JP2008244047A - Optical transceiver module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a compact and economical optical transceiver module capable of taking route redundancy of an optical link, using a pair of two modules. <P>SOLUTION: The optical transceiver module 10 has at least one pair of two main light signal input/output ports and one pair of two main electrical signal input/output terminals. One of the pair of two main electrical signal input/output terminals inputs a main electrical signal, and the other outputs the main electrical signal. One of the pair of two main light signal input/output ports transmits/receives the main light signal by using different wavelengths for transmission and reception, and the other likewise transmits/receives the main light signal by using different wavelengths for the transmission and reception. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an optical transceiver module.

  An optical communication apparatus for performing bidirectional optical communication using an optical fiber as a medium includes optical transmission / reception means, signal processing means, monitoring control means, and the like. The optical transmission / reception module is obtained by modularizing the optical transmission / reception means.

  FIG. 4 is a configuration diagram of a conventional optical transceiver module. As shown in FIG. 4, the optical transceiver module 40 includes an optical transmission sub-module 41, an optical reception sub-module 42, an optical transmission sub-module driving unit 43, and a reception signal equalization unit 44. It is common to mount monitoring control means 45 for performing control and monitoring of received power.

  The optical transmission submodule 41 has a built-in laser diode, and directly or on-modulates the current of the laser diode with an electric signal, or when a modulation element is built in together with the laser diode, the electrical transmission to the modulation element is performed. By transmitting the signal, an on-off modulated optical signal is obtained. The optical reception submodule 42 is generally composed of a photodiode and a transimpedance amplifier, and outputs an on / off modulated optical signal as an electric signal based on a voltage.

  By modularizing the optical transmission / reception means part in the optical communication device, the optical transmission / reception function part can be shared regardless of the type of device and the type of signal. By replacing it, it is possible to cope with various transmission wavelengths and transmission distances. For these reasons, the shape of the optical transmission / reception module 40 and the common use of the electric input / output interface are in progress.

  For example, there is a shape called SFP (Small form factor pluggable) at a transmission rate of several gigabits / second or less and an X-input / output interface that is called XFP (10 Gigabit small factor pluggable) at a transmission rate of 10 gigabits / second. The detailed configuration of the SFP is disclosed in, for example, Non-Patent Document 1 below.

  In order to connect two points using the optical transceiver module 40 shown in FIG. 4, usually, two optical transceiver modules 40 are opposed to each other and arranged at two points, and these are formed by two optical fibers. Connecting. However, from the viewpoint of effective use of optical fibers, lasers having different output wavelengths are applied to the lasers of the respective optical transmission / reception modules 40, and the transmission wavelength and the reception wavelength are multiplexed and separated with respect to one optical fiber. By adding a wavelength division multiplexing (WDM) filter 57 (see FIG. 5), the two points can be connected by a single optical fiber.

  In particular, a standard recommendation G.A. from the Telecommunications Sector (ITU-T) of the International Telecommunications Union. 983.3 and G.M. Optical access networks such as those described in detail in 984.2 are premised on communication using one optical fiber, and a single-fiber bidirectional optical transceiver module shown in FIG. ing.

  FIG. 5 is a configuration diagram of a single-fiber bidirectional optical transceiver module. As shown in FIG. 5, the bidirectional optical transceiver module 50 includes a bidirectional optical transceiver submodule 51, a laser driving unit 52, and a reception signal equalizing unit 53. In general, a monitoring control means 54 for monitoring or the like is installed.

  The bidirectional optical transmission / reception submodule 51 includes a laser diode 55, a photodiode 56, and a WDM filter 57. In this example, the laser is directly modulated with an electrical signal. The detailed configuration of the bidirectional optical transmission / reception submodule 51 is disclosed in, for example, Non-Patent Document 2 below.

  In addition, in order to perform high-speed or long-distance transmission, direct modulation may have insufficient characteristics, and external modulation may be applied. FIG. 6 is a configuration example of a bidirectional optical transmission / reception submodule when external modulation is applied. In this bidirectional optical transmission / reception submodule 60, an external modulation element 62 is disposed adjacent to a laser diode 61, and an optical signal is generated by driving the modulation element 62 with an electric signal. Accordingly, the laser driving means 52 in FIG. 5 becomes a modulation element driving means.

  In addition, the standard recommendation G.A. 983.3 and G.M. An optical access network as described in detail in 984.2 is a network called a point-to-multipoint passive optical network (PON). FIG. 7 is a configuration diagram of a conventional passive optical network. As shown in FIG. 7, the optical line terminal 70 normally arranged in a network operator building communicates with a plurality of n optical network units 72 arranged on the user side via an optical splitter 71 having n branches. Do.

  Both the optical line terminal 70 and the optical network unit 72 include an optical transmission / reception module 73 and a signal processing circuit 74. The optical transmission / reception module 73 in FIG. 7 has the configuration shown in FIG. 6, for example, and performs communication using different wavelengths by transmission / reception with one optical fiber. The optical transmission / reception module 73 exchanges a supervisory control signal in order to exchange bidirectional main electrical signals with the signal processing circuit 74 and to enable the presence / absence monitoring of the reception optical signal and the forced stop of the transmission optical signal. .

  The signal processing circuit 74 is a circuit that performs termination and processing of a frame (for example, an ATM frame in ITU-TG.983). The signal processing circuit of the optical line terminal 70 performs timing control on the signal processing circuit 74 of each optical network unit 72 so that signals transmitted from the plurality of optical network units 72 do not have the same timing.

M.M. Ichino, eight others, "Small Form Factor Pluggable Optical Transceiver Module with Extremely Low Power Consumption for Dense Wavelength Division Multiplexing Applications", 2005 Electronic Components and Technology Conference, IEEE, 2005, Vol. 1, p. 1044-1049 M.M. L. Tsai, 7 others, “Fiber-Based BiDi Transceiver Module Using Optical Subsemble with an Injection Molded Polymer Optical Bench”, 2005 Electron 1, p. 1629-1633

  However, in order to achieve path redundancy in point-to-point communication using the conventional optical transmission / reception module described above, two active and standby optical transmission / reception modules are required at each point, for a total of four at two points. A small optical transceiver module is required.

Further, when the connection between two points is performed with the one-fiber bidirectional optical transceiver module facing each other, the laser output wavelengths of the two facing modules need to be different. In other words, different types of single-fiber bidirectional optical transceiver modules are required at each point, and the type management of the optical transceiver modules is complicated.

  Further, in the optical network unit and the optical line terminal applied to the passive optical network, it is necessary to change the signal processing circuit provided in the optical network unit or the optical line terminal in order to make the optical transmission section redundant. This is difficult for practical reasons.

  In view of the above, an object of the present invention is to provide a small and economical optical transmission / reception module that can take path redundancy of an optical link by a pair of two.

An optical transceiver module according to a first invention (corresponding to claim 1) for solving the above-described problem is
An optical transceiver module having at least one to two main optical signal input / output ports and one to two main electrical signal input / output terminals;
Of the one-to-two main electric signal input / output terminals, one performs the input of the main electric signal, the other performs the output of the main electric signal,
Of the one-to-two main optical signal input / output ports, one transmits and receives main optical signals using different wavelengths for transmission and reception, and the other also uses main wavelengths using different wavelengths for transmission and reception. Signal transmission / reception is performed.

An optical transceiver module according to a second invention (corresponding to claim 2) for solving the above-mentioned problems is the optical transceiver module according to the first invention,
The optical transceiver module comprises two bidirectional optical transceiver submodules, transmission signal branching and optical transceiver submodule driving means, and reception signal selection and equalization means,
The reception signal selection and equalization means selects one of the reception electric signal outputs from the two bidirectional optical transmission / reception submodules and equalizes and sends to one of the electric signal input / output terminals,
The transmission signal branching and optical transmission / reception submodule driving means branches the input from the other main electric signal input / output terminal to drive the two bidirectional optical transmission / reception submodules.

An optical transceiver module according to a third invention (corresponding to claim 3) for solving the above-mentioned problems is an optical transceiver module according to the second invention,
The reception signal selection and equalization means compares the intensity or amplitude of the current or voltage of the reception electric signal output from the two bidirectional optical transmission / reception sub-modules, and selects the one with the larger intensity or amplitude to select the main electric The signal is sent to one of the signal input / output terminals.

An optical transceiver module according to a fourth invention (corresponding to claim 4) for solving the above-described problems is the optical transceiver module according to the second invention,
The reception signal selection and equalization means is a selection means for selecting one after retiming both of the reception electrical signal outputs from the two bidirectional optical transmission / reception submodules. Of the received electrical signals, the side that can reproduce the clock necessary for retiming is selected.

An optical transceiver module according to a fifth invention (corresponding to claim 5) for solving the above-mentioned problems is the optical transceiver module according to the fourth invention,
In the case where the necessary clocks can be reproduced by both received electric signals, the intensity or amplitude of the current or voltage of the received electric signal output is compared, and the one having the larger amplitude is selected.

An optical transceiver module according to a sixth invention (corresponding to claim 6) for solving the above-described problems is an optical transceiver module according to any one of the second invention to the fifth invention,
Of the two bidirectional optical transceiver sub-modules,
One transmits at the first wavelength and receives at the second wavelength,
The other is characterized by transmitting at the second wavelength and receiving at the first wavelength.

An optical transceiver module according to a seventh invention (corresponding to claim 7) for solving the above-described problems is an optical transceiver module according to any one of the second invention to the fifth invention,
Of the two bidirectional optical transceiver sub-modules,
One is composed of at least a photodiode, a laser diode that emits light at the first wavelength, and a wavelength filter that demultiplexes the first wavelength and the second wavelength,
The other includes at least a photodiode, a laser diode that emits light at the second wavelength, and a wavelength filter that demultiplexes the first wavelength and the second wavelength.

According to the present invention, path redundancy of an optical link can be achieved using two pairs of small optical transceiver modules. Further, when the two modules are connected with the modules facing each other, the same module can be used for the two modules facing each other in the one-fiber bidirectional transmission.
Furthermore, when applied to a passive optical network, a general-purpose signal processing circuit that does not support redundancy can be used, and economical redundancy is possible.

  Various embodiments of the optical transceiver module according to the present invention will be described with reference to FIGS. FIG. 1 is a block diagram of an optical transceiver module according to the first embodiment, FIG. 2 is a block diagram of an optical transceiver module according to the second embodiment, and FIG. 3 is a block diagram of an optical transceiver module according to the third embodiment. It is.

[First Embodiment]
FIG. 1 shows a configuration of an optical transceiver module according to the first embodiment of the present invention. As shown in FIG. 1, the optical transceiver module 10 includes two bidirectional optical transceiver submodules 11, branch and optical transceiver submodule driving means 12, received signal selection and equalization means 13, transmission power monitoring and control, In addition, the monitoring control unit 14 is configured to monitor received power.

  The bidirectional optical transmission / reception submodule 11 is configured as a part of FIG. 5 described as the prior art or as shown in FIG. The monitoring control unit 14 performs transmission power monitoring and control, reception power monitoring, and the like.

  The optical transmission / reception module 10 has optical signal input / output ports of two optical fibers 17 as the optical signal transmission / reception interface 15, and each transmits and receives the same signal. That is, 1 + 1 path redundancy is provided, and the optical transceiver module 10 operates so that communication does not stop even when one optical fiber 17 is cut.

  The electric signal transmission / reception interface 16 includes a main electric signal input / output terminal. A main signal (electricity) 19-2 input from this terminal is input to the branching and bidirectional optical transmission / reception submodule driving means 12, and two signals are input. Is then converted into a drive signal of a predetermined condition for driving the laser or the modulation element in the bidirectional optical transmission / reception submodule 11 (for example, a binary digital signal sandwiches a laser oscillation threshold value) Or after being converted into a drive signal, it branches into two. Two drive signals (transmission signal 20) obtained in this way are respectively input to the two bidirectional optical transmission / reception submodules 11 to obtain two main signals (light) 18-2 to be transmitted.

  The optical signal transmission / reception interface 15 is composed of two optical fibers 17, and two received main signals (light) 18-1 input from the optical fiber 17 are input to different bidirectional optical transmission / reception submodules 11. It is converted into an electric reception signal 21. These are input to the reception signal selection and equalization means 13, and one of them is equalized and output to the electric signal transmission / reception interface 16 as the main signal (electricity) 19-1. Alternatively, either one may be selected after both are equalized. For example, the equalization means performs amplification, removal of unnecessary frequency components, retiming, and the like.

  As a selection criterion, for example, the stronger one is selected by comparing the intensity or amplitude of the current or voltage of the reception signal 21 output from the two bidirectional optical transmission / reception submodules 11. As another example, it is assumed that either one is selected after both are equalized, the retiming is performed in the equalization circuit, and the side on which the clock necessary for retiming can be reproduced is selected. . When the clocks are regenerated in both equalization circuits, the stronger one is selected by comparing the intensity or amplitude of the current or voltage of the reception signal 21 output from the two bidirectional optical transmission / reception submodules 11. I will do it.

  Further, in the optical transceiver module 10, the electrical signal transmission / reception interface 16 including the main electrical signal input / output terminal can be hot-plugged / removed from / to the signal processing device (that is, the module in the normal operation can be replaced by supplying power) Then, it can be easily replaced for various uses such as transmission distance, and can be easily replaced with a normal optical transmission / reception module that does not support redundancy. Thus, according to the present embodiment, the main electrical signal input / output terminal can be hot-swapped with respect to the signal processing device.

  Particularly, by making the shape of the optical transceiver module 10 into the SFP or XFP shape, general-purpose components can be applied to components such as a housing and an electrical interface, and the optical transceiver module 10 is small and economical. Can be configured. With such a configuration, it is possible to take a redundant path of an optical link by using two pairs of small optical transceiver modules 10.

  The monitoring control unit 14 monitors which of the two main optical signals to be received is output from the optical transceiver module 10 as the main electrical signal, and obtains this information from the outside of the optical transceiver module 10. This is effective because it is possible to infer which optical fiber 24 has a failure when the selected optical signal is switched.

  Further, the supervisory control unit 14 can control which of the two main optical signals to be received is output from the optical transceiver module 10 as the main electrical signal by a command from the outside of the optical transceiver module 10. For example, this is effective when one of the optical fibers 24 is replaced with another optical fiber.

[Second Embodiment]
FIG. 2 is a diagram showing an application of the optical transceiver module in the second embodiment of the present invention. This is a configuration in which one-fiber bidirectional transmission is performed by the same two optical transceiver modules 10 (see FIG. 1).

  Here, the optical transceiver modules 10a and 10b have the same configuration as that shown in the first embodiment. In addition, the two bidirectional optical transceiver submodules 11a and 11b to be mounted have output wavelengths of , Wavelength 1 and wavelength 2. The WDM filter 57 (see FIG. 5) arranged in the bidirectional optical transmission / reception submodules 11a and 11b can demultiplex wavelength 1 and wavelength 2.

  As shown in FIG. 2, a bidirectional optical transmission / reception submodule 11a for transmitting wavelength 1 of the optical transmission / reception module 10a on the left side in FIG. 2 with two optical transmission / reception modules 10 (see FIG. 1) facing each other is shown in FIG. A bidirectional optical transceiver submodule for transmitting wavelength 2 of the optical transceiver module 10a on the left side in FIG. 2 so as to be connected to the bidirectional optical transceiver module 11b for transmitting wavelength 2 of the middle optical transceiver module 10b. The connection is performed so that 11b is connected to the bidirectional optical transmission / reception submodule 11a that transmits the wavelength 1 of the optical transmission / reception module 10b on the right side in FIG.

  In the conventional single-fiber bidirectional transmission, different types of optical transmission / reception modules 10a and 10b have to be applied to each other. One-core bidirectional transmission can be performed using the same module as the modules 10a and 10b.

  The monitoring control means 14 monitors which of the two main optical signals to be received is output from the optical transmission / reception modules 10a and 10b as the main electric signal, and this is transmitted from the outside of the optical transmission / reception modules 10a and 10b. If information can be obtained, it is effective because it is possible to estimate which optical fiber 24 has a failure when the selected optical signal is switched.

  Further, the supervisory control unit 14 determines which of the two main optical signals to be received is to be output from the optical transmission / reception modules 10a and 10b as a main electrical signal by a command from the outside of the optical transmission / reception modules 10a and 10b. If it can be controlled, it is effective when one of the optical fibers 24 is replaced with another optical fiber.

  In order to manufacture the small and economical bidirectional optical transmission / reception submodules 11a and 11b, it is necessary to arrange the transmission optical axis and the reflection optical axis of the WDM filter to be about 90 ° as shown in FIG. However, in this case, if the interval between the wavelength 1 and the wavelength 2 is not secured to some extent, the WDM filter cannot be realized, and the interval between the wavelength 1 and the wavelength 2 is ensured to be several tens nm or more. It is known that it can be realized economically. Standard Recommendation G. by ITU-T. 983.3 and G.M. In 984.2, the upstream (optical network unit → optical line terminal) wavelength is defined as 1310 nm (± 50 nm), and the downstream (optical line terminal → optical network unit) wavelength is defined as 1490 nm (± 5 nm).

  Accordingly, the optical transceiver modules 10a and 10b described in the present embodiment can be realized economically if the wavelength 1 is 1310 nm and the wavelength 2 is 1490 nm or vice versa. Thus, wavelength 1 includes a wavelength band of 1310 nm, and wavelength 2 includes a wavelength band of 1490 nm.

  By the way, in order to create a small bidirectional optical transceiver sub-module 11a, 11b by omitting the laser temperature stabilization circuit, the wavelength ranges of the wavelength 1 and the wavelength 2 are set in consideration of the temperature fluctuation of the laser wavelength. It is known that it needs to be 10 nm to 15 nm or more. Further, in order to create a small bidirectional optical transmission / reception submodule 11a, 11b by applying an economical WDM filter, the interval between the wavelength 1 and the wavelength 2 is set to the same range of the transmission wavelength range of the wavelength 1 and the wavelength 2. It is known that it is good to secure about twice. That is, by setting the interval between the wavelength 1 and the wavelength 2 to 20 nm or more, the small-sized and economical bidirectional optical transceiver module 10a, 10b can be realized.

  In addition, wavelength bands that can be transmitted with low loss in a single mode optical fiber are 1260 nm to 1360 nm and 1450 nm to 1620 nm, and 1360 nm to 1450 nm has a large loss. For this reason, when the wavelength 1 is included in 1260 nm to 1360 nm and the wavelength 2 is included in 1450 nm to 1620 nm, the small-sized and economical bidirectional optical transceiver modules 10 a and 10 b can be realized.

  Furthermore, since 1450 nm to 1620 nm has a lower loss than 1260 nm to 1360 nm in a single-mode optical fiber, the transmission distance can be increased by arranging both wavelength 1 and wavelength 2 at 1450 nm to 1620 nm. In other words, both the wavelength 1 and the wavelength 2 are included in the range of 1450 nm to 1620 nm, and the wavelength 1 and the wavelength 2 are set to have an interval of 20 nm or more even if the wavelength variation due to the temperature or the like is taken into consideration. In addition, the bidirectional optical transceiver modules 10a and 10b having a long fiber transmission distance can be realized.

  However, the degradation due to wavelength dispersion of the optical fiber is minimized in the vicinity of 1310 nm. Since signal quality degradation due to chromatic dispersion cannot be ignored in high-speed communication of 10 giga or more, signal quality degradation due to chromatic dispersion can be reduced by arranging both wavelength 1 and wavelength 2 at 1260 nm to 1360 nm. In other words, both the wavelength 1 and the wavelength 2 are included in 1260 nm to 1360 nm, and the wavelength 1 and the wavelength 2 are set to have an interval of 20 nm or more even when the wavelength variation due to the temperature or the like is taken into consideration. In addition, the bidirectional optical transceiver modules 10a and 10b can be realized with less signal quality degradation due to wavelength dispersion.

[Third Embodiment]
FIG. 3 is a diagram showing another application of the optical transceiver module according to the third embodiment of the present invention. This is an example in which the optical transceiver module 10 of the present invention is applied to a point-to-multipoint passive optical network (PON). For PON, the standard recommendation G.I. 983.3 and G.M. 984.2 and the like. The optical transceiver module 10 has the same configuration as that shown in the first embodiment.

  In the conventional PON, the optical transceiver modules 10, 10a, and 10b described in the first and second embodiments are applied instead of the bidirectional optical transceiver module provided in the optical network unit and the optical line terminal. Two sections of the optical fibers 30 and 31 and the optical splitter 32 between the optical network unit and the optical line terminal are arranged in the same manner.

  In the conventional PON, in order to make the section from the optical line terminal to the optical network unit redundant, the optical network unit (or optical line terminal) includes two optical transmission / reception modules, and a signal processing circuit for the two. It was necessary to switch and select the transmission / reception signal.

  However, according to the configuration shown in FIG. 3, the signal processing circuit 33 does not need to be aware of path redundancy. For this reason, a general-purpose (that is, economical) optical network unit (or optical line terminal) that does not support path redundancy has the same shape and electrical signal interface as the conventional PON optical transceiver module. By applying the optical transceiver module 10, 10a, 10b of the second embodiment, path redundancy can be achieved economically.

  However, since the timing control performed between the optical line terminal and the optical network unit is not aware of which of the duplexed paths is used for communication, the difference in transmission delay between the two duplexed paths Must be low. Specifically, optical signals from a plurality of optical network units whose timings are controlled are arranged in different time regions with a certain guard time. The difference in the amount of transmission delay between the above-mentioned two paths needs to be set so as not to exceed this guard time.

  In the case of PON, the upstream (optical network unit → optical line terminal) wavelength is defined as 1310 nm (± 50 nm), and the downstream (optical line terminal → optical network unit) wavelength is defined as 1490 nm (± 5 nm). The two optical transmission / reception submodules in the network unit may both transmit 1310 nm, and the two optical transmission / reception submodules in the optical line terminal may both transmit 1490 nm.

  The present invention can be applied to, for example, an optical transmission / reception module used for communication using an optical fiber as a medium.

1 is a configuration diagram of an optical transceiver module according to a first embodiment. Configuration diagram of optical transceiver module according to second embodiment The block diagram of the optical transmission-and-reception module which concerns on 3rd Embodiment Configuration diagram of conventional optical transceiver module Configuration diagram of single-fiber bidirectional optical transceiver module Another block diagram of bi-directional optical transceiver submodule when external modulation is applied Configuration diagram of conventional passive optical network

Explanation of symbols

DESCRIPTION OF SYMBOLS 10, 10a, 10b Optical transmission / reception module 11 Bidirectional optical transmission / reception submodule 11a Bidirectional optical transmission / reception submodule 11 which transmits wavelength 1 Bidirectional optical transmission / reception submodule 12 which transmits wavelength 2 Branch and optical transmission / reception submodule drive means 13 Reception Signal selection and equalization means 14 Supervisory control means 15 Optical signal transmission / reception interface 16 Electrical signal transmission / reception interface 17, 24, 30, 31 Optical fiber 18-1 Main signal (light) to be received
18-2 Main signal to transmit (light)
19-1, 19-2 Main signal (electricity)
20 Transmission signal (drive signal)
21 Received signal 22, 23 Monitoring control signal (electric)
32 Optical splitter 33 Signal processing circuit

Claims (7)

An optical transceiver module having at least one to two main optical signal input / output ports and one to two main electrical signal input / output terminals;
Of the one-to-two main electric signal input / output terminals, one performs the input of the main electric signal, the other performs the output of the main electric signal,
Of the one-to-two main optical signal input / output ports, one transmits and receives main optical signals using different wavelengths for transmission and reception, and the other also uses main wavelengths using different wavelengths for transmission and reception. An optical transceiver module that performs transmission and reception of signals. The optical transceiver module according to claim 1,
The optical transceiver module comprises two bidirectional optical transceiver submodules, transmission signal branching and optical transceiver submodule driving means, and reception signal selection and equalization means,
The reception signal selection and equalization means selects one of the reception electric signal outputs from the two bidirectional optical transmission / reception submodules and equalizes and sends to one of the electric signal input / output terminals,
The optical transmission / reception module, wherein the transmission signal branching and optical transmission / reception submodule driving means branches the input from the other main electric signal input / output terminal to drive the two bidirectional optical transmission / reception submodules. The optical transceiver module according to claim 2,
The reception signal selection and equalization means compares the intensity or amplitude of the current or voltage of the reception electric signal output from the two bidirectional optical transmission / reception sub-modules, and selects the one with the larger intensity or amplitude to select the main electric An optical transceiver module characterized by being sent to one of signal input / output terminals. The optical transceiver module according to claim 2,
The reception signal selection and equalization means is a selection means for selecting one after retiming both of the reception electrical signal outputs from the two bidirectional optical transmission / reception submodules. An optical transmission / reception module that selects a side of a received electrical signal that can reproduce a clock necessary for retiming. The optical transceiver module according to claim 4,
Optical transmission / reception characterized by comparing the strength or amplitude of the current or voltage of the received electrical signal output and selecting the larger amplitude when the necessary clock is recovered by both received electrical signals module. The optical transceiver module according to any one of claims 2 to 5,
Of the two bidirectional optical transceiver sub-modules,
One transmits at the first wavelength and receives at the second wavelength,
The other is an optical transmission / reception module that transmits at a second wavelength and receives at a first wavelength. The optical transceiver module according to any one of claims 2 to 5,
Of the two bidirectional optical transceiver sub-modules,
One is composed of at least a photodiode, a laser diode that emits light at the first wavelength, and a wavelength filter that demultiplexes the first wavelength and the second wavelength,
The other is composed of at least a photodiode, a laser diode that emits light at the second wavelength, and a wavelength filter that demultiplexes the first wavelength and the second wavelength.

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