JP4066739B2 - Optical transmitter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical transmitter .
[0002]
[Prior art]
The optical communication system includes an optical transmitter that outputs light, an optical transmission path that transmits the light, and an optical transmitter that receives light transmitted through the optical transmission path. When such an optical communication system is, for example, a wavelength division multiplexing optical communication system, an optical transmitter used in the optical communication system includes a plurality of optical transmission modules that output light of mutually different wavelengths, The lights from the respective optical transmission modules are combined and output. As an optical transmission module included in this optical transmitter, a wavelength adjustment request instruction transmitted from a host control unit (for example, a host CPU) by specifying its own apparatus is received by communication means, and a wavelength is determined based on the wavelength adjustment request instruction. A device is known in which the adjusting means adjusts the wavelength of light output from a laser diode.
[0003]
[Problems to be solved by the invention]
As described above, in the conventional optical transmitter, an upper control unit is always required to set the wavelength of each optical transmission module. Further, as an aspect that does not require the host control unit, it may be possible to set the wavelength of the output light of each optical transmission module in advance, but if it is set in advance, solid management of the optical transmission module Becomes complicated.
[0004]
Therefore, an object of the present invention is to provide an optical transmitter capable of setting the wavelength of light to be output without a host control unit.
[0005]
[Means for Solving the Problems]
The light emitting module of the present invention is an optical transmission module configured to be detachable from the optical transmitter, and is adjusted to output light of any wavelength from among a plurality of wavelengths that can be output. A laser diode that can output light having an adjusted wavelength, a wavelength adjusting unit that adjusts the wavelength of light output from the laser diode, and a wavelength adjusting unit that adjusts the wavelength of light in association with a slave address Based on the control information storage means for storing the wavelength control information and the slave address as the wavelength selection signal from the outside of the own device and the received slave address and the wavelength control information stored in the control information storage means , and a control means for adjusting the wavelength of light output from the laser diode wavelength adjusting means, the control means, from the laser diode When the detected light is in an abnormal state, it outputs an abnormality notification signal to notify the abnormal state to the outside of the aircraft, and the wavelength adjusting means stops emitting the laser diode in response to the output of the abnormality notification signal Let

[0006]
In the optical transmission module of the present invention, the control unit adjusts the wavelength of light output from the laser diode to the wavelength adjusting unit based on the slave address input from the outside of the own device and the wavelength control information stored in advance. Let Therefore, for example, if the substrate on which the optical transmission module is arranged so that a predetermined slave address can be input, the wavelength of the light to be output can be set without a host control unit.
[0007]
In the optical transmission module of the present invention, when the light output from the laser diode is in an abnormal state, the control means outputs an abnormality notification signal for notifying the outside of the own device of the abnormal state. Is preferred. If an abnormality notification signal is output to the outside of the own device, it can be recognized that an abnormality has occurred in the optical transmission module.
[0008]
In the optical transmission module of the present invention, it is preferable that the wavelength adjusting unit stops the light output from the laser diode in response to the output of the abnormality notification signal. There is no longer any output of light in an abnormal state, and for example, it can be replaced with a standby light output. It is also preferable to feed back the abnormality report signal to the own device and stop the output of light from the laser diode based on the abnormality report signal.
[0009]
The optical transmission module of the present invention is preferably configured to be detachable from the optical transmitter. If the optical transmission module is detachable from the optical transmitter, replacement becomes easy when an abnormality occurs in the optical transmission module.
[0010]
The optical transmitter of the present invention includes a plurality of the above-described optical transmission modules and a slave that outputs a slave address as a wavelength selection signal to the optical transmission module so as to output light having different wavelengths from the plurality of optical transmission modules. When the light is no longer output from the address output means, the optical combiner that outputs light of different wavelengths output from each of the multiple optical transmission modules, and the multiple optical transmission modules , a standby optical transmission module for outputting light instead, a standby optical output control means for outputting a stop signal to the standby optical transmission module so that the light is not output from the standby optical transmission module in a steady state Based on the abnormality notification signal output from the optical transmission module, the slave corresponding to the optical transmission module that has output the abnormality notification signal. An optical transmission module that includes an encoder that generates an address and a selector that selects a modulation input signal based on the generated slave address, and that outputs an abnormality notification signal is a laser diode according to the output of the abnormality notification signal. The standby light output control means stops the output of the stop signal in response to the output of the abnormality notification signal output from the control means, and the standby light transmission module is generated by the encoder. Light is output based on the slave address and the modulation input signal selected by the selector.
[0011]
In the optical transmitter according to the present invention, based on the slave address output from the slave address output means and the wavelength control information stored in the optical transmission module in advance, the control means of the optical transmission module transmits the wavelength adjustment means from the laser diode. Adjust the wavelength of the output light. Therefore, it is possible to set the wavelength of the output light without the host control unit.
[0012]
In the optical transmitter of the present invention, a plurality of the case where the light from one of the optical transmission module is not output, and standby optical transmission module for outputting light instead, the protection system light in a steady state The standby optical output control means for outputting a stop signal to the standby optical transmission module so that light is not output from the transmission module, and the light that has output the abnormality notification signal based on the abnormality notification signal output from the optical transmission module The optical transmission module that further includes an encoder that generates a slave address corresponding to the transmission module and a selector that selects a modulation input signal based on the generated slave address. stop the light output from the laser diode in response to the output signal, standby optical output control means from the control means Stops outputting the stop signal in response to the output of the force is the abnormality notification signal, the standby optical transmission module, can output light based on a modulation input signal slave address and selector encoder generates selects preferable.
[0013]
Since the optical transmission module that has output the abnormality notification signal stops the light output from the laser diode, the optical transmitter is prevented from outputting an abnormal optical signal. When the optical transmission module that has output an error notification signal stops outputting light, the standby optical transmission module substitutes for the light output by the optical transmission module, so the optical output is switched to the standby system. Can do. Since the standby optical output control means stops outputting the stop signal in response to the output of the abnormality notification signal, it can be operated only when the standby optical transmission module is required.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
The knowledge of the present invention can be easily understood by considering the following detailed description with reference to the accompanying drawings shown for illustration only. Subsequently, embodiments of the present invention will be described with reference to the accompanying drawings. Where possible, the same parts are denoted by the same reference numerals, and redundant description is omitted.
[0015]
An optical transmission module according to an embodiment of the present invention will be described. FIG. 1 is a diagram illustrating a configuration of the optical transmission module 10. The optical transmission module 10 includes a laser diode driving unit (wavelength adjusting unit) 101, a laser diode 102, a CPU (control unit) 103, a monitor unit 104, a nonvolatile memory (control information storage unit) 105, and a terminal 106a. -106e.
[0016]
The laser diode 102 can output light of a plurality of wavelengths, and is adjusted to output light of any wavelength among the light of a plurality of wavelengths, and the light of the adjusted wavelength is output. It can be output via the terminal 106e. As the laser diode 102, for example, a distributed feedback laser diode is used.
[0017]
The laser diode driver 101 is a part that controls the light emission of the laser diode 102. The laser diode driver 101 includes a laser diode driver, a current controller, and a wavelength adjuster (wavelength adjuster). The laser diode driver 101 drives the laser diode 102 by supplying a bias current and a modulation current to the laser diode 102. Here, the modulation current is a current superimposed on the bias current in accordance with the data signal to be transmitted. The laser diode driver 101 is connected to the terminal 106a, and a data signal to be transmitted is input as, for example, a modulation input signal.
[0018]
The laser diode driver 101 adjusts the wavelength of light output from the laser diode 102. The wavelength of light output from the laser diode 102 is adjusted by controlling the temperature of the laser diode 102. The part that functions as the wavelength adjusting unit of the laser diode driving unit 101 includes a temperature control unit, a Peltier element, a Peltier driver, and a thermistor. The portion functioning as the wavelength adjusting unit of the laser diode driving unit 101 sets the temperature of the laser diode 102 in accordance with an input signal from the CPU 103, and performs temperature control so that light of a predetermined wavelength is output from the laser diode 102. Do.
[0019]
The CPU 103 is a part that controls each part of the optical transmission module 10. The CPU 103 is connected to the terminal 106c and the terminal 106d. The terminal 106 c is used for inputting a slave address to the CPU 103. The CPU 103 receives a slave address as a wavelength selection signal from the outside of the own device via the terminal 106 c, and based on the received slave address and the wavelength control information stored in the nonvolatile memory 105, the laser diode driving unit 101. A signal is output so that the wavelength adjustment unit adjusts the output wavelength of the laser diode 102.
[0020]
The non-volatile memory 105 stores information as shown in FIG. That is, the slave address and the wavelength control information are stored in the nonvolatile memory 105 in association with each other. The wavelength control information is information for controlling the wavelength of light output from the laser diode 102. When receiving the slave address, the CPU 103 selects the wavelength control information corresponding to the slave address and outputs it to the wavelength adjustment unit of the laser diode driving unit 101.
[0021]
The terminal 106d is used for outputting an abnormality notification signal to the outside. When the CPU 103 receives the monitoring result of the output light of the laser diode 102 from the monitor unit 104 and determines that the output light of the laser diode 102 is in an abnormal state, the CPU 103 informs the outside of the own device of the abnormal state. An error report signal is output. The monitor unit 104 is a part that monitors the light amount of the laser diode 102. As the monitor unit 104, for example, a photodiode is used.
[0022]
The abnormality notification signal output from the CPU 103 via the terminal 106d is input to the laser diode driving unit 101 via the terminal 106b. The laser diode driving unit 101 stops the light emission of the laser diode 102 when the abnormality notification signal is input.
[0023]
Next, the optical transmitter 1 using the optical transmission module 10 will be described with reference to FIG. The optical transmitter 1 includes N optical transmission modules 10 (optical transmission modules 10a to 10N). The optical transmission modules 10a to 10N are configured to be detachable from the optical transmitter 1 individually. Data signals to be transmitted are input to the optical transmission modules 10a to 10N via the terminals 106aa to 106aN. Also, slave addresses are output to the optical transmission modules 10a to 10N from a slave address output circuit (slave address output means) (not shown), and each of the optical transmission modules 10a to 10N outputs according to the output slave address. Sets the wavelength of light. Light output from the optical transmission modules 10 a to 10 N is combined by the optical multiplexer 111 and output via the terminal 112.
[0024]
The standby optical transmission module 110 includes, as its constituent elements, a laser diode driving unit, a laser diode, a CPU, a monitoring unit, and a non-volatile memory, like the optical transmission modules 10a to 10N. In the standby system optical transmission module 110, in a steady state, the shutdown signal (stop signal) output from the standby system light output control unit 109 is input to the laser diode driving unit, and the light emission of the laser diode is stopped. ing.
[0025]
The standby optical output control unit 109 outputs a shutdown signal to the standby optical transmission module 110 in a steady state, and stops the optical output from the standby optical transmission module 110. The standby optical output control unit 109 monitors an abnormality notification signal output from the optical transmission modules 10a to 10N to the encoder 108. When an abnormality notification signal is output from the optical transmission modules 10a to 10N, the standby optical output control unit 109 detects that an abnormality has occurred in the optical transmission modules 10a to 10N, and generates a shutdown signal for the standby optical transmission module 110. Stop output. Therefore, the standby optical transmission module 110 can output light.
[0026]
The encoder 108 is a part that generates a slave address corresponding to the optical transmission modules 10a to 10N that output the abnormality notification signal based on the abnormality notification signal output from the optical transmission modules 10a to 10N. For example, when an abnormality notification signal is output from the optical transmission module 10a and the slave address corresponding to the optical transmission module 10a is “# 1,” the slave address is generated. The encoder 108 outputs the generated slave address to the selector 107 and the standby optical transmission module 110.
[0027]
The selector 107 is a part that selects a modulation input signal based on the slave address generated by the encoder 108. For example, when the slave address is “# 1”, the modulation input signal input to the optical transmission module 10 a from the terminal 106 aa is selected, and the selected modulation input signal is output to the standby optical transmission module 110.
[0028]
The standby optical transmission module 110 selects a wavelength corresponding to the slave address generated by the encoder 108 and outputs the modulation input signal selected by the selector 107. For example, when the slave address is “# 1”, it functions as an optical transmission module similar to the optical transmission module 10a.
[0029]
Subsequently, the operation of the optical transmitter 1 when an abnormality occurs in any of the optical transmission modules 10a to 10N will be described with reference to the sequence diagram shown in FIG. In the steady state, a shutdown signal is output from the standby optical output control unit 109 to the standby optical transmission module 110, and no light is output from the standby optical transmission module 110. (Step S01).
[0030]
When an abnormality occurs in any of the optical transmission modules 10a to 10N (for example, the optical transmission module 10a) (step S02), an abnormality notification signal is output from the optical transmission module 10a to the encoder 108 (step S03).
[0031]
The abnormality notification signal output from the optical transmission module 10a to the encoder 108 is input to the laser diode driving unit of the optical transmission module 10a (step S04). When the abnormality notification signal is input, the laser diode driving unit of the optical transmission module 10a stops the light emission of the laser diode (step S05).
[0032]
The abnormality notification signal output from the optical transmission module 10a to the encoder 108 is monitored by the standby optical output control unit 109. When the abnormality notification signal is output, it is detected that an abnormality has occurred in the optical transmission module 10a. (Step S06).
[0033]
The standby optical output control unit 109 that has detected the abnormality stops the output of the shutdown signal to the standby optical transmission module 110 (step S07). Therefore, the standby optical transmission module 110 is ready to output light.
[0034]
The encoder 108 that has output the abnormality notification signal from the optical transmission module 10a generates a slave address corresponding to the optical transmission module 10a that has output the abnormality notification signal (step S08). Here, the slave address functions as information for specifying the optical transmission module 10a in which an abnormality has occurred.
[0035]
The encoder 108 outputs the generated slave address to the selector 107 and the standby optical transmission module 110 (step S09).
[0036]
The standby optical transmission module 110 performs wavelength adjustment based on the slave address output from the encoder 108 (step S10).
[0037]
The selector 107 selects a modulation input signal based on the slave address output from the encoder 108 (step S11). In the case of the present embodiment, since an abnormality has occurred in the optical transmission module 10a, the modulation input signal input from the terminal 106aa is selected.
[0038]
The selector 107 outputs the selected modulation input signal to the standby optical transmission module 110 (step S12). The standby optical transmission module 110 outputs the modulation input signal output from the selector 107 using the wavelength adjusted in step S10 (step S13). The light output from the standby optical transmission module 110 is combined with the light output from the optical transmission modules 10b to 10N by the optical multiplexer 111 and output.
[0039]
In the present embodiment, the optical transmission module 10 receives the light output from the laser diode 102 to the laser diode driver 101 based on the slave address input from the outside of the own device and the wavelength control information stored in advance. Adjust the wavelength. Therefore, if the electric circuit is configured on the substrate of the optical transmitter on which the optical transmission module 10 is arranged so that a predetermined slave address can be output, the wavelength of the light that is output without the host control unit Can be set.
[0040]
Further, in the optical transmitter 1, since the optical transmission module 10a that has output the abnormality notification signal stops the light output from the laser diode, the optical transmitter 1 is prevented from outputting an abnormal optical signal to the outside. The When the optical transmission module 10a that has output the abnormality report signal stops outputting light, the standby optical transmission module 110 substitutes and outputs the light output by the optical transmission module 10a. You can switch to Since the standby optical output control unit 109 stops outputting the stop signal in response to the output of the abnormality notification signal, it can be operated only when the standby optical transmission module 110 is required.
[0041]
【The invention's effect】
According to the present invention, the control unit causes the wavelength adjusting unit to adjust the wavelength of the light output from the laser diode based on the slave address input from the outside of the own device and the wavelength control information stored in advance. Therefore, for example, if the substrate on which the optical transmission module is arranged so that a predetermined slave address can be input, the wavelength of the light to be output can be set without a host control unit. Therefore, the optical transmitter capable of setting the wavelength of the output light without the host control unit, which is an object of the present invention, can be provided.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of an optical transmission module according to an embodiment of the present invention.
FIG. 2 is a diagram showing an example of information stored in the nonvolatile memory of FIG.
FIG. 3 is a diagram showing a configuration of an optical transmitter according to an embodiment of the present invention.
FIG. 4 is a sequence diagram showing an operation of the optical transmitter according to the embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Optical transmission module, 101 ... Laser diode drive part, 102 ... Laser diode, 103 ... CPU, 104 ... Monitor part, 105 ... Non-volatile memory.

Claims (1)

An optical transmitter,
A plurality of optical transmission modules configured to be detachable from the optical transmitter, the optical transmission module,
A laser diode that is adjusted to output light of any wavelength among a plurality of wavelengths that can be output, and that can output light of the adjusted wavelength;
Wavelength adjusting means for adjusting the wavelength of light output from the laser diode;
Control information storing means for storing wavelength control information for adjusting the wavelength of light by the wavelength adjusting means in association with a slave address;
A slave address as a wavelength selection signal is received from the outside of the own device, and is output from the laser diode to the wavelength adjustment unit based on the received slave address and the wavelength control information stored in the control information storage unit. Control means for adjusting the wavelength of the light to be
When the light output from the laser diode is in an abnormal state, the control means outputs an abnormality notification signal for notifying the outside of the own device,
The wavelength adjusting means stops light emission of the laser diode according to the output of the abnormality notification signal ,
The optical transmitter further includes:
Slave address output means for outputting a slave address as a wavelength selection signal to the optical transmission module so as to output light of different wavelengths from a plurality of the optical transmission modules;
An optical multiplexer that multiplexes and outputs lights of different wavelengths respectively output from the plurality of optical transmission modules;
When light is not output from any of the plurality of optical transmission modules, a standby optical transmission module for outputting light instead,
Standby optical output control means for outputting a stop signal to the standby optical transmission module so that light is not output from the standby optical transmission module in a steady state;
Based on the abnormality notification signal output from the optical transmission module, an encoder that generates a slave address corresponding to the optical transmission module that has output the abnormality notification signal;
A selector for selecting a modulation input signal based on the generated slave address;
The optical transmission module that has output the abnormality notification signal stops the light output from the laser diode in response to the output of the abnormality notification signal.
The standby light output control means stops the output of the stop signal according to the output of the abnormality notification signal output from the control means,
The standby optical transmission module is an optical transmitter that outputs light based on a slave address generated by the encoder and a modulation input signal selected by the selector.

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