output of the light detecting unit 15. Therefore, in the optical communication device having such a configuration, the operating point is stably maintained even when there is no input light temporarily.

Of course, when the input light is larger than the predetermined light intensity so as to use the light modulation means 11, no signal is output from the light detection means 15. Therefore, the operating point control means 13 optimally controls the operating point only by the output of the light modulation means 11 incident through the light branching means 12.
Furthermore, it is possible to detect whether or not the modulation signal is below a predetermined signal intensity by the modulation signal detection means 42. The attenuation control means 61 also receives a signal from the light detection means 15 and takes the sum of this signal and the signal from the modulation signal detection means 42. For this reason, when the input light is less than or equal to the predetermined light intensity or when the modulation signal is less than or equal to the predetermined signal intensity, the attenuation amount control means 61 controls the attenuation means 31 to input the input light to the light modulation means 11. The light intensity can be attenuated and input. Alternatively, it can be sent to a terminal not connected to the light modulation means 11. Therefore, the optical communication apparatus having such a configuration does not send ASE to the output port when there is no input light. Furthermore, even when there is input light and no modulation signal, input light that is not modulated by the ASE and the modulation signal is not output to the output port.

Of course, when there is information to be communicated and the modulation signal to be transmitted becomes larger than the predetermined signal intensity, and the input light becomes larger than the predetermined light intensity, the attenuation control means 61 causes the light attenuation means 31 to input the light attenuation means 31. Control is performed so as to transmit or switch to a terminal connected to the light modulation means 11.
(Claim 15)
FIG. 13 is a block diagram of an optical communication apparatus according to a fifteenth aspect.

  In FIG. 13, this optical communication apparatus comprises optical branching means 10 and 12, optical modulation means 11, operating point control means 13, control means 14, light detection means 15, modulation signal detection means 42, and modulation control means 65. Is done.

FIG. 13 shows a configuration when the light detection means 15 detects input light. On the other hand, the configuration in the case where the light detection means 15 detects the output light is indicated by a broken line in FIG.
Further, the same components as those in claim 1 or claim 9 are denoted by the same reference numerals, and the description thereof is omitted.

The input light input to the input port is branched by the optical branching means 10, and the branched first branched input light is incident on the light modulating means 11. The incident light is modulated by the light modulation means 11, and the modulated optical signal is branched by the light branching means 12.
The first branched optical signal branched by the optical branching means 12 is output to the output port. On the other hand, the second branched optical signal branched by the optical branching unit 12 enters the operating point control unit 13.

On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detection means 15, and a signal corresponding to the light intensity is output. A signal corresponding to the light intensity is input to the control unit 14 and the modulation control unit 65.
Further, the modulation signal to be transmitted is input not only to the optical modulation means 11 but also to the modulation signal detection means 42. The modulation signal detection means 42 outputs a signal corresponding to the signal strength, and the output signal is input to the modulation control means 65.

The modulation control means 65 controls the light modulation means 11. That is, the modulation control means 65 controls the input light to be attenuated to a predetermined light intensity by taking the sum of the signal from the light detection means 15 and the signal from the modulation signal detection means 42. For example, the output can be eliminated by not supplying energy to the light modulation means 11. Alternatively, in the case of an MZ modulator, the output can be eliminated by shifting the phases of input light branched into two optical waveguides in the MZ modulator to create a phase difference of 180 degrees. Alternatively, in the case of a light modulation means using an acoustooptic effect, the output can be eliminated by applying an RF signal that selects a wavelength other than the wavelength of the input light.

  In this way, it is possible to detect whether or not the input light is below a predetermined light intensity by the light detection means 15. For this reason, when the input light is less than or equal to a predetermined light intensity, the control unit 14 can control the operating point control unit 13 so that the operating point is stably maintained according to the output of the light detecting unit 15. Therefore, in the optical communication device having such a configuration, the operating point is stably maintained even when there is no input light temporarily.

Of course, when the input light is larger than the predetermined light intensity so as to use the light modulation means 11, no signal is output from the light detection means 15. Therefore, in the operating point control means 13, the operating point is optimally controlled only by the output of the light modulating means 11 that enters via the light branching means 12.
Furthermore, it is possible to detect whether or not the modulation signal is below a predetermined signal intensity by the modulation signal detection means 42. The modulation control means 65 also receives a signal from the light detection means 15 and takes the sum of this signal and the signal from the modulation signal detection means 42. For this reason, when the input light is less than or equal to the predetermined light intensity or the modulation signal is less than or equal to the predetermined signal intensity, the modulation control means 65 can eliminate the output by controlling the light modulation means 11. For this reason, the optical communication apparatus having such a configuration does not output the input light that is not modulated by the ASE and the modulation signal to the output port even when there is input light and no modulation signal.

Of course, when there is information to be communicated and the modulation signal to be transmitted becomes larger than the predetermined signal intensity and the input light becomes larger than the predetermined light intensity, the light detection means 15 does not transmit a signal to the modulation control means 65. . Therefore, the light modulation unit 11 does not receive a signal from the modulation control unit 65 and thus operates normally as a modulation unit.
(Claim 16)
FIG. 14 is a block diagram of an optical add / drop device according to claim 16 and using the optical modulation means of claim 1 as an optical insertion means. A sixteenth aspect of the present invention is an optical branching / inserting device including an optical branching / inserting unit, an optical wavelength branching unit, and an optical inserting unit. 14 is used as an optical insertion means. FIG. 14 shows an optical add / drop apparatus configured using the optical communication apparatus according to claim 1 as the optical insertion means. It is a block diagram.

Hereinafter, the structure of Claim 16 in this case will be described, and the description of other cases will be omitted. Further, the same components as those in claim 1 are denoted by the same reference numerals, and description thereof is omitted.
In FIG. 14, the optical add / drop device comprises an add / drop means 70, an optical wavelength add / drop means 73, and an optical add means 75.

  Note that the optical add / drop device is actually configured to include as many optical wavelength branching means 73 and optical inserting means 75 as the number of wavelengths to be branched or inserted. However, each optical wavelength branching means 73 is the same in configuration only with different reception processing wavelengths, and each optical insertion means 75 is also the same in configuration only with different wavelengths of inserted light. In FIG. 14, only one of the plurality of light branching means 73 and the light inserting means 75 is illustrated by a solid line, and the other is illustrated by a broken line.

The branching / inserting means 70 is connected to an optical transmission line that transmits the wavelength-multiplexed optical signal, and branches and inserts an optical signal having at least one wavelength with respect to the optical signal on the optical transmission line. In the case of branching, the optical signal is branched to the optical wavelength branching unit 73 via the optical distribution unit 72 that distributes the optical signal according to the number of the optical wavelength branching units 73. In the case of insertion, the light inserted from each optical adder 75 is multiplexed by the optical multiplexer 74, and the optical signal transmitted through this optical add / drop device is wavelength-multiplexed and sent to the optical transmission line.

The optical wavelength branching means 73 receives and processes the distributed optical signal for each wavelength. On the other hand, the optical insertion means 75 generates insertion light to be inserted into an optical signal on the optical transmission path.
Hereinafter, the configuration of the light inserting means 75 will be described.
The light insertion means 75 includes light branching means 10 and 12, light modulation means 11, operating point control means 13, control means 14, and light detection means 15.

Input light of a specific wavelength input to the input port is branched by the optical branching means 10. The first branched input light branched by the optical branching means 10 is modulated by the optical modulation means 11, and the modulated modulated optical signal is branched by the optical branching means 12. It should be noted that the specific wavelength is different between the respective light inserting means 75.
The first branched optical signal branched by the optical branching unit 12 is output to the output port and enters the optical multiplexing unit 74. On the other hand, the second branched optical signal branched by the optical branching unit 12 enters the operating point control unit 13 that controls the operating point of the optical modulation unit 11.

On the other hand, the light intensity of the second branched input light branched by the light branching means 10 is detected by the light detection means 15, and the light detection means 15 outputs a signal corresponding to the light intensity and inputs it to the control means 14. Is done.
In this way, it is possible to detect whether or not the input light is below a predetermined light intensity by the light detection means 15. For this reason, when the input light is less than or equal to a predetermined light intensity, the control unit 14 can control the operating point control unit 13 so that the operating point is stably maintained according to the output of the light detecting unit 15. Therefore, in the optical branching / inserting device having such a configuration, since the insertion light is not supplied to the branching / inserting unit 70, even when there is no input light of the optical inserting unit 75, the operating point of the optical inserting unit 75 is Maintains stability.
Of course, when the input light becomes larger than a predetermined light intensity so as to generate insertion light by the light insertion means 75, no signal is output from the light detection means 15. Therefore, the operating point control means 13 optimally controls the operating point only by the output of the light modulation means 11 incident through the light branching means 12.

In the first to fifth aspects of the invention, since the input light or output of the light modulation means and the modulation signal are monitored, even if the input light or the modulation signal is temporarily not in the optical communication device, the light modulation means The operating point can be kept stable.
In the inventions according to claims 6 to 9, since the input light or output of the optical modulation means and the modulation signal are monitored, even if the input light or modulation signal is temporarily absent in the optical communication device, the ASE and Input light that is not modulated by the modulation signal is not output.
Furthermore, in the inventions according to claims 10 to 15, since the input light or output of the light modulation means and the modulation signal are monitored, even if the input light or modulation signal is temporarily absent in the optical communication device, the light modulation is performed. The operating point of the means can be kept stable and does not output input light that is not modulated by the ASE and modulation signals.
Further, in the optical branching / inserting device according to claim 16, even when there is an unused insertion device, the input light or output of the optical modulation means and the modulation signal in the insertion device are monitored. The operating point is kept stable, and input light that is not modulated by the ASE and the modulation signal is not inserted from the insertion device.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Configuration of the first embodiment)
The first embodiment is an embodiment of an optical add / drop device corresponding to the first, third, and sixth aspects of the invention.
FIG. 15 is a block diagram of the optical add / drop device according to the first embodiment.
In FIG. 15, the optical add / drop device includes optical amplifiers 101 and 103, OADM 102, 1 × M optical coupler 104, M optical wavelength branch circuits 105, N × 1 optical coupler 106, and N optical adder circuits 107a. It consists of.

The optical add / drop device includes M optical wavelength branch circuits 105 and N optical add circuits 107a. Since each circuit has the same configuration, FIG. Only one of the optical wavelength branching circuit 105 and the optical insertion circuit 107a is illustrated by a solid line, and the other is illustrated by a broken line.
The wavelength-multiplexed optical signal transmitted through the optical transmission line is input to the optical add / drop device and is amplified by the amplifier 101 that amplifies the signal to a predetermined light intensity. The amplified optical signal enters the OADM 102 that branches and inserts the wavelength multiplexed optical signal. The signal light having a predetermined wavelength branched by the OADM 102 is incident on a 1 × M optical coupler 104 that is distributed by the number of optical branching circuits. The optical signal distributed by the 1 × M optical coupler 104 is incident on an optical wavelength branch circuit 105 that receives and processes a wavelength multiplexed optical signal for each wavelength, and is subjected to reception processing. The optical signal inserted by the OADM 102 is generated by the optical insertion circuit 107a. The optical insertion circuit 107 a is prepared with N pieces which are the number of optical signals to be inserted in the OADM 102. The inserted optical signal and the optical signal transmitted without being branched by the OADM 102 are wavelength-multiplexed, amplified by the optical amplifier 103, and transmitted to the optical transmission line.

  On the other hand, the optical insertion circuit 107a includes a laser diode bank (hereinafter abbreviated as “LD bank”) 110, an optical amplifier 111, 115, an optical branching device 112, 114, an MZ modulator 113, a PD 116, 123, an amplifier 117, 121, a comparator 118, a switch 119, a variable gain amplifier 120, a coupling capacitor 122, a buffer amplifier 124, a multiplier 125, an LPF 126, a differential amplifier 127, an inductor 128, a capacitor 129, a resistor 130, and a low-frequency oscillator 131. Is done.

A circuit composed of a variable gain amplifier 120, an amplifier 121, a coupling capacitor 122, a PD 123, a buffer amplifier 124, a multiplier 125, an LPF 126, a differential amplifier 127, an inductor 128, a capacitor 129, a resistor 130, and a low-frequency oscillator 131. It will be called an operating point control circuit.
In FIG. 15, the LD bank 110 can emit laser beams having a plurality of wavelengths L1 to L8 corresponding to the wavelength-multiplexed wavelengths. Which wavelength is emitted is determined by a wavelength monitor (not shown in FIG. 15). A free wavelength of the optical transmission line is detected, and a wavelength to emit light is selected according to the detection signal. For example, the LD bank 110 emits light having a wavelength L 2 and enters the optical amplifier 111. The amplified light is branched into two lights by the optical branching device 112, and the branched first light is incident on the MZ modulator 113.

  Further, the modulation signal and the low frequency signal of the predetermined frequency f 0 output from the low frequency oscillator 131 are input to the variable gain amplifier 120. The variable gain amplifier 120 modulates the amplitude of the input signal with a low frequency signal and outputs the result. This output signal is input to one modulation input terminal of the MZ modulator 113 via an amplifier 121 that obtains a predetermined signal level and a coupling capacitor 122.

The other modulation input terminal of the MZ modulator 113 is connected to a bias T circuit and a resistor 130 including an inductor 128 and a capacitor 129.
The MZ modulator 113 modulates the light of the wavelength L2 of the LD bank with a signal given from the drive circuit, converts it into an optical signal, and outputs it.
A part of the output light from the MZ modulator 113 is branched and extracted by the optical branching device 114, and the other output light is amplified by the optical amplifier 115 and incident on the N × 1 optical coupler. Part of the branched output light is detected by the PD 123, and this detection signal is amplified by the buffer amplifier 124 that selectively amplifies the frequency component of f 0 and is input to the multiplier 125. The multiplier 125 receives the low frequency signal output from the low frequency oscillator 131, compares the phase of the input signal from the buffer amplifier 124 and the low frequency signal from the low frequency oscillator 131, and determines the phase difference. A corresponding signal is output. The multiplier 125 detects a low frequency signal having a predetermined frequency f 0 superimposed by the variable gain amplifier 120.

  The output signal of the multiplier 125 is input to one input terminal of the differential amplifier 127 via the LPF 126 and a switch 119 that pass a frequency equal to or lower than a predetermined frequency f0. On the other hand, the other input terminal of the differential amplifier 127 is grounded. The output of the differential amplifier 127 is input to the inductor 128 of the bias T circuit as an error signal for moving the operating point, and the bias value is variably controlled so as to correct the operating point.

On the other hand, the second light branched by the optical splitter 112 enters the PD 116 and outputs an electrical signal proportional to the average light intensity of the second light. That is, the PD 116 detects the light intensity of the light emitted from the LD bank.
This electric signal is amplified by the amplifier 117 and compared with the reference voltage Vref by the comparator 118. When the electrical signal is equal to or lower than the reference voltage Vref, the comparator 118 outputs a signal to the switch 119 to control on / off of the switch 119.

When the switch 119 receives a signal from the comparator 118, the switch 119 is turned off to disconnect the connection between the LPF 126 and the differential amplifier 127. Further, the switch 119 is turned on while the signal from the comparator 118 is not received, and the LPF 126 and the differential amplifier 127 are connected.
(Correspondence between the present invention and the first embodiment)
With respect to the correspondence relationship between the first and third embodiments of the present invention, the branching / insertion means includes optical amplifiers 101 and 103, OADM 102, 1 × M optical coupler 104, and N × 1 optical coupler 106. The optical wavelength branching means corresponds to the optical wavelength branching circuit 105, and the optical insertion means corresponds to the optical insertion circuit 107a.

  Further, regarding the optical add-in circuit 107a, the first branching means corresponds to the optical branching unit 112, the light modulating unit corresponds to the MZ modulator 113, the light detecting unit corresponds to the PD 116, and the control unit is compared with the amplifier 117. The second optical branching unit corresponds to the optical branching unit 114, and the operating point control unit corresponds to the operating point control circuit.

(Operational effects of the first embodiment)
In the optical add / drop device configured as described above, there is no input light while changing the wavelength at which the LD emits light in the optical adder circuit 107a, for example, while changing the laser light of wavelength L2 to the laser light of wavelength L4. The operating point can be maintained stably.
This will be described below in the case of the wavelengths L2 to L4.

First, since the vacant wavelength of the wavelength multiplexed signal transmitted through the optical transmission line is L2, the LD bank emits light of wavelength L2. The light emitted at this time is modulated by the MZ modulator, inserted by the OADM 102 via the N × 1 optical coupler 106 as insertion light, and transmitted to the optical transmission line. The emitted light enters the operating point control circuit and is used to control the operating point of the MZ modulator. Further, the emitted light is photoelectrically converted by the PD 116, and the output signal from the PD is determined by the comparator 118 whether or not it is equal to or lower than the reference voltage Vref. That is, whether or not the light intensity of the wavelength L2 emitted from the LD bank 110 is equal to or lower than the predetermined light intensity is determined by determining whether or not the electric signal from the PD 116 is equal to or lower than the predetermined reference voltage Vref. It can be determined whether or not.

  Since the light of the wavelength L2 emitted from the LD bank 110 is used as insertion light, the comparator 118 does not emit a signal because it is greater than a predetermined light intensity. Therefore, the switch 119 is kept on, and the connection state is maintained between the LPF 126 and the differential amplifier 127. For this reason, the operating point control circuit continues to operate normally.

Next, since the vacant wavelength of the wavelength multiplexed signal transmitted through the optical transmission line is changed from L2 to L4, the LD bank 110 stops emitting light of wavelength L2.
At this time, the output signal of the PD 116 decreases to almost zero. For this reason, since this output signal is equal to or lower than the reference voltage Vref, the comparator 118 transmits the signal to the switch 119. Therefore, the switch 119 is turned off, and the connection between the LPF 126 and the differential amplifier 127 is cut off. As a result, the operating point control circuit stops operating, and the operating point is in an initial state and is maintained in a range that can be controlled by the operating point control circuit. Therefore, the operating point does not enter an indefinite state.

  Thereafter, the LD bank 110 emits light of wavelength L4. At this time, the output signal of the PD 116 rises and outputs the same level as in the case of the wavelength L2. For this reason, since this output signal becomes larger than the reference voltage Vref, the comparator 118 does not transmit a signal. Therefore, the switch 119 is turned on, and the LPF 126 and the differential amplifier 127 are connected. At this time, the operating point control circuit controls the operating point from the initial state, and thus can operate normally.

In the above description, the case where the LD bank 110 stops temporary light emission in order to change the light emission wavelength has been described. However, in order to use another optical insertion circuit in the optical add / drop multiplexer, light emission is performed. Similarly, when stopping, the operating point can be stably maintained.
Next, another embodiment will be described.

(Configuration of Second Embodiment)
The second embodiment is an embodiment of an optical add / drop device corresponding to the invention of claims 2, 3, 16.
FIG. 16 is a block diagram of an optical add / drop device according to the second embodiment.
Note that in the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

In FIG. 16, the optical add / drop devices include optical amplifiers 101 and 103, OADM 102, 1 × M optical coupler 104, M optical wavelength branch circuits 105, N × 1 optical coupler 106, and N optical adder circuits 107b. It consists of.
The optical add / drop device includes M optical wavelength branch circuits 105 and N optical add circuits 107b. Since each circuit has the same configuration, FIG. Only one of the optical wavelength branching circuit 105 and the optical insertion circuit 107b is illustrated by a solid line, and the other is illustrated by a broken line.

The wavelength-multiplexed optical signal transmitted through the optical transmission line is input to the optical add / drop device and enters the OADM 102 via the optical amplifier 101. The signal light having a predetermined wavelength branched by the OADM 102 is distributed by the 1 × M optical coupler 104, enters the optical wavelength branch circuit 105, and is received and processed. The optical signal inserted by the OADM 102 is generated by the optical insertion circuit 107b. The optical insertion circuit 107b is prepared with N pieces which are the number of optical signals to be inserted in the OADM 102. The inserted optical signal and the optical signal transmitted without being branched by the OADM 102 are wavelength-multiplexed and sent to the optical transmission line via the optical amplifier 103.

  On the other hand, the optical add-in circuit 107b includes an LD bank 110, optical amplifiers 111 and 115, an optical branching device 140, an MZ modulator 113, PDs 123 and 141, a buffer amplifier 124, amplifiers 121 and 142, a comparator 143, switches 144 and 148, Variable gain amplifier 120, coupling capacitor 122, multiplier 125, LPF 126, differential amplifier 127, inductor 128, capacitors 129 and 151, resistors 130, 145 and 146, low frequency oscillator 131, field effect transistor (hereinafter “FET”) 147, 149 and operational amplifiers 150, 152.

In FIG. 16, the laser light emitted from the LD bank 110 is incident on the MZ modulator 113 via the optical amplifier 111.
Further, the modulation signal and the low frequency signal of the predetermined frequency f 0 output from the low frequency oscillator 131 are input to the variable gain amplifier 120. This output signal is input to one modulation input terminal of the MZ modulator 113 via the amplifier 121 and the coupling capacitor 122.

The other modulation input terminal of the MZ modulator 113 is connected to a bias T circuit and a resistor 130 including an inductor 128 and a capacitor 129.
The MZ modulator 113 modulates light from the LD bank 110, for example, laser light having a wavelength L2, with a signal supplied from the drive circuit, converts the light into an optical signal, and outputs the optical signal.
The output light from the MZ modulator 113 is branched into three by the optical branching unit 140. The first branched output light is incident on the PD 123. The second branched output light is incident on the PD 141. The third output light is incident on the aforementioned N × 1 optical coupler 106 via the optical amplifier 115. The first branched output light is detected by the PD 123, and this detection signal is input to the multiplier 125 via the buffer amplifier 124. The multiplier 125 receives the low frequency signal output from the low frequency oscillator 131, compares the phase of the input signal from the buffer amplifier 124 and the low frequency signal from the low frequency oscillator 131, and determines the phase difference. A corresponding signal is output.

  The output signal of the multiplier 125 is input to the LPF 126. The output is input to one input terminal of the differential amplifier 127 and the non-inverting input terminal (+) of the operational amplifier 152 via the switch 144. On the other hand, the other input terminal of the differential amplifier 127 is grounded. The output of the differential amplifier 127 is input to the inductor 128 of the bias T circuit, and the bias value is variably controlled so as to correct the operating point.

The output of the operational amplifier 152 is input to the drain terminal of the FET 147 and the source terminal of the FET 149.
The gate terminal of the FET 147 is controlled by a switch 148 and is connected to the power source Vcc via the switch 148. The source terminal is connected to the inverting input terminal (−) of the operational amplifier 152 via the resistor 145 and is connected to the inverting input terminal (−) of the operational amplifier 150 via the resistor 146.

The gate terminal of the FET 149 is controlled by a switch 148 and is connected to the power source Vcc via the switch 148. The drain terminal is grounded via a capacitor 151 and is connected to the non-inverting input terminal (+) of the operational amplifier 150.
A circuit composed of the operational amplifiers 150 and 152, the FETs 147 and 149, the resistors 145 and 146, and the capacitor 151 is a holding circuit that holds the output voltage of the LPF 126.

On the other hand, the second branched output light is detected by the PD 141, and the PD 141 outputs an electric signal proportional to the average light intensity. That is, the PD 141 detects the light intensity of the light emitted from the LD bank 110 by monitoring the output light of the MZ modulator 113.
The electric signal from the PD 141 is amplified by the amplifier 142 and compared with the reference voltage Vref by the comparator 143. When the electrical signal is equal to or lower than the reference voltage Vref, the comparator 143 outputs a signal to the switch 144 and the switch 148 and controls them.

  The switch 144 can switch between connecting the LPF 126 and the differential amplifier 127 or connecting the output terminal of the operational amplifier 150 and the differential amplifier 127. The switch 144 is normally switched so as to connect the LPF 126 and the differential amplifier 127. However, when the signal is received from the comparator 143, the switch 144 is switched so as to connect the output terminal of the operational amplifier 150 and the differential amplifier 127. . Further, when the switch 144 stops receiving a signal from the comparator 143, the switch 144 connects the LPF 126 and the differential amplifier 127 again.

  In addition, the switch 148 controls on / off of the FET 147 and on / off of the FET 149 in accordance with a signal from the comparator 143. That is, while no signal is received from the comparator 143, the FET 149 is turned on and the FET 147 is turned off by connecting the power supply Vcc and the gate terminal of the FET 149. On the other hand, when a signal is received from the comparator 143, the FET 149 is turned off and the FET 147 is turned on by connecting the power source Vcc and the gate terminal of the FET 147.

(Correspondence between the present invention and the second embodiment)
As for the correspondence relationship between the invention described in claims 2, 3, and 16 and the second embodiment, branching / insertion means are optical amplifiers 101, 103, OADM 102, 1 × M optical coupler 104, and N × 1 optical coupler 106. The optical wavelength branching means corresponds to the optical wavelength branching circuit 105, and the optical insertion means corresponds to the optical insertion circuit 107b.

Further, regarding the optical insertion circuit 107b, the optical modulation means corresponds to the MZ modulator 113, the optical branching means corresponds to the optical branching device 140, the light detection means corresponds to the PD 141, and the operating point control means is the operating point control circuit. The control means corresponds to a portion including an amplifier 142, a comparator 143, switches 144 and 149, and a holding circuit.
(Operational effects of the second embodiment)
In the optical add / drop device configured as described above, the input light is received while changing the wavelength emitted by the LD bank 110 in the optical adder circuit 107b, for example, while changing the laser light having the wavelength L2 to the laser light having the wavelength L4. Even if it disappears, the operating point of the MZ modulator 113 can be maintained stably.

The case where this is changed from the wavelength L2 to the wavelength L4 will be described below.
First, since the vacant wavelength of the wavelength multiplexed signal transmitted through the optical transmission line is L2, the LD bank 110 emits light of wavelength L2. The light emitted at this time is modulated by the MZ modulator 113, inserted as an insertion light by the OADM 102 via the N × 1 optical coupler 106, and transmitted to the optical transmission line. The emitted light is incident on the operating point control circuit via the optical modulator 113 and is used to control the operating point of the MZ modulator 113. Further, the emitted light is photoelectrically converted by the PD 141 via the MZ modulator 113 and the like, and the output signal from the PD 141 is determined by the comparator 143 to determine whether it is equal to or lower than the reference voltage Vref. That is, by determining whether the electric signal from the PD 141 is equal to or lower than the predetermined reference voltage Vref by the comparator 143, whether the light intensity of the wavelength L2 emitted from the LD bank 110 is equal to or lower than the predetermined light intensity. It can be determined whether or not.

Since the light of wavelength L2 emitted from the LD bank 110 is used as insertion light, the comparator 143 does not emit a signal because it is greater than a predetermined light intensity. Therefore, switch 144
The connection state is maintained between the LPF 126 and the differential amplifier 127. For this reason, the operating point control circuit continues to operate normally. The switch 148 turns off the FET 147 and turns on the FET 149. For this reason, the output voltage of the LPF 126 is stored in the capacitor 151.

Next, since the vacant wavelength of the wavelength multiplexed signal transmitted through the optical transmission line is changed from L2 to L4, the LD bank 110 stops emitting light of wavelength L2.
At this time, the output signal of the PD 116 decreases to almost zero. For this reason, since this output signal is equal to or lower than the reference voltage Vref, the comparator 143 transmits the signal to the switches 144 and 148. Therefore, the switch 144 switches from the connection state between the LPF 126 and the differential amplifier 127 to the connection state between the output terminal of the operational amplifier 150 and the differential amplifier 127. The switch 148 turns on the FET 147 and turns off the FET 149. Therefore, the same voltage as the LPF 126 stored in the capacitor 151 is output to the output terminal of the operational amplifier 150. As a result, the differential amplifier 127 maintains the state immediately before the LD bank 110 stops emitting light of wavelength L2. Therefore, the operating point does not enter an indefinite state.

  Thereafter, the LD bank 110 emits light of wavelength L4. At this time, the output signal of the PD 141 rises and outputs the same level as in the case of the wavelength L2. For this reason, since this output signal becomes larger than the reference voltage Vref, the comparator 142 does not transmit a signal. Therefore, the switch 144 switches from the connection state between the output terminal of the operational amplifier 150 and the differential amplifier 127 to the connection state between the LPF 126 and the differential amplifier 127 again. Therefore, the operating point control circuit controls the operating point of the MZ modulator 113 by the optical signal from the optical modulator 113 incident on the operating point control circuit as usual.

In addition, since the operating point control circuit maintains the state immediately before switching from the laser light of the wavelength L2 to the laser light of the wavelength L4, the operating point is set earlier than when the control of the operating point is started from the initial state. Can be compensated.
In the above description, the case where the LD bank 110 stops temporary light emission in order to change the light emission wavelength has been described. However, in order to use another optical insertion circuit in the optical add / drop multiplexer, light emission is performed. Similarly, when stopping, the operating point can be stably maintained.

Next, another embodiment will be described.
(Third embodiment)
The third embodiment is an embodiment of an optical add / drop device corresponding to the invention described in claims 4, 5, 16.
FIG. 17 is a block diagram of an optical add / drop device according to the third embodiment.

In FIG. 17, an optical add / drop device includes optical amplifiers 101 and 103, an OADM 102, a 1 × M optical coupler 104, M optical wavelength branch circuits 105, an N × 1 optical coupler 106, and N optical adder circuits 107c. It consists of.
The optical add / drop device includes M optical wavelength branch circuits 105 and N optical add circuits 107c. Since each circuit has the same configuration, FIG. Only one of the optical wavelength branch circuit 105 and the optical insertion circuit 107c is illustrated by a solid line, and the other is illustrated by a broken line.

Moreover, about the structure same as 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
The wavelength-multiplexed optical signal transmitted through the optical transmission path is input to the optical add / drop device, is amplified by the optical amplifier 101, and enters the OADM 102. The signal light having a predetermined wavelength branched by the OADM 102 enters the 1 × M optical coupler 104. The optical signal distributed by the 1 × M optical coupler 104 enters the optical wavelength branch circuit 105 and is received and processed. The optical signal inserted by the OADM 102 is generated by the optical insertion circuit 107c. The inserted optical signal and the optical signal transmitted without being branched by the OADM 102 are wavelength-multiplexed, amplified by the optical amplifier 103, and transmitted to the optical transmission line.

  On the other hand, the optical adder circuit 107c includes an LD bank 110, optical amplifiers 111 and 115, an optical splitter 114, an MZ modulator 113, a PD 123, amplifiers 121 and 162, a buffer amplifier 124, a comparator 163, a switch 164, and a variable gain amplifier 120. A coupling capacitor 122, a multiplier 125, an LPF 126, a differential amplifier 127, an inductor 128, a capacitor 129, resistors 130 and 161, and a low-frequency oscillator 131.

In FIG. 17, the laser light emitted from the LD bank 110 enters the MZ modulator 113 via the optical amplifier 111.
Further, the modulation signal and the low frequency signal of the predetermined frequency f 0 output from the low frequency oscillator 131 are input to the variable gain amplifier 120. This output signal is input to one modulation input terminal of the MZ modulator 113 via the amplifier 121 and the coupling capacitor 122.

The other modulation input terminal of the MZ modulator 113 is connected to a bias T circuit and a resistor 130 including an inductor 128 and a capacitor 129.
The MZ modulator 113 modulates the light of the wavelength L2 of the LD bank 110 with a signal given from the drive circuit, converts it to an optical signal, and outputs it.
A part of the output light from the MZ modulator 113 is branched and extracted by the optical branching device 114, and the other output light is incident on the N × 1 optical coupler 106 through the optical amplifier 115. Part of the branched output light is detected by the PD 123, and this detection signal is input to the multiplier 125 via the buffer amplifier 124. The multiplier 125 receives the low frequency signal output from the low frequency oscillator 131, compares the phase of the input signal from the buffer amplifier 124 and the low frequency signal from the low frequency oscillator 131, and determines the phase difference. A corresponding signal is output.

  The output signal of the multiplier 125 is input to one input terminal of the differential amplifier 127 via the LPF 126 and the switch 164. On the other hand, the other input terminal of the differential amplifier 127 is grounded. The output of the differential amplifier 127 is input to the inductor 128 of the bias T circuit, and the bias value is variably controlled so as to correct the operating point.

On the other hand, the modulation signal is connected to one terminal of the diode 160, and the other terminal of the diode 160 is grounded via the resistor 161. The modulation signal is half-wave rectified by the diode 160, and a voltage corresponding to the signal strength of the modulation signal is detected across the resistor 161.
The voltage corresponding to the signal strength of the modulation signal is amplified by the amplifier 162 and compared with the reference voltage Vref by the comparator 163. When the electric signal is equal to or lower than the reference voltage Vref, the comparator 163 outputs a signal to the switch 164 and controls the switch 164.

  The switch 164 can switch between connecting the LPF 126 and the differential amplifier 127 or connecting the reference voltage V 1 and the differential amplifier 127. The switch 164 is normally switched so as to connect the LPF 126 and the differential amplifier 127, but when receiving a signal from the comparator 163, the switch 164 switches so as to connect the reference voltage V 1 and the differential amplifier 127. Further, when the switch 164 stops receiving a signal from the comparator 163, the switch 164 connects the LPF 126 and the differential amplifier 127 again.

The reference voltage V1 is a voltage value in a range in which the operating point can be controlled in the operating point control circuit.
(Correspondence relationship between the present invention and the third embodiment)
Regarding the correspondence relationship between the invention described in claims 4, 5, and 16 and the third embodiment, the branching / insertion means are optical amplifiers 101, 103, OADM 102, 1 × M optical coupler 104, and N × 1 optical coupler 106. The optical wavelength branching means corresponds to the optical wavelength branching circuit 105, and the optical insertion means corresponds to the optical insertion circuit 107c.

  Further, with respect to the optical adder circuit 107c, the optical modulation means corresponds to the MZ modulator 113, the optical branching means corresponds to the optical branching device 114, the operating point control means corresponds to the operating point control circuit, and the modulation signal detection means includes The control means corresponds to a portion comprising the diode 160 and the resistor 161, and the control means corresponds to a portion comprising the amplifier 162, the comparator 163, the switch 164 and the reference voltage V1.

(Operational effect of the third embodiment)
In the optical add / drop device having such a configuration, the operating point can be stably maintained even when there is no modulation signal to be transmitted in the optical add circuit 107.
For example, the operation of the optical add-in circuit 107c when there is a case where the modulated signal is present and not present again will be described below.

First, the modulation signal to be transmitted modulates the input light from the LD bank 110 by the MZ modulator 113. The modulated input light is inserted as insertion light by the OADM 102 via the N × 1 optical coupler 106 and transmitted to the optical transmission line.
Further, the signal strength of the modulation signal is detected by the diode 160 and the resistor 161, and the voltage corresponding to the signal strength of the modulation signal is determined by the comparator 163 to determine whether it is equal to or lower than a predetermined reference voltage Vref. That is, it is determined whether or not the signal strength of the modulation signal is equal to or lower than a predetermined signal strength.

  Since there is a modulation signal to be sent now, the comparator 163 does not send the signal to the switch 164. For this reason, the switch 164 switches to connect the LPF 126 and the differential amplifier 127. Therefore, since the operating point control circuit operates as usual, the operating point of the MZ modulator 113 can be controlled by the optical signal from the MZ modulator 113 incident on the operating point control circuit.

Next, because there is no signal to be inserted in this optical add / drop device, or because an optical insertion circuit other than this optical insertion circuit is used among N optical insertion circuits, the modulation signal is lost. .
At this time, the voltage value of the resistor 161 decreases and becomes almost zero. For this reason, since this voltage value is equal to or lower than the reference voltage Vref, the comparator 163 transmits a signal to the switch 164. Therefore, the switch 164 switches from the connection state between the LPF 126 and the differential amplifier 127 to the connection state between the reference voltage V 1 and the differential amplifier 127. As a result, the operating point control circuit maintains the operating point at the reference voltage V1. Therefore, the operating point does not enter an indefinite state.

  Thereafter, when a modulation signal to be transmitted again is generated, a voltage is generated in the resistor 161. For this reason, since this voltage value becomes larger than the reference voltage Vref, the comparator 163 does not transmit a signal. Therefore, the switch 164 switches from the connection state between the reference voltage V1 and the differential amplifier 127 to the connection state between the LPF 126 and the differential amplifier 127 again. Therefore, the operating point control circuit controls the operating point of the MZ modulator 113 by the optical signal from the MZ modulator 113 incident on the operating point control circuit as usual from the state of the reference voltage V1.

At this time, if the reference voltage is appropriately selected in consideration of the temperature when the MZ modulator 113 is operating, the operating point is compensated earlier than when the operating point control is started from the initial state. be able to.
Next, another embodiment will be described.
(Fourth embodiment)
The fourth embodiment is an embodiment of an optical add / drop device corresponding to the invention described in claims 1, 3, 6, 8, 10, 12, 14, 16.

FIG. 18 is a block diagram of an optical add / drop device according to the fourth embodiment.
In FIG. 18, the optical add / drop device includes optical amplifiers 101 and 103, OADM 102, 1 × M optical coupler 104, M optical wavelength branch circuits 105, N × 1 optical coupler 106, and N optical adder circuits 107d. It consists of.
The optical add / drop device includes M optical wavelength branch circuits 105 and N optical add circuits 107d. Since each circuit has the same configuration, FIG. Only one of the optical wavelength branching circuit 105 and the optical insertion circuit 107d is illustrated by a solid line, and the other is illustrated by a broken line.

The same reference numerals are given to the same configurations as those in the first embodiment and the third embodiment, and the description thereof is omitted.
The wavelength-multiplexed optical signal transmitted through the optical transmission path is input to the optical add / drop device, is amplified by the optical amplifier 101, and enters the OADM 102. The signal light having a predetermined wavelength branched by the OADM 102 enters the 1 × M optical coupler 104. The optical signal distributed by the 1 × M optical coupler 104 enters the optical wavelength branch circuit 105 and is received and processed. The optical signal inserted by the OADM 102 is generated by the optical insertion circuit 107d. The inserted optical signal and the optical signal transmitted without being branched by the OADM 102 are wavelength-multiplexed, amplified by the optical amplifier 103, and sent to the optical transmission line.

  On the other hand, the optical add-in circuit 107d includes an LD bank 110, optical amplifiers 111 and 115, optical splitters 112 and 114, an MZ modulator 113, PDs 116 and 123, amplifiers 117, 121, and 162, a buffer amplifier 124, and comparators 118 and 163. , Switch 119, variable gain amplifier 120, coupling capacitor 122, multiplier 125, LPF 126, differential amplifier 127, inductor 128, capacitor 129, resistor 130, 161, low frequency oscillator 131, diode 160, adder 170, and light. And an attenuator 171.

In FIG. 18, the laser light emitted from the LD bank 110 enters the optical amplifier 111. The amplified light is branched into two lights by the optical branching device 112, and the branched first light enters the MZ modulator 113 via the optical attenuator 171.
On the other hand, the second light branched by the optical branching device 112 enters the PD 116, and the electric signal is amplified by the amplifier 117 and compared with the reference voltage Vref 1 by the comparator 118. When the electric signal is equal to or lower than the reference voltage Vref1, the comparator 118 outputs a signal to the switch 119 and the adder 170.

The switch 119 is controlled according to the output of the comparator 118, and is turned off when a signal is received from the comparator 118 to disconnect the LPF 126 and the differential amplifier 127. Further, the switch 119 is turned on while the signal from the comparator 118 is not received, and the LPF 126 and the differential amplifier 127 are connected.
Further, the modulation signal and the low frequency signal of the predetermined frequency f 0 output from the low frequency oscillator 131 are input to the variable gain amplifier 120. This output signal is input to one modulation input terminal of the MZ modulator 113 via the amplifier 121 and the coupling capacitor 122.

The other modulation input terminal of the MZ modulator 113 is connected to a bias T circuit and a resistor 130 including an inductor 128 and a capacitor 129.
The MZ modulator 113, for example, of the LD bank 110 by a signal given from the drive circuit,
The light of wavelength L2 is modulated, converted into an optical signal and output.
A part of the output light from the MZ modulator 113 is branched and extracted by the optical branching device 114, and the other output light is incident on the N × 1 optical coupler 106 through the optical amplifier 115. Part of the branched output light is detected by the PD 123, and this detection signal is input to the multiplier 125 via the buffer amplifier 124. The multiplier 125 receives the low frequency signal output from the low frequency oscillator 131, compares the phase of the input signal from the buffer amplifier 124 and the low frequency signal from the low frequency oscillator 131, and determines the phase difference. A corresponding signal is output.

  The output signal of the multiplier 125 is input to one input terminal of the differential amplifier 127 via the LPF 126 and the switch 119. On the other hand, the other input terminal of the differential amplifier 127 is grounded. The output of the differential amplifier 127 is input to the inductor 128 of the bias T circuit, and the bias value is variably controlled so as to correct the operating point of the MZ modulator 113.

On the other hand, the modulation signal is grounded via the diode 160 and the resistor 161, and a voltage corresponding to the signal strength of the modulation signal is detected at both ends of the resistor 161.
A voltage corresponding to the signal strength of the modulation signal is input to the comparator 163 via the amplifier 162, and is compared with the reference voltage Vref2 by the comparator 163. When the electrical signal is equal to or lower than the reference voltage Vref2, the comparator 163 outputs a signal to the adder 170.

  The adder 170 takes the union of the signal from the comparator 118 and the signal from the comparator 163 and outputs the result to the optical attenuator 171. That is, a signal is output to the optical attenuator 171 when one of the signal from the comparator 118 and the signal from the comparator 163 is received and when the signal from both the comparators 118 and 163 is received, A signal is not output to the optical attenuator 171 only when signals are not received from both the comparators 118 and 163.

When receiving the output from the adder 170, the optical attenuator 171 attenuates the light intensity of the input light from the optical splitter 112 to a predetermined intensity. When there is no output from the adder 170, the optical attenuator 171 The input light is transmitted to the MZ modulator 113. (Correspondence between the present invention and the fourth embodiment)
With respect to the correspondence relationship between the invention described in claims 1, 3, 6, 8, 10, 12, 14, and 16, the branching / inserting means includes optical amplifiers 101 and 103, OADM 102 and 1 × M The optical wavelength branching means corresponds to the optical wavelength branching circuit 105, and the optical insertion means corresponds to the optical insertion circuit 107 d.

  Further, regarding the optical add-in circuit 107d, the first branching means corresponds to the optical branching unit 112, the light modulating unit corresponds to the MZ modulator 113, the light detecting unit corresponds to the PD 116, and the control unit is compared with the amplifier 117. The second optical branching unit corresponds to the optical branching unit 114, and the operating point control unit corresponds to the operating point control circuit. The modulation signal detection means corresponds to a portion made up of the diode 160 and the resistor 161, and the attenuation amount control means corresponds to a portion made up of the amplifiers 117, 162, the comparators 118, 163, and the adder 170, and the light attenuation means. Corresponds to the optical attenuator 171.

(Operational effect of the fourth embodiment)
In the optical add / drop device configured as described above, the input light is received while the wavelength of light emitted from the LD bank 110 is changed in the optical adder circuit 107d, for example, when the laser light having the wavelength L2 is changed to the laser light having the wavelength L4. Even if it disappears, the operating point can be maintained stably. Furthermore, the input light and the ASE that are not modulated by the modulation signal are not transmitted to the N × 1 optical coupler 106 even when there is no modulation signal to be transmitted in the optical insertion circuit 107d or there is no light emitted from the LD bank 110.

The stabilization of the operating point of the operating point control circuit operates in the same manner as in the first embodiment, and thus the description thereof is omitted here.
Here, it will be described below that input light and ASE that are not modulated by the modulation signal are not sent to the N × 1 optical coupler 106.
The signal strength of the modulation signal is detected by the diode 160 and the resistor 161, and the voltage corresponding to the signal strength of the modulation signal is determined by the comparator 163 to determine whether it is equal to or lower than a predetermined reference voltage Vref2. That is, it is determined whether or not the signal strength of the modulation signal is equal to or lower than a predetermined signal strength.

If there is a modulated signal to be sent, the comparator 163 does not send the signal to the summer 170. For this reason, since the adder 170 does not output a signal to the optical attenuator 171, the MZ modulator 113 modulates the input light with the modulation signal and outputs it.
On the other hand, when the modulation signal disappears, the voltage value of the resistor 161 decreases and becomes almost zero. For this reason, since this voltage value becomes equal to or lower than the reference voltage Vref2, the comparator 163 transmits a signal to the adder 170. Therefore, the adder 170 outputs a signal to the optical attenuator 171, and the optical attenuator 171 attenuates the input light to a predetermined optical intensity (including the case where the optical intensity is 0). Therefore, the input light and ASE that are not modulated by the modulation signal are not sent to the N × 1 optical coupler 106.

  Further, the input light from the LD bank 110 is photoelectrically converted by the PD 116, and the output signal from the PD 116 is determined by the comparator 118 whether or not it is equal to or lower than the reference voltage Vref1. That is, it is possible to determine whether or not there is input light from the LD bank 110 by determining whether or not the electric signal from the PD 116 is equal to or lower than the predetermined reference voltage Vref1 by the comparator 118.

When there is input light from the LD bank 110, the comparator 118 does not send a signal to the adder 170 because it is greater than the predetermined light intensity. For this reason, since the adder 170 does not output a signal to the optical attenuator 171, the MZ modulator 113 modulates the input light with the modulation signal and outputs it.
On the other hand, when there is no input light from the LD bank 110, the output signal of the PD 116 decreases and becomes almost zero. Therefore, since this output signal is equal to or lower than the reference voltage Vref1, the comparator 118 transmits the signal to the adder 170. Therefore, the adder 170 outputs a signal to the optical attenuator 171, and the optical attenuator 171 attenuates the ASE generated by the optical amplifier 111 or the like to a predetermined light intensity (including the case where the light intensity is 0). . Therefore, ASE is not sent to the N × 1 optical coupler 106.

  Of course, even when there is no modulation signal and no input light, the signal is sent from the adder 170 to the optical attenuator 171, so that the ASE is not sent to the N × 1 optical coupler 106.

Next, another embodiment will be described.
(Fifth embodiment)
The fifth embodiment is an embodiment of an optical add / drop device corresponding to the invention described in claims 1, 3, 7, 9, 11, 13, 15, 16.
FIG. 19 is a block diagram of an optical add / drop device according to the fifth embodiment.

In FIG. 19, the optical add / drop device includes optical amplifiers 101 and 103, OADM 102, 1 × M optical coupler 104, M optical wavelength branch circuits 105, N × 1 optical coupler 106, and N optical adder circuits 107e. It consists of.
The optical add / drop device includes M optical wavelength branch circuits 105 and N optical add circuits 107e. Since each circuit has the same configuration, FIG. Only one of the optical wavelength branching circuit 105 and the optical insertion circuit 107e is illustrated by a solid line, and the other is illustrated by a broken line.

The same reference numerals are given to the same configurations as those in the first embodiment and the third embodiment, and the description thereof is omitted.
The wavelength-multiplexed optical signal transmitted through the optical transmission path is input to the optical add / drop device, is amplified by the amplifier 101, and enters the OADM 102. The signal light having a predetermined wavelength branched by the OADM 102 enters the 1 × M optical coupler 104. The optical signal distributed by the 1 × M optical coupler 104 enters the optical wavelength branch circuit 105 and is received and processed. An optical signal inserted by the OADM 102 is generated by the optical insertion circuit 107e. The inserted optical signal and the optical signal transmitted without being branched by the OADM 102 are wavelength-multiplexed, amplified by the optical amplifier 103, and transmitted to the optical transmission line.

  On the other hand, the optical adder circuit 107e includes an LD bank 110, optical amplifiers 111 and 115, optical splitters 112 and 114, an MZ modulator 113, PDs 116 and 123, amplifiers 117, 121, and 162, a buffer amplifier 124, and comparators 118 and 163. , Switch 181, variable gain amplifier 120, coupling capacitor 122, multiplier 125, LPF 126, differential amplifier 127, inductor 128, capacitor 129, resistor 130, 161, low frequency oscillator 131, diode 160, and adder 180. Composed.

In FIG. 19, the laser light emitted from the LD bank 110 enters the optical amplifier 111. The amplified light is branched into two lights by the optical branching device 112, and the branched first light enters the MZ modulator 113 via the optical attenuator 171.
On the other hand, the second light branched by the optical branching device 112 enters the PD 116, and the electric signal is amplified by the amplifier 117 and compared with the reference voltage Vref 1 by the comparator 118. When the electric signal is equal to or lower than the reference voltage Vref1, the comparator 118 outputs a signal to the switch 181 and the adder 180.

  The switch 181 can switch between connecting the LPF 126 and the differential amplifier 127 or connecting the reference voltage V 1 and the differential amplifier 127. The switch 181 is normally switched so as to connect the LPF 126 and the differential amplifier 127, but switches to connect the reference voltage V 1 and the differential amplifier 127 when receiving a signal from the comparator 118. When the switch 181 stops receiving a signal from the comparator 118, the switch 181 connects the LPF 126 and the differential amplifier 127 again.

The reference voltage V1 is a voltage value in a range in which the operating point can be controlled in the operating point control circuit.
Further, the modulation signal and the low frequency signal of the predetermined frequency f 0 output from the low frequency oscillator 131 are input to the variable gain amplifier 120. This output signal is input to one modulation input terminal of the MZ modulator 113 via the amplifier 121 and the coupling capacitor 122.

The other modulation input terminal of the MZ modulator 113 is connected to a bias T circuit and a resistor 130 including an inductor 128 and a capacitor 129.
The MZ modulator 113 modulates, for example, light of wavelength L2 in the LD bank 110 with a signal given from the drive circuit, converts it to an optical signal, and outputs it. Further, when a signal is received from the adder 180, the output light is eliminated by shifting the phase difference of each light transmitted through the two optical waveguides in the MZ modulator 113 by 180.

A part of the output light from the MZ modulator 113 is branched and extracted by the optical branching device 114, and the other output light is incident on the N × 1 optical coupler 106 through the optical amplifier 115. Part of the branched output light is detected by the PD 123, and this detection signal is input to the multiplier 125 via the buffer amplifier 124. The multiplier 125 receives the low frequency signal output from the low frequency oscillator 131, compares the phase of the input signal from the buffer amplifier 124 and the low frequency signal from the low frequency oscillator 131, and determines the phase difference. A corresponding signal is output.

  The output signal of the multiplier 125 is input to one input terminal of the differential amplifier 127 via the LPF 126 and the switch 119. On the other hand, the other input terminal of the differential amplifier 127 is grounded. The output of the differential amplifier 127 is input to the inductor 128 of the bias T circuit, and the bias value is variably controlled so as to correct the operating point.

On the other hand, the modulation signal is grounded via the diode 160 and the resistor 161, and a voltage corresponding to the signal strength of the modulation signal is detected at both ends of the resistor 161.
A voltage corresponding to the signal strength of the modulation signal is input to the comparator 163 via the amplifier 162, and is compared with the reference voltage Vref2 by the comparator 163. When the electrical signal is equal to or lower than the reference voltage Vref2, the comparator 163 outputs a signal to the adder 180.

The adder 180 takes the union of the output of the comparator 118 and the output of the comparator 163 and outputs the result to the MZ modulator 113.
(Correspondence between the present invention and the fifth embodiment)
With respect to the correspondence relationship between the invention described in claims 1, 3, 6, 8, 10, 12, 14, and 16, the branching / inserting means includes optical amplifiers 101 and 103, OADM 102 and 1 × M. The optical wavelength branching means corresponds to the optical wavelength branching circuit 105, and the optical insertion means corresponds to the optical insertion circuit 107e.

  Further, regarding the optical add-in circuit 107e, the first branching means corresponds to the optical branching unit 112, the light modulating unit corresponds to the MZ modulator 113, the light detecting unit corresponds to the PD 116, and the control unit is compared with the amplifier 117. The second optical branching unit corresponds to the optical branching unit 114, and the operating point control unit corresponds to the operating point control circuit. Further, the modulation signal detecting means corresponds to a portion made up of the diode 160 and the resistor 161, and the modulation control means corresponds to a portion made up of the amplifiers 117 and 162, the comparators 118 and 163, and the adder 180.

(Operational effects of the fifth embodiment)
In the optical add / drop device configured as described above, the input light is received while the wavelength of light emitted from the LD bank 110 is changed in the optical adder circuit 107e, for example, while the laser light having the wavelength L2 is changed to the laser light having the wavelength L4. Even if it disappears, the operating point can be maintained stably. Furthermore, the input light and the ASE that are not modulated by the modulation signal are not transmitted to the N × 1 optical coupler 106 even when there is no modulation signal to be transmitted in the optical insertion circuit 107e or there is no light emitted from the LD bank 110.

To stabilize the operating point of the operating point control circuit, instead of turning on / off the switch 119, one input terminal of the differential amplifier 127 is connected to the LPF 126 by the switch 164 or to the reference voltage V1. Except for this, the operation is the same as in the first embodiment, and the description thereof is omitted here.
Here, it will be described below that input light and ASE that are not modulated by the modulation signal are not sent to the N × 1 optical coupler 106.

The signal strength of the modulation signal is detected by the diode 160 and the resistor 161, and the voltage corresponding to the signal strength of the modulation signal is determined by the comparator 163 to determine whether it is equal to or lower than a predetermined reference voltage Vref2. That is, it is determined whether or not the signal strength of the modulation signal is equal to or lower than a predetermined signal strength.
When there is a modulation signal to be transmitted, the comparator 163 does not transmit the signal to the adder 180. For this reason, since the adder 180 does not output a signal to the MZ modulator 113, the MZ modulator 113 modulates the input light with the modulation signal and outputs it.

  On the other hand, when the modulation signal disappears, the voltage value of the resistor 161 decreases and becomes almost zero. For this reason, since this voltage value becomes equal to or lower than the reference voltage Vref, the comparator 163 transmits a signal to the adder 180. Therefore, the adder 180 outputs a signal to the optical modulator 113, and the optical modulator 113 shifts the phase difference of each light transmitted through the two optical waveguides in the MZ modulator 113 by 180 so as to eliminate the output light. Therefore, the input light and ASE that are not modulated by the modulation signal are not sent to the N × 1 optical coupler 106.

  Further, the input light from the LD bank 110 is photoelectrically converted by the PD 116, and the output signal from the PD 116 is determined by the comparator 118 whether or not it is equal to or lower than the reference voltage Vref. That is, it is possible to determine whether or not there is input light from the LD bank 110 by determining whether or not the electric signal from the PD 116 is equal to or lower than the predetermined reference voltage Vref1 by the comparator 118.

When there is input light from the LD bank 110, the comparator 118 does not send a signal to the adder 180 because it is greater than the predetermined light intensity. For this reason, since the adder 180 does not output a signal to the MZ modulator 113, the MZ modulator 113 modulates the input light with the modulation signal and outputs it.
On the other hand, when there is no input light from the LD bank 110, the output signal of the PD 116 decreases and becomes almost zero. Therefore, since this output signal is equal to or lower than the reference voltage Vref, the comparator 118 transmits the signal to the adder 180. Therefore, the adder 180 outputs a signal to the MZ modulator 113, and the MZ modulator 113 attenuates ASE generated in the optical amplifier 111 and the like. Therefore, ASE is not sent to the N × 1 optical coupler 106.

Of course, even when there is no modulation signal and no input light, the signal is sent from the adder 180 to the MZ modulator 113, so that the ASE is not sent to the N × 1 optical coupler 106.
The laser diode bank in the first to fifth embodiments can be replaced with an optical tunable laser capable of emitting an arbitrary light wavelength.

It is a block diagram of the optical communication apparatus according to claim 1 and claim 3. It is a block diagram of the optical communication apparatus according to claim 2. It is a block diagram of the optical communication apparatus according to claim 4 and claim 5. It is a block diagram of the optical communication apparatus according to claim 6. It is a block diagram of the optical communication apparatus according to claim 7. It is a block diagram of the optical communication apparatus according to claim 8. It is a block diagram of the optical communication apparatus according to claim 9. FIG. 10 is a block diagram of an optical communication apparatus according to claim 10 in which the optical attenuation means is added to claim 1. FIG. 11 is a block diagram of an optical communication apparatus according to claim 11 in which the optical modulation means of claim 1 is controlled according to a modulation signal. It is a block diagram of the optical communication apparatus according to claim 12. It is a block diagram of the optical communication apparatus according to claim 13. It is a block diagram of the optical communication apparatus according to claim 14. It is a block diagram of the optical communication apparatus according to claim 15. FIG. 16 is a block diagram of an optical add / drop device using the optical communication device according to claim 1 as an optical insertion means. 1 is a block diagram of an optical add / drop device according to a first embodiment. FIG. It is a block diagram of the optical add / drop device of the second embodiment. It is a block diagram of the optical add / drop device of the third embodiment. It is a block diagram of the optical add / drop device of the fourth embodiment. It is a block diagram of the optical add / drop device of the fifth embodiment. It is a block diagram of the MZ modulator provided with the conventional operating point control circuit. It is a wave form diagram for demonstrating operation | movement when a drift arises in an operating point. It is a block diagram of the conventional optical add / drop device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Optical branching means 14 Control means 15 Optical detection means 21 Optical branching means 23 Optical detection means 25 Control means 26 Modulation signal detection means 31 Optical attenuation means 32 Attenuation amount control means 33 Optical detection means 35 Modulation control means 41 Attenuation amount control means 42 Modulation signal detection means 45 Modulation control means 50 Optical attenuation means 55 Optical modulation means 61 Attenuation amount control means 65 Modulation control means 107a to e Optical adder circuit 112 Optical branching device 114 Optical branching device 116 PD
117 Amplifier 118 Comparator 119 Switch 140 Optical splitter 140
141 PD
142 Amplifier 143 Comparator 144 Switch 145 Resistor 146 Resistor 147 FET
148 Switch 149 FET
150 operational amplifier 151 capacitor 152 operational amplifier 160 diode 161 amplifier 161 resistor 163 comparator 164 switch 170 adder 171 optical attenuator 180 adder 181 switch

Claims (16)

First optical branching means for splitting the input light input to the input port into two;
Optical modulation means for modulating the first branched input light output from the first optical branching means in accordance with a modulation signal to be transmitted;
Light detecting means for detecting the light intensity of the second branched input light output from the first light branching means;
A second optical branching unit that branches the modulated optical signal output from the optical modulation unit into two and outputs the branched first branched optical signal to an output port;
Operating point control means for controlling the light modulation means in accordance with a second branched optical signal output from the second optical branch means;
An optical communication apparatus comprising: control means for controlling the operating point control means in accordance with the light intensity detected by the light detection means. Light modulation means for modulating the input light input to the input port according to the modulation signal to be transmitted;
Optical branching means for branching the modulated optical signal output from the optical modulation means into three and outputting the branched first branched optical signal to the output port;
Light detecting means for detecting the light intensity of the second branched optical signal output from the light branching means;
Operating point control means for controlling the light modulation means in accordance with a third branching optical signal output from the light branching means;
An optical communication apparatus comprising: control means for controlling the operating point control means in accordance with the light intensity detected by the light detection means. The optical communication apparatus according to claim 1 or 2,
The optical communication apparatus, wherein the control means controls the operating point of the operating point control means to become a predetermined value in a control range according to the light intensity detected by the light detecting means. Light modulation means for modulating the input light input to the input port according to the modulation signal to be transmitted;
Optical branching means for branching the modulated optical signal output from the optical modulation means into two and outputting the branched first branched optical signal to the output port;
Operating point control means for controlling the light modulation means in accordance with a second branch optical signal output from the light branch means;
Modulation signal detection means for detecting the signal intensity of the modulation signal;
An optical communication apparatus comprising: control means for controlling the operating point control means in accordance with the signal intensity detected by the modulation signal detection means. The optical communication device according to claim 4,
The control means controls the operating point of the operating point control means so as to become a predetermined value in a control range in accordance with the signal intensity detected by the modulation signal detecting means. . Light modulating means for modulating the input light according to the modulation signal to be transmitted;
A light attenuating means for transmitting or attenuating input light;
An optical branching means for splitting the input light into two;
Light detecting means for detecting the light intensity of the second branched input light output from the light branching means;
Attenuation amount control means for controlling the light attenuation means according to the light intensity detected by the light detection means,
The first branched input light output from the optical branching unit is output to an output port via the optical attenuation unit and the optical modulation unit, or the optical modulation unit and the optical attenuation unit An optical communication device characterized in that either one of the cases is output to the output port via the optical communication device. Optical branching means for splitting the input light input to the input port into two;
A light modulating means for modulating the first branched input light output from the light branching means in accordance with a modulation signal to be transmitted, and outputting the modulated optical signal to an output port;
Light detecting means for detecting the light intensity of the second branched input light output from the light branching means;
An optical communication apparatus comprising: modulation control means for controlling the light modulation means in accordance with the light intensity detected by the light detection means. Light modulating means for modulating the input light according to the modulation signal to be transmitted;
A light attenuating means for transmitting, attenuating or blocking the input light;
Modulation signal detection means for detecting the signal intensity of the modulation signal;
An attenuation control means for controlling the light attenuation means according to the signal intensity detected by the modulation signal detection means,
The input light input to the input port is output to the output port via the light attenuating means and the light modulating means, or is output to the output port via the light modulating means and the light attenuating means. An optical communication apparatus characterized by being in either case. Optical modulation means for modulating the input light input to the input port according to the modulation signal to be transmitted, and outputting the modulated optical signal to the output port;
Modulation signal detection means for detecting the signal intensity of the modulation signal;
An optical communication apparatus comprising: modulation control means for controlling the optical modulation means in accordance with the modulation signal intensity detected by the modulation signal detection means. The optical communication device according to any one of claims 1, 2, and 4,
An optical communication apparatus, wherein an optical attenuating means for transmitting or attenuating the light according to the intensity of the input light is inserted into the input or output of the light modulating means. The optical communication device according to any one of claims 1, 2, and 4,
The optical communication device is controlled according to the signal intensity of the modulation signal or the input light intensity. The optical communication apparatus according to claim 1 or 2,
Modulation signal detection means for detecting the signal intensity of the modulation signal;
An optical attenuation connected to either the first optical branching unit and the optical modulation unit or between the optical modulation unit and the second optical branching unit, and transmits or attenuates input light. Means,
An optical communication apparatus further comprising: an attenuation amount control unit that controls the optical attenuation unit in accordance with the signal intensity detected by the modulation signal detection unit. The optical communication apparatus according to claim 1 or 2,
Modulation signal detection means for detecting the signal intensity of the modulation signal;
Modulation control means for controlling the optical modulator according to the signal intensity detected by the modulation signal detection means,
The optical communication device is characterized in that the optical modulation means is controlled in accordance with the signal intensity detected by the modulation signal detection means. The optical communication device according to claim 12, wherein
The optical communication apparatus, wherein the attenuation control means is controlled according to the light intensity detected by the light detection means and the signal intensity detected by the modulation signal detection means. The optical communication device according to claim 13.
The optical communication device is controlled according to the light intensity detected by the light detection means and the signal intensity detected by the modulation signal detection means. A branch / insertion unit that is connected to a transmission line that transmits a wavelength-multiplexed optical signal and that can branch and insert an optical signal of at least one wavelength with respect to the optical signal on the transmission line; An optical branching / inserting device comprising: an optical wavelength branching unit that receives and processes the received optical signal for each wavelength; and an optical insertion unit that outputs insertion light to be inserted into the optical signal on the transmission path to the branching / insertion unit ,
The light inserting means is
An optical branching / inserting device, which is the optical communication device according to any one of claims 1, 2, 4, 6, 7, 8, and 9.

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