KR100969736B1 - Optical transmitting device having injection light source detection function and optical transmitting and receiving system therefor - Google Patents

Abstract

Disclosed are an optical transmitting apparatus and an optical transmitting and receiving system therefor that employ an injection light source detection function to maintain a stable quality of light output. An optical transmission device of the present invention includes a wavelength independent light source outputting a variable wavelength of light according to an injection light source, an injection light source detection unit operable to detect intensity and wavelength information of the injection light source, and intensity information of transmission light. A transmission light detector that operates, and a temperature controller that operates to detect temperature information inside the apparatus; And a light source driving control unit configured to output-control the intensity of the wavelength independent light source based on the intensity and wavelength information of the injection light source, the intensity information of the transmission light, and the temperature information inside the device. In one embodiment, the injection light source detector is provided on the outside of the device, the intensity information of the transmission light, the intensity of the light output from the wavelength independent light source and the intensity of the light output from the injection light source generation unit. This is information. In another embodiment, the injection light source detecting unit is provided inside the apparatus, and the intensity information of the transmission light is intensity information of pure light output from the wavelength independent light source not including the injection light source.

Wavelength independent light source, injection light source, transmission light, reception light, WDM

Description

Optical transmitting device having an injection light source detection function and an optical transmitting and receiving system therefor {OPTICAL TRANSMISSION APPARATUS WITH INJECTED SEED LIGHT DETECTION AND OPTICAL TRANCEIVING SYSTEM FOR THE SAME}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transmission apparatus used in a wavelength independent wavelength division multiplexing (WDM) optical network. More particularly, the present invention relates to a wavelength independent light source, in which a wavelength of light is varied according to an injection light source. The present invention relates to an optical transmission apparatus capable of maintaining stable quality of light output by employing an injection light source detection function in an optical transmission and reception system for transmitting and receiving light.

With the recent spread of the Internet, based on Ethernet signals, not only traditional voice over IP (VoIP: Voice over IP) and personal data communication (P2P) but also real time broadcasting (IPTV), VOD (Video On Demand), and electronic education (E-) Various multimedia-based application services, such as including image information such as learning (UCC) and user creative contents (UCC), have been introduced. Broadband bandwidth is required to reliably support these various application services. In order to accommodate such bandwidth bandwidth in a limited fiber infrastructure, WDM techniques are actively applied.

WDM is a method of simultaneously transmitting optical signals having several different wavelengths through a single optical fiber, and bandwidth can be increased without additional laying of optical fibers. Currently, WDM transmission system uses a fixed light source for each WDM channel, but high density WDM (Dense WDM) technology is introduced to increase the number of WDM channels per fiber to dozens and hundreds. There is a problem of management and maintenance of the used light source. In order to solve this problem, it adopts the same method as DWDM Passive Optical Network (DWDM-PON), which has a wavelength independent light source while accommodating the bandwidth of the broadband, and solves the problem of management and maintenance of fixed light source. A wavelength-independent DWDM passive optical network transmission system has been developed.

In the wavelength independent DWDM passive optical network transmission system, an optical transmitter and receiver having a wavelength independent light source is installed at each end of the optical path of the DWDM passive optical network in order to transmit optical signals. Adopted structure and interface. For example, the configuration of an optical transmission / reception system complying with a standard such as a gigabit interface converter (GBIC) and a small form-factor pluggable (SFP) will be described with reference to FIG. 1.

The transmission data (differential signal) received from the transmission system (not shown) is first input to the light source driver 11 of the optical transmission / reception apparatus.

The light source driver 11 of the optical transmitting / receiving apparatus drives the fixed wavelength light source 12 according to the input differential signal, and transmits the optical signal to the counterpart optical transmitting / receiving device through a transmission or transmission optical fiber. At this time, as the fixed wavelength light source 12, a Fabry-Perot Laser Diode, a Distributed FeedBack Laser Diode, or the like is used.

The transmission light detector 13 of the optical transmission / reception apparatus detects the intensity of the optical signal output from the fixed wavelength light source 12 to the transmission optical fiber and feeds back the optical signal intensity information to the light source driver 11. Then, the light source driver 11 determines whether the intensity of the optical signal is appropriate based on the optical signal intensity information, and controls the output of the appropriate optical signal from the fixed wavelength light source 12.

The optical signal received through the receiving or transmitting / receiving optical fiber is converted into an electrical signal by the receiving light detector 14 of the optical transmitting and receiving device, amplified by the limiting amplifier 15 and transmitted to the optical transmission system as received data (differential signal).

In the above, the transmission and reception optical fiber means using one optical fiber in both directions (transmission and reception), and it is also possible to perform optical connection by separating the transmission optical fiber and the reception optical fiber.

The light source driver 11 and the limiting amplifier 15 of the transmitting and receiving device monitor and control functions such as transmission and reception failure detection and transmission interruption defined in the standard, and the optical transmission and reception device supports an optical transmission system and a two-wire serial interface. Provides the contents of the memory 16 containing the standard information (eg, manufacturer, transmit / receive wavelength, transmit / receive optical output, device temperature, etc.) of the optical transmission / reception device previously stored through the internal controller.

The light transmitting / receiving device having such a configuration is based on the premise of using a fixed wavelength light source 12, and has a feedback control structure for maintaining a stable light output using the transmitting light detector 13. However, when the wavelength independent light source is used, the detection function of the injection light source is essential. However, since the optical transmission and reception device of FIG. 1 detects and feeds back only the optical transmission output irrespective of the injection light source, the wavelength independent light source is properly driven. It's hard to do.

Therefore, when the optical transmitter / receiver using the wavelength independent light source is implemented by using the optical transmitter / receiver as shown in FIG. 1, the transmission light detector of the wavelength independent optical transmitter / receiver includes the light intensity of the wavelength independent light source and the injection light source. Light intensity is detected at the same time. Therefore, when implementing the wavelength independent optical transmitting and receiving device using the light source injected from the outside by using the optical transmitting and receiving device of FIG. 1, in particular, the optical transmission is performed according to the intensity of the injection light source that varies according to the optical transmission loss such as distance and connection. Due to the change in the light intensity detected from the detector, an error occurs in the feedback control for maintaining a stable light output (light intensity), which makes it difficult to maintain stable light transmission quality due to temperature changes and external conditions. In addition, the temperature control is an essential factor in maintaining a stable quality of the wavelength independent light source, but the optical transmitting and receiving device of FIG. 1 has no function of measuring or controlling the internal temperature. Although there may be a method of maintaining a certain temperature by the temperature control method of the wavelength independent light source, the light transmitting and receiving device of FIG. 1 has a disadvantage in that power consumption increases to maintain a constant temperature.

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical transmission apparatus capable of maintaining stable quality of light output by employing an injection light source detection function in an optical transmission and reception system for transmitting and receiving light using a wavelength independent light source, and an optical transmission and reception system therefor.

According to one aspect of the present invention, there is disclosed an optical transmission device and an optical transmission / reception system therefor, which can maintain stable quality of light output by employing an injection light source detection function.

An optical transmission device of the present invention includes a wavelength independent light source outputting a variable wavelength of light according to an injection light source, an injection light source detection unit operable to detect intensity and wavelength information of the injection light source, and intensity information of transmission light. A transmission light detector that operates, and a temperature controller that operates to detect temperature information inside the apparatus; And a light source driving control unit configured to output-control the intensity of the wavelength independent light source based on the intensity and wavelength information of the injection light source, the intensity information of the transmission light, and the temperature information inside the device. The apparatus may further include an injection light source generation unit provided outside the apparatus and operable to adjust the intensity of the injection light source under the control of the injection light source controller. In one embodiment, the injection light source detector is provided on the outside of the device, the intensity information of the transmission light, the intensity of the light output from the wavelength independent light source and the intensity of the light output from the injection light source generation unit. This is information. In another embodiment, the injection light source detecting unit is provided inside the apparatus, and the intensity information of the transmission light is intensity information of pure light output from the wavelength independent light source not including the injection light source.

In addition, the optical transmission device of the present invention, the wavelength independent light source that the wavelength of the light is output according to the injection light source; A transmission light detector operable to detect intensity information of the transmission light; A temperature control unit operative to detect temperature information inside the device; And a light source driving control unit configured to outputly control the intensity of the wavelength independent light source based on the intensity information of the transmission light and the temperature information inside the apparatus, wherein the intensity information of the transmission light is determined when the driving of the injection light source is stopped. The intensity information of the pure light output from the wavelength independent light source is information including the intensity of the light output from the wavelength independent light source and the intensity of the light output from the injection light source generator when the driving of the injection light source is restarted. The apparatus may further include an injection light source generation unit provided outside the apparatus and operable to adjust the intensity of the injection light source under the control of the injection light source controller.

The optical transmission device of the present invention is applied to an optical transmission / reception system for transmitting and receiving light using a wavelength independent light source in which the wavelength of the light is varied and output according to the injection light source.

According to the present invention, there is provided an optical transmission apparatus using a wavelength independent light source and a light output system including the same through a function of detecting an injection light source and temperature control of the wavelength independent light source required for proper driving of the wavelength independent light source. There is an advantage that can maintain a stable quality (light intensity).

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions will not be described in detail if they obscure the subject matter of the present invention.

The optical transmission device according to the present invention is applied to an optical transmission and reception system for transmitting and receiving light using a wavelength independent light source that is output by varying the wavelength of light according to the injection light source. An optical transmission / reception system using a wavelength independent light source includes an injection light source detection unit inside or outside the optical transmission and reception device as well as a transmission light detection unit having a feedback control structure for maintaining stable optical output (light intensity). The injection light source detection unit detects the intensity of the injection light source and transmits it to the light source driving control unit, and the light source driving control unit controls the wavelength independent light source to be properly driven. In addition, the optical transmission / reception system includes a temperature controller inside the optical transmission / reception apparatus. The temperature controller detects a change in external environmental conditions such as a temperature change and transmits it to the light source driving controller, and the temperature controller controls the temperature of the wavelength independent light source so that the wavelength independent light source can be properly driven.

As shown in FIG. 2, in the optical transmission system to which the optical transmission device according to the first embodiment of the present invention is applied, the injection light source controller 21 and the injection light source generator 22 are external to the optical transmission device 20. And an injection light source detecting unit 23, the light source driving control unit 24, the transmitting light detecting unit 25, the wavelength independent light source 26, the temperature control unit 27, the receiving light detecting unit inside the optical transmission and reception device 20. 28, a limiting amplifier 30, and a controller / memory 29 are provided.

The injection light source controller 21 is mounted in an external system (not shown), controls the injection light source generator 22 to control the intensity and wavelength characteristics of the injection light source, and controls the injection light source detected by the injection light source detector 23. Information (intensity and wavelength information of the injection light source) is received and provided to the controller / memory 29 of the optical transmission / reception apparatus 20 through a serial interface. Since the output of the injection light source used is very strong, it is designed to suppress the light output when the optical port for transmitting the output of the injection light source to the transmission and reception optical fiber is hernia. In this case, based on the system control signal input from the external system, the injection light source generation unit 22 interrupts or weakens the transmission output of the output injection light source.

The injection light source generator 22 adjusts the intensity of the injection light source injected into the optical transmission and reception, or stops or activates the drive according to the command of the injection light source controller 21.

The injection light source detector 23 detects the intensity and wavelength information of the injection light source generated by the injection light source generator 21 and transmits the information to the injection light source controller 21.

The light source driving control unit 24 is detected by the injection light source detecting unit 23 outside the optical transmission and reception apparatus 20 and the intensity and wavelength information of the injection light source stored in the control unit / memory 29 via the serial interface from the injection light source control unit 21. Is received from the external system, and the intensity data of the transmitted light fed back from the transmission system (differential signal) and the transmitted light detector 25 (in this case, the intensity information of the fed back light is output from the wavelength independent light source 26). (Light intensity) and light output (including light intensity) output from the injection light source generator 22 are input, and internal temperature information of the optical transmitter / receiver 20 detected by the temperature controller 27 is received. The light source driving controller 24 transmits input information, that is, the intensity and wavelength information of the injection light source detected by the external injection light source detector 23, a differential signal, and a part of the injection light source detected by the transmission light detector 25. Based on the light intensity information and the internal temperature information detected by the temperature control unit 27, arithmetic processing is performed, and a driving signal for driving the wavelength independent light source 26 is generated based on the arithmetic processing result. The light source driving control unit 24 may know the intensity and wavelength characteristic information of the light output from the wavelength independent light source 26 to the transmission / reception optical fiber as a result of the calculation process, and may detect transmission intensity and transmission failure of the output light. The detected information is stored in the controller / memory 29 or transmitted through a separate interface. In addition, the information on the internal temperature detected by the temperature control unit 27 may also be transmitted to the control unit / memory 29 to give information on the temperature of the optical transmission / reception device 20 to an external system. The light source driving controller 24 stops driving the wavelength independent light source 26 when a transmission stop command is input from the controller / memory 29.

The light source driving control unit 24 generates a driving signal by recomputing when the input information is changed. In an exemplary embodiment, the light source driving controller 24 may change the intensity and wavelength information of the injection light source detected by the external injection light source detector 23 or may include a part of the injection light source detected by the transmission light detector 25. When the intensity of the transmitted light is changed or when the internal temperature of the optical transmitter / receiver detected by the temperature control unit 27 is changed, the wavelength independent light source 26 is recalculated based on the changed information, and the wavelength independent light source 26 is used. Control to output the appropriate intensity of the optical signal.

The transmission light detector 25 detects the light output (light intensity) output from the wavelength independent light source 26 and the light output (light intensity) output from the injection light source generator 22, and this information (transmission light of Intensity information) is transmitted to the light source driving controller 24.

The wavelength independent light source 26 generates an optical signal having a predetermined wavelength according to a driving signal from the light source driving control unit 24 and outputs the optical signal to the transmission / reception optical fiber. In one embodiment, selectively outputting light of a specific wavelength desired through an injection locking process for injecting an auxiliary light, which is a broadband light source (BLS), into a Fabry-Perot laser diode (FP-LD). can do. That is, when a light source having a specific light wavelength is injected into the FP-LD, only the mode corresponding to the wavelength is oscillated greatly and other modes are suppressed. Accordingly, the FP-LD can output an optical signal close to a single mode rather than a multi-mode output, and the wavelength is independent of the wavelength-dependent light source 26 because the injection locked light source is determined according to the wavelength of the external injection light (auxiliary light). It is possible to use as. In addition, the wavelength independent light source 26 may use a semiconductor optical amplifier (SOA) for amplifying and modulating an auxiliary light source or a reflective semiconductor amplifier (RSOA) for reflecting, amplifying and modulating an auxiliary light source. . In addition, the auxiliary light source may be separately configured to be injected into the wavelength independent light source 26, and a portion of the received optical signal applied to the optical transmission and reception device 20 is diverted and used as the auxiliary light, the wavelength independent light source 26 Can also be injected into.

The temperature control unit 27 detects a temperature change in the light transmitting and receiving device 20 and transmits it to the light source driving control unit 24, and adjusts the temperature of the wavelength independent light source 26 according to a command of the light source driving control unit 24. This allows the wavelength independent light source 26 to be properly driven. At this time, the temperature control does not control to maintain the wavelength independent light source 26 at a constant temperature at all times, but only when the detected external temperature is lower than a preset threshold to affect the characteristics of the wavelength independent light source 26. To control. The temperature controller 27 controls a heater or a thermoelectric cooler attached to the wavelength independent light source 26.

The reception light detector 28 converts the optical signal received through the transmission and reception optical fiber into an electrical signal and transmits the signal to the limiting amplifier 30.

The limiting amplifier 30 amplifies an electric signal received from the reception light detector 28 to make a differential signal and transmits the differential signal to an external system. The limiting amplifier 30 detects the reception power and reception failure by comparing the magnitude of the reception signal with a preset threshold, and transmits the information to the controller / memory 29.

The controller / memory 29 performs serial interface communication (eg, a 2-wire serial interface) with an external system, and stores commands from the external system and data processed therein so that they can be transmitted to the external system.

As shown in FIG. 3, in the optical transmission system to which the optical transmission apparatus according to the second embodiment of the present invention is applied, an injection light source controller 21 and an injection light source generator 22 are external to the optical transmitter and receiver 20. And a light source driving control unit 24, a transmission light detecting unit 25, a wavelength independent light source 26, a temperature control unit 27, a reception light detecting unit 28, and a limited amplification unit inside the optical transmitting and receiving device 20. 30, a control unit / memory 29 is provided. The optical transmission / reception system to which the optical transmission device according to the second embodiment of the present invention is applied is similar to the optical transmission / reception system to which the optical transmission device according to the first embodiment is applied. And explain only what is discriminated.

The injection light source controller 21 is mounted in an external system (not shown) and controls the injection light source generator 22 to control the intensity and wavelength characteristics of the injection light source.

The light source driving control unit 24 receives the transmission data (differential signal) transmitted from an external system, and the transmission detected by the transmission light detecting unit 25 when the driving of the injection light source output from the injection light source generating unit 22 is stopped. When the light intensity information is input and set as the light intensity reference value of the wavelength independent light source 26, and the injection light source is driven and output by the injection light source generator 22, the wavelength of the transmitted light output from the wavelength independent light source 26 is output. A signal including the intensity and the intensity of the injection light source injected by the injection light source generator 22 is input, and internal temperature information of the optical transmitter / receiver 20 detected by the temperature controller 27 is received. The light source driving controller 24 performs arithmetic processing based on input information, that is, a light intensity reference value or intensity information of a transmission light including a part of an injection light source, and internal temperature information. Generates a drive signal for driving. The light source driving control unit 24 generates a driving signal by recomputing when the input information is changed. In one embodiment, the light source driving control unit 24 changes the information when the intensity of the transmission light detected by the transmission light detection unit 25 is changed or when the internal temperature of the optical transmission / reception device detected by the temperature control unit 27 is changed. Based on the recomputation processing result, the wavelength independent light source 26 controls the output of the appropriate light signal intensity.

The transmission light detector 25 detects the light output from the wavelength independent light source 26 when driving of the injection light source generator 22 is stopped, and transmits this information (intensity information of the transmitted light) to the light source drive controller 24. To send). The intensity information of the transmitted light becomes the light intensity reference value of the wavelength independent light source 26. The transmission light detector 25 detects the light output from the wavelength independent light source 26 and the light output from the injection light source generator 22 when driving of the injection light source generator 22 is activated. This information (intensity information of the transmitted light) is transmitted to the light source drive control unit 24.

As shown in FIG. 4, in the optical transmission system to which the optical transmission device according to the third embodiment of the present invention is applied, the injection light source controller 21 and the injection light source generator 22 are external to the optical transmission device 20. And an injection light source detecting unit 23, a light source driving control unit 24, a transmission light detecting unit 25, a wavelength independent light source 26, a temperature control unit 27, and a reception light detecting unit inside the optical transmitting and receiving device 20. 28, a limiting amplifier 30, a control unit / memory 29, and an optical branch unit 31. Since the optical transmission / reception system to which the optical transmission device according to the third embodiment of the present invention is applied is similar to the optical transmission / reception system to which the optical transmission device according to the first embodiment is applied, the same parts of both will be omitted. Only explain what is different.

The light source driving control unit 24 receives the transmission data (differential signal) transmitted from an external system and the intensity and wavelength information of the injection light source detected by the injection light source detection unit 23 inside the optical transmission / reception device 20, and transmits the transmission light. The optical transmission / reception apparatus detected by the temperature control unit 27 by receiving intensity information of the transmitted light fed back from the detector 25 (in this case, the intensity information of the fed-in feedback light is the light output from the wavelength independent light source 26). Receive internal temperature information of 20). In this case, the intensity information of the transmission light detected by the transmission light detector 25 does not include the injection light source generated by the injection light source generator 22. The reason is that the injection light source does not flow into the transmission light detection unit 25 by the optical branch unit 31 provided in front of the wavelength independent light source 26. Therefore, a part of the injection light source flows into only the injection light source detector 23, and the injection light source detector 23 detects a part of the injection light source. The light source driving control unit 24 transmits input information, that is, pure transmission without including the intensity and wavelength information of the injection light source detected by the internal injection light source detector 23, the differential signal, and the injection light source detected by the transmission light detector 25. Based on the light intensity information and the internal temperature information detected by the temperature control unit 27, arithmetic processing is performed, and a driving signal for driving the wavelength independent light source 26 is generated based on the arithmetic processing result. The light source driving control unit 24 may know the intensity and wavelength characteristic information of the light output from the wavelength independent light source 26 to the transmission / reception optical fiber as a result of the calculation process, and may detect transmission intensity and transmission failure of the output light.

The light source driving control unit 24 generates a driving signal by recomputing when the input information is changed. In an exemplary embodiment, the light source driving controller 24 may not change the intensity and wavelength information of the injection light source detected by the injection light source detector 23, or may not include the injection light source detected by the transmission light detector 25. When the intensity of pure transmission light is changed or the internal temperature of the optical transmission / reception apparatus detected by the temperature control unit 27 is changed, the wavelength independent light source 26 is recalculated based on the changed information and based on the recalculation result. Controls the output of the appropriate optical signal intensity.

The injection light source detecting unit 23 receives the injection light source flowing from the optical branch unit 31, detects the intensity and wavelength information of the injection light source, and transmits the information to the light source driving control unit 24.

The transmission light detection unit 25 detects the intensity of the light output from the wavelength independent light source 26 and transmits this information (intensity information of the transmission light) to the light source driving control unit 24.

Although the present invention has been described in connection with some embodiments thereof, it should be understood that various changes and modifications may be made therein without departing from the spirit and scope of the invention as understood by those skilled in the art. something to do. It is also contemplated that such variations and modifications are within the scope of the claims appended hereto.

1 is a view showing the configuration of an optical transmission and reception system according to the prior art.

2 is a diagram showing the configuration of an optical transmission / reception system to which an optical transmission device is applied according to a first embodiment of the present invention.

3 is a diagram showing the configuration of an optical transmission / reception system to which an optical transmission device is applied according to a second embodiment of the present invention.

4 is a diagram showing the configuration of an optical transmission / reception system to which an optical transmission device is applied according to a third embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

21: injection light source control unit 22: injection light source generation unit

23: injection light source detection unit 24: light source driving control unit

25: transmission light detector 26: wavelength independent light source

27: temperature controller 28: reception light detector

29 control unit / memory 30 limiting amplifier

31: optical branch

Claims (12)

In the optical transmission device, A wavelength independent light source outputting a variable wavelength of light according to the injection light source; An injection light source detector operable to detect intensity and wavelength information of the injection light source; A transmission light detector operable to detect intensity information of the transmission light; A temperature control unit operative to detect temperature information inside the device; And And a light source driving control unit configured to outputly control the intensity of the wavelength independent light source based on the intensity and wavelength information of the injection light source, the intensity information of the transmission light, and the temperature information of the inside of the device. The method of claim 1, And an injection light source generation unit provided outside the apparatus and operable to adjust the intensity of the injection light source under the control of the injection light source controller. The method of claim 2, The injection light source detecting unit is provided outside the device. The method of claim 3, The intensity information of the transmission light is information including an intensity of light output from the wavelength independent light source and an intensity of light output from the injection light source generation unit. The method of claim 2, And the injection light source detecting unit is provided inside the apparatus. The method of claim 5, And the intensity information of the transmission light is intensity information of pure light output from the wavelength independent light source not including the injection light source. The method of claim 6, And an optical branching unit which prevents the injection light source generated by the injection light source generation unit from flowing into the transmission light detection unit and introduces only the injection light source detection unit. In the optical transmission device, A wavelength independent light source outputting a variable wavelength of light according to the injection light source; A transmission light detector operable to detect intensity information of the transmission light; A temperature control unit operative to detect temperature information inside the device; And And a light source driving controller configured to control output of the intensity of the wavelength independent light source based on the intensity information of the transmitted light and the temperature information inside the device. The intensity information of the transmission light is intensity information of pure light output from the wavelength independent light source when the driving of the injection light source is stopped, and the intensity of the light output from the wavelength independent light source and the injection when the driving of the injection light source is resumed. The optical transmission device which is information including the intensity of the light output from the light source generator. The method of claim 8, And an injection light source generation unit provided outside the apparatus and operable to adjust the intensity of the injection light source under the control of the injection light source controller. The method according to any one of claims 1 to 9, The temperature control unit detects a temperature change inside the device, transmits the detected information to a light source driving control unit, and is driven only when the temperature is lower than or equal to a preset threshold value in adjusting the temperature of the wavelength independent light source. , Optical transmission device. The method according to any one of claims 2 to 9, The injection light source control unit controls to interrupt or weaken the output of the injection light source output from the injection light source generating unit by generating a system control signal when dismounting the optical port transferring the output of the injection light source. Transmitting device. An optical transmission / reception system including the apparatus of claim 10, wherein the light is transmitted and received using a wavelength independent light source that is output by varying the wavelength of the light according to the injection light source.

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