JP2005039358A - Optical transmission module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a low-cost optical transmission module in simple shape in which interference between a light emission part and a light reception part is prevented and faulty wiring of an optical fiber for transmission and an optical fiber for reception are prevented. <P>SOLUTION: The optical transmission module is equipped with an optical transmission part 12 which converts an electric signal for transmission into an optical signal and transmits the optical signal, an optical reception part 14 which is adjacent to the optical transmission part and converts a received optical signal into an electric signal, a signal input part 19 which inputs the electric signal converted by the optical transmission part, a signal output part 20 which outputs the electric signal converted by the optical reception part, and an arithmetic circuit 30 which is connected between the optical transmission part and signal input part, and the optical reception part and signal output part, and transmits the electric signal converted by the optical reception part to the signal output part or stops the transmission depending upon the signal level of the electric signal inputted to the signal input part. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical transmission module.
[0002]
[Prior art]
A bidirectional optical transmission module that employs a half-duplex transmission system transmits and receives digital signals using a single optical fiber. Since signals are transmitted and received by a single optical fiber, the light emitting unit used for transmitting the optical signal and the light receiving unit used for receiving the optical signal are configured adjacent to each other within the same optical transmission module. If the light emitting unit and the light receiving unit are adjacent to each other, direct light or reflected light of an optical signal transmitted from the light emitting unit may enter the light receiving unit. As a result, there is a problem that the light receiving unit erroneously receives the optical signal from the light emitting unit.
[0003]
FIG. 4 is a cross-sectional view of an optical transmission module 121 that employs the half-duplex transmission method described in Patent Document 4. Conventionally, in order to prevent an optical signal from the semiconductor laser 102 from entering the photodiode 117, the optical waveguide 104 and the optical waveguide 105 are provided in the optical transmission module 121.
[0004]
On the other hand, a bidirectional optical transmission module (not shown) that employs a full-duplex transmission scheme transmits and receives signals using a transmission optical fiber and a reception optical fiber. In the full-duplex transmission method, signals are transmitted and received by a plurality of optical fibers, so that there is no problem that an optical signal from the light emitting unit enters the light receiving unit.
[0005]
[Patent Document 1]
JP 2000-341219 A [Patent Document 2]
JP 2001-4878 [Patent Document 3]
JP-A-5-130039 [Patent Document 4]
JP-A-11-308179 [0006]
[Problems to be solved by the invention]
In the conventional half-duplex transmission optical transmission module, the optical waveguide 104 and the optical waveguide 105 are formed in various shapes in order to prevent an optical signal from the semiconductor laser 102 from entering the photodiode 117. . That is, conventionally, in order to shield the light emitting portion and the light receiving portion from light, it is necessary to form the light transmission module in a complicated shape. When the structure of the optical transmission module is complicated, the cost increases.
[0007]
Further, the optical signal from the semiconductor laser 102 may be reflected at the end face E of the optical fiber 1. In order to prevent the reflected light from entering the photodiode 117, the end face E is formed to be inclined with respect to the traveling direction of the optical signal. The end face E had to be inclined at an appropriate angle in order to reduce the reflectance of the optical signal. This is a factor that increases the cost of the optical fiber.
[0008]
In a conventional full-duplex transmission optical transmission module, there is a risk of miswiring (reverse wiring) between the transmission optical fiber and the reception optical fiber when the optical connector and the optical fiber are connected. is there. In the past, in order to prevent such erroneous wiring, a sign that can identify transmission and reception has been attached to an optical fiber. However, since the optical connector and the optical fiber are connected by an operator, the possibility of erroneous wiring cannot be completely eliminated.
[0009]
SUMMARY OF THE INVENTION An object of the present invention is to provide an optical transmission module that has a simple shape, is low in cost, and prevents interference between a light emitting unit and a light receiving unit.
[0010]
Another object of the present invention is to provide an optical transmission module that prevents erroneous wiring between a transmission optical fiber and a reception optical fiber.
[0011]
[Means for Solving the Problems]
An optical transmission module according to an embodiment according to the present invention includes:
An optical transmitter that converts an electrical signal for transmission into an optical signal and transmits the optical signal;
An optical receiver that is adjacent to the optical transmitter and converts a received optical signal into an electrical signal; and a signal input unit that inputs an electrical signal to be converted in the optical transmitter;
A signal output unit that outputs an electrical signal converted in the optical receiver;
The optical receiver is connected between the optical transmitter and the signal input unit, and connected between the optical receiver and the signal output unit, and according to the signal level of the electric signal input to the signal input unit. And an arithmetic circuit for executing or stopping the transmission of the electrical signal converted in step 1 to the signal output unit.
[0012]
An optical transmission module according to another embodiment according to the present invention includes:
A first optical transmitter that converts an electrical signal for transmission into an optical signal and transmits the optical signal, and a first optical transmitter that is adjacent to the first optical transmitter and converts the received optical signal into an electrical signal. A first pair of transceivers having one optical receiver;
A second optical transmitter that converts an electrical signal for transmission into an optical signal and transmits the optical signal, and a second optical transmitter that is adjacent to the second optical transmitter and converts the received optical signal into an electrical signal. A second transceiver pair having two optical receivers;
A signal input unit for inputting an electrical signal to be converted in either the first optical transmission unit or the second optical transmission unit;
A signal output unit that outputs an electrical signal converted in either the first optical receiver or the second optical receiver;
The first optical receiver is connected between the first and second transceiver pairs and the signal input unit and between the first and second transceiver pairs and the signal output unit. Or a transceiver pair including an optical receiver that does not receive an optical signal among the first and second transmitter / receiver pairs according to the signal level of the electrical signal sent from the second optical receiver to the signal output unit. And a first arithmetic circuit that transmits the electrical signal input to the signal input unit.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. These embodiments do not limit the present invention.
[0014]
The half-duplex transmission optical transmission module according to the embodiment of the present invention stops the signal output of the optical receiver when the optical transmitter transmits the optical signal. Accordingly, the optical transmission module can prevent interference between the optical transmission unit and the optical reception unit without requiring a structure for shielding the optical transmission unit and the optical reception unit.
[0015]
A full-duplex transmission optical transmission module according to an embodiment of the present invention automatically identifies a transmission optical fiber and a reception optical fiber. Thereby, erroneous wiring between the transmission optical fiber and the reception optical fiber can be prevented.
[0016]
In the following embodiments, the optical transmission module is used for FA equipment, OA equipment, consumer equipment, and the like, and transmits and receives digital signals using optical fibers as transmission paths.
[0017]
(First embodiment)
FIG. 1 is a schematic diagram of a half-duplex optical transmission module 100 according to an embodiment of the present invention. The optical transmission module 100 includes an optical transmission module 11, an optical transmission unit 12, an optical reception module 13, an optical reception unit 14, a signal input unit 19, a signal output unit 20, and an arithmetic circuit 30. The optical transmission unit 12 is a light emitting element such as an LED or a semiconductor laser (LD), for example, and is disposed in the optical transmission module 11 together with a transmission IC (not shown). The light receiving unit 14 is a light receiving element such as a photodiode (PD), for example, and is provided in the light receiving module unit 13 together with a receiving IC (not shown). The optical fiber 10 is an optical transmission medium such as a plastic optical fiber (POF).
[0018]
The optical transmission module 100 communicates with another optical transmission module (not shown) through the optical fiber 10. The optical transmitter 12 converts an electrical signal for transmission into an optical signal, and transmits the optical signal to another optical transmission module through the optical fiber 10. The optical receiver 14 receives an optical signal from another optical transmission module through the optical fiber 10 and converts the optical signal into an electrical signal. Thus, the optical transmitter 12 and the optical receiver 14 transmit and receive optical signals through a single transmission line called the optical fiber 10, respectively. Therefore, the optical transmitter 12 and the optical receiver 14 are provided adjacent to each other.
[0019]
The signal input unit 19 is configured to be able to input an electrical signal converted in the optical transmission unit 12. The signal output unit 20 is configured to output the electrical signal converted in the optical receiving unit 13.
[0020]
The arithmetic circuit 30 is connected between the optical transmitter 12 and the signal input unit 19 and between the optical receiver 14 and the signal output unit 20. The arithmetic circuit 30 includes a level holding circuit 16, an inverter circuit 17, and an AND circuit 18.
[0021]
The level holding circuit 16 has an input terminal 16 a connected between the optical transmitter 12 and the signal input unit 19. The level holding circuit 16 is configured to hold the signal level of the electric signal input from the input terminal 16a for a certain period. Further, the level holding circuit 16 outputs the electrical signal, whose signal level is held, from the output terminal 16b. For example, the level holding circuit 16 is a peak hold circuit. The signal level is a level that represents a digital value of the electric signal. For example, when the digital value is represented by the voltage value of the electric signal, the signal level is the level of the voltage value of the electric signal.
[0022]
The inverter circuit 17 has an input terminal 17 a connected to the output terminal 16 b of the level holding circuit 16. The inverter circuit 17 inverts the highest voltage value of the electrical signal input from the level holding circuit 16, and outputs the inverted electrical signal from the output terminal 17b.
[0023]
The AND circuit 18 has two input terminals and one output terminal. One input terminal 18 a is connected to the output terminal 17 b of the inverter circuit 17, and the other input terminal 18 b is connected to the optical receiver 14. The output terminal 18 c is connected to the signal output unit 20. The AND circuit 18 is configured to calculate the logical product of the signal from the inverter circuit 17 and the signal from the optical receiver 14 and output the calculation result.
[0024]
Next, the operation of the optical transmission module 100 will be described. In the present embodiment, since the half-duplex transmission method is adopted, the optical fiber 10 periodically and alternately communicates a transmission signal and a reception signal. Accordingly, the optical transmission module 100 periodically and alternately repeats the transmission operation and the reception operation. Hereinafter, the period of the transmission operation and the period of the reception operation are referred to as a transmission period and a reception period, respectively.
[0025]
First, in the transmission period, the signal input unit 19 inputs an electrical signal for transmission from an external signal processing system (not shown). The electrical signal for transmission is transmitted to the optical transmission module 11 through the arithmetic circuit 30. Further, the optical transmitter 12 converts the electrical signal for transmission into an optical signal, and transmits the optical signal to the optical fiber 10.
[0026]
The level holding circuit 16 receives an electric signal for transmission from the end 16a, and holds the maximum voltage value (hereinafter also referred to as a high level) of this electric signal only during the transmission period. When a digital signal is input to the end portion 16a, a high level signal is always included. At this time, since the output terminal 16b of the level holding circuit 16 is held at a high level, the output terminal 17b of the inverter circuit 17 becomes a low voltage (hereinafter also referred to as a low level).
[0027]
Since the input terminal 18a of the AND circuit 18 is connected to the output terminal 17b of the inverter circuit 17, the input terminal 18a of the AND circuit 18 becomes low level. Accordingly, at this time, the AND circuit 18 outputs a low level at the output terminal 18c regardless of the level of the voltage value of the input terminal 18b. That is, even if the optical signal transmitted from the optical transmitter 12 is incident on the optical receiver 14, the AND circuit 18 does not transmit the signal from the optical receiver 14 to the signal output unit 20. In other words, the arithmetic circuit 30 can invalidate the signal from the optical receiver 14 in the transmission period.
[0028]
During the reception period, the electrical signal for transmission input from the signal input unit 19 is maintained at a low level, and the voltage value at the input terminal 18a of the AND circuit 18 is maintained at a high level. Therefore, the AND circuit 18 outputs an electrical signal at the input terminal 18b from the output terminal 18c.
[0029]
Thereby, in the reception period, the optical receiver 14 receives an optical signal, and an electrical signal according to the optical signal is output from the signal output unit 20. That is, during the reception period, the optical transmission module 100 can perform a reception operation normally.
[0030]
Here, the level holding circuit 16 holds the level of the voltage value of the electric signal for a certain period. When the level holding circuit 16 holds the high level in the reception period beyond the transmission period, the optical transmission module 100 cannot receive the reception signal during the reception period. Therefore, this fixed period is a period shorter than the transmission period.
[0031]
On the other hand, the level holding circuit 16 is high for a sufficiently long period in the transmission period so that the optical signal transmitted in the transmission period is received by the optical receiver 14 and this signal is not erroneously output from the signal output unit 20. It is preferable to maintain the level. Therefore, preferably, the certain period is between the transmission period and the synchronization period. Further, it is preferable that the level holding circuit 16 holds a sufficiently high voltage value during the transmission period and is changed to a sufficiently low voltage value immediately before switching from the transmission period to the reception period. Thereby, the useless time between the transmission period and the reception period is reduced.
[0032]
Thus, the arithmetic circuit 30 does not pass the signal received by the optical receiver 14 to the signal output unit 20 when a signal is input to the signal input unit 19. On the other hand, when no signal is input to the signal input unit 19, the arithmetic circuit 30 passes the signal from the optical receiver 14 to the signal output unit 20.
[0033]
In the present embodiment, interference between the light emitting unit and the light receiving unit can be prevented only by adding a simple circuit such as the arithmetic circuit 30. That is, this embodiment does not require a light shielding wall or light shielding plate having a complicated shape like the optical waveguide 104 and the optical waveguide 105 shown in FIG. Can be prevented.
[0034]
According to the present embodiment, the signal received by the optical receiver 14 in the transmission period does not pass to the signal output unit 20. Therefore, in the transmission period, the light reflected at the end face E ₁₀ of the optical fiber 10 is incident on the light receiving unit 14 is not a problem. Therefore, the end surface E ₁₀ of the optical fiber 10 need not inclined with respect to the traveling direction of the optical signal.
[0035]
(Second Embodiment)
FIG. 2 is a schematic diagram of a full-duplex optical transmission module 200 according to an embodiment of the present invention. The optical transmission module 200 includes a transceiver pair 40, a transceiver pair 42, a signal input unit 28, a signal output unit 29, and an arithmetic circuit 32.
[0036]
The transceiver pairs 40 and 42 include an optical transmission module 11, an optical transmission unit 12, an optical reception module 13, an optical reception unit 14, and a light shielding unit 8, respectively. In the transceiver pair 40 and 42, the optical transmitter 12 and the optical receiver 14 are provided adjacent to each other. The light shielding unit 8 has a structure such that the optical signal transmitted from the optical transmission unit 12 does not enter the optical reception unit 14. For example, the light shielding unit 8 is a barrier between the optical waveguide 104 and the optical waveguide 105 in the optical transmission module shown in FIG. Therefore, although the transceiver pair 40 and 42 are simply shown in FIG. 2, they actually have a complicated shape like the optical transmission module 121 shown in FIG. The optical transmission module 11, the optical transmission unit 12, the optical reception module 13, and the optical reception unit 14 are the same as those shown in FIG.
[0037]
The optical fiber 44 and the optical fiber 45 are transmission and reception optical fibers, respectively. Therefore, the transceiver pair 40 is used for receiving optical signals, and the transceiver pair 42 is used for transmitting optical signals.
[0038]
The signal input unit 28 is configured to be able to input an electrical signal converted in the optical transmission unit 12 of the transceiver pair 40. The signal output unit 29 is configured to output the electrical signal converted in the optical receiving unit 13 of the transceiver pair 42.
[0039]
The arithmetic circuit 32 is connected between the transceiver pair 40 and the signal input unit 28 and between the transceiver pair 42 and the signal output unit 29. The arithmetic circuit 32 includes an OR circuit 25, an AND circuit 26, a level holding circuit 24, and signal control circuits 60 and 80.
[0040]
The input terminals 25a and 25b of the OR circuit 25 are connected to the optical receiver 14 of the transceiver pair 40 and the optical receiver 14 of the transceiver pair 42, respectively. An output terminal 25 c of the OR circuit 25 is connected to the signal output unit 29.
[0041]
One input terminal 26 a of the AND circuit 26 is connected to the signal input unit 28. The other input terminal 26 a of the AND circuit 26 is connected to the output terminal 25 c of the OR circuit 25 via the level holding circuit 24. The output terminal 26 c of the AND circuit 26 is connected to the signal control circuits 60 and 80.
[0042]
The input terminal 24 a of the level holding circuit 24 is connected to the output terminal 25 c of the OR circuit 25, and the output terminal 24 b of the level holding circuit 24 is connected to the input terminal 26 b of the AND circuit 26. The level holding circuit 24 is configured to hold the maximum voltage value (high level) of the electric signal input to the input terminal 24a for a certain period and output the electric signal from the output terminal 24b.
[0043]
The signal control circuit 60 includes an AND circuit 21, an inverter circuit 22, and a level holding circuit 23. The signal control circuit 80 includes an AND circuit 51, an inverter circuit 52, and a level holding circuit 53.
[0044]
The input terminal 23 a of the level holding circuit 23 is connected to the input terminal 25 a of the OR circuit 25. The level holding circuit 23 is configured to hold the maximum voltage value (high level) of the electric signal input to the input terminal 23a for a certain period and output the electric signal from the output terminal 23b.
[0045]
The input terminal 22 a of the inverter circuit 22 is connected to the output terminal 23 b of the level maintaining circuit 23. The inverter circuit 22 is configured to invert the signal level of the electric signal input from the input terminal 22a and output the electric signal from the output terminal 22b.
[0046]
The input terminal 21a of the AND circuit 21 is connected to the output terminal 26c of the AND circuit. The input terminal 21 b of the AND circuit 21 is connected to the output terminal 22 b of the inverter circuit 22. An output terminal 21 c of the AND circuit 21 is connected to the optical transmission unit 12 of the transceiver pair 40.
[0047]
The input terminal 53 a of the level holding circuit 53 is connected to the input terminal 25 b of the OR circuit 25. The level holding circuit 53 is configured to hold the maximum voltage value (high level) of the electric signal input to the input terminal 53a for a certain period and output the electric signal from the output terminal 53b.
[0048]
The input terminal 52 a of the inverter circuit 52 is connected to the output terminal 53 b of the level maintaining circuit 53. The inverter circuit 52 is configured to invert the signal level of the electric signal input from the input terminal 52a and output the electric signal from the output terminal 52b.
[0049]
The input terminal 51a of the AND circuit 51 is connected to the output terminal 26c of the AND circuit. The input terminal 51 b of the AND circuit 51 is connected to the output terminal 52 b of the inverter circuit 52. An output terminal 51 c of the AND circuit 51 is connected to the optical transmission unit 12 of the transceiver pair 42.
[0050]
The level holding circuits 23, 24 and 53 are, for example, peak hold circuits having the same characteristics as the level holding circuit 16 shown in FIG. However, the level holding period of the level holding circuits 23, 24, 53 need not be the same as that of the level holding circuit 16.
[0051]
Next, the operation of the optical transmission module 200 will be described. In the present embodiment, since the full-duplex transmission method is adopted, the optical transmission module 200 can simultaneously perform transmission and reception.
[0052]
The OR circuit 25 can pass the signal to the signal output unit 19 regardless of which optical receiver 14 of the transmission / reception pair 40 or the transmission / reception pair 42 receives the signal. In FIG. 2, the optical receiver 14 of the transmission / reception pair 42 receives a signal. However, when the transmission / reception pair 40 and the transmission / reception pair 42 are exchanged, the optical receiver 14 of the transmission / reception pair 42 can receive signals.
[0053]
The level holding circuit 23 holds the high level of the electric signal from the optical receiver 14 of the transmission / reception pair 40 only during the transmission period. Therefore, when the electrical signal at the terminal 23a is at a high level, the end 22b of the inverter circuit 22 is at a low level. Thus, when the optical receiver 14 of the transmission / reception pair 40 is receiving a signal, the output signal of the AND circuit 21 is at a low level regardless of the signal level of the input terminal 21a of the AND circuit 21.
[0054]
On the other hand, when the electrical signal at the input terminal 23a of the level holding circuit 23 is at a low level, the output terminal 22b of the inverter circuit 22 is at a high level. Therefore, when the optical receiver 14 of the transmission / reception pair 40 is not receiving a signal, the electrical signal input to the input terminal 21 a of the AND circuit 21 is output to the optical transmitter 12 as an output signal of the AND circuit 21.
[0055]
The level holding circuit 53 holds the high level of the electrical signal from the optical receiver 14 of the transmission / reception pair 42 only during the transmission period. Therefore, when the electrical signal at the input terminal 53a is at a high level, the end 52b of the inverter circuit 52 is at a low level. Thus, when the optical receiver 14 of the transmission / reception pair 42 is receiving a signal, the output signal of the AND circuit 51 becomes low level regardless of the signal level of the input terminal 51a of the AND circuit 51.
[0056]
On the other hand, when the electrical signal at the terminal 53a is at a low level, the end 52b of the inverter circuit 52 is at a high level. Therefore, when the optical receiver 14 of the transmission / reception pair 42 is not receiving a signal, an electrical signal input to the input terminal 51 a of the AND circuit 51 is output as an output signal of the AND circuit 51.
[0057]
As described above, the signal control circuits 60 and 80 do not transmit the signal output from the AND circuit 26 to the optical transmission unit 12 when the optical reception unit 14 receives the signal. On the other hand, when the optical receiver 14 is not receiving a signal, the signal control circuits 60 and 80 can transmit the signal output from the AND circuit 26 to the optical transmitter 12. As a result, the arithmetic circuit 32 can automatically identify which optical transmission unit 12 of the optical transmission units 12 provided in the transmission / reception pairs 40 and 42 should send an electrical signal.
[0058]
The level holding circuit 24 maintains the high level of the electric signal at the output terminal 25c. That is, the level holding circuit 24 outputs a high-level electrical signal to the output terminal 24b when either the optical receiver 14 of the transmission / reception pair 40 or the transmission / reception pair 42 receives an optical signal. At this time, since the input terminal 26 b of the AND circuit 26 becomes high level, the AND circuit 26 outputs the signal from the signal input unit 28 to the signal control circuit 60.
[0059]
On the other hand, when the optical receivers 14 of both the transmission / reception pair 40 and the transmission / reception pair 42 are not receiving signals, the level holding circuit 24 outputs a low-level electrical signal to the output terminal 24b. At this time, since the input terminal 26b of the AND circuit 26 becomes low level, the output signal of the AND circuit 26 becomes low level regardless of the signal level from the signal input unit 28.
[0060]
Thereby, when the optical receivers 14 of both the transmission / reception pair 40 and the transmission / reception pair 42 have not received the optical signal, the signal input to the signal input unit 28 becomes invalid. Therefore, both the optical transmission units 12 of the transmission / reception pair 40 and the transmission / reception pair 42 do not transmit optical signals.
[0061]
Further, when one optical receiver 14 of the transmission / reception pair 40 and the transmission / reception pair 42 receives an optical signal, the other optical transmission unit 12 can transmit the optical signal. Therefore, according to the present embodiment, miswiring between the transmission optical fiber and the reception optical fiber does not occur.
[0062]
(Third embodiment)
FIG. 3 is a schematic diagram of a full-duplex optical transmission module 300 according to an embodiment of the present invention. The optical transmission module 300 is different from the second embodiment in that the control circuit 30 shown in FIG. 1 is connected between the arithmetic circuit 32 and the modules 11 and 12. Thereby, in this Embodiment, the light-shielding part 8 shown in FIG. 2 is unnecessary. This embodiment has the effects of both the first and second embodiments.
[0063]
【The invention's effect】
The light transmission module according to the present invention has a simple shape, is low in cost, and can prevent interference between the light emitting unit and the light receiving unit.
[0064]
According to the optical transmission module of the present invention, erroneous wiring between the transmission optical fiber and the reception optical fiber does not occur.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of a first embodiment according to the present invention.
FIG. 2 is a schematic diagram of a second embodiment according to the present invention.
FIG. 3 is a schematic diagram of a third embodiment according to the present invention.
FIG. 4 is a cross-sectional view of a conventional optical transmission module.
[Explanation of symbols]
100, 200, 300 Optical transmission module 12 Optical transmission unit 14 Optical reception unit 19, 28 Signal input unit 16, 24, 53 Level holding circuit 17, 22, 23, 52 Inverter circuit 18, 26, 21, 51 AND circuit 20, 29 Signal output units 30 and 32 Arithmetic circuit 8 Shading unit 40 Transceiver pair 42 Transceiver pair 25 OR circuit 60 and 80 Signal control circuit

Claims (14)

An optical transmitter that converts an electrical signal for transmission into an optical signal and transmits the optical signal;
An optical receiver adjacent to the optical transmitter for converting the received optical signal into an electrical signal;
A signal input unit for inputting an electrical signal to be converted in the optical transmission unit;
A signal output unit that outputs an electrical signal converted in the optical receiver;
The optical receiver is connected between the optical transmitter and the signal input unit, and connected between the optical receiver and the signal output unit, and according to the signal level of the electric signal input to the signal input unit. An optical transmission module comprising: an arithmetic circuit that executes or stops transmitting the electrical signal converted in step 1 to the signal output unit. The arithmetic circuit is:
One end is connected between the optical transmission unit and the signal input unit, an inverter circuit that inverts the signal level of the electric signal input from the one end and outputs the electric signal from the other end,
2. The AND circuit according to claim 1, further comprising: an AND circuit having two input terminals connected to the other end of the inverter circuit and the optical receiver, and an output terminal connected to the signal output unit. Optical transmission module. The arithmetic circuit is:
One end is connected between the optical transmission unit and the signal input unit, a level holding circuit that holds the signal level of the electric signal input from the one end for a certain period and outputs the electric signal from the other end,
One end is connected to the other end of the level holding circuit, an inverter circuit for inverting the signal level of the electric signal input from the one end and outputting the electric signal from the other end,
2. The AND circuit according to claim 1, further comprising: an AND circuit having two input terminals connected to the other end of the inverter circuit and the optical receiver, and an output terminal connected to the signal output unit. Optical transmission module. The arithmetic circuit is:
When the electrical signal input to the signal input unit is at a low level, the electrical signal converted in the optical receiving unit is transmitted to the signal output unit,
2. The transmission of the electrical signal converted in the optical receiving unit to the signal output unit is stopped when the electrical signal input to the signal input unit is at a high level. Optical transmission module. The optical transmission module according to claim 1, wherein a digital signal is transmitted and received by a half-duplex transmission method. A first optical transmitter that converts an electrical signal for transmission into an optical signal and transmits the optical signal, and a first optical transmitter that is adjacent to the first optical transmitter and converts the received optical signal into an electrical signal. A first pair of transceivers having one optical receiver;
A second optical transmitter that converts an electrical signal for transmission into an optical signal and transmits the optical signal, and a second optical transmitter that is adjacent to the second optical transmitter and converts the received optical signal into an electrical signal. A second transceiver pair having two optical receivers;
A signal input unit for inputting an electrical signal to be converted in either the first optical transmission unit or the second optical transmission unit;
A signal output unit that outputs an electrical signal converted in either the first optical receiver or the second optical receiver;
The first optical receiver is connected between the first and second transceiver pairs and the signal input unit and between the first and second transceiver pairs and the signal output unit. Or a transceiver pair including an optical receiver that does not receive an optical signal among the first and second transmitter / receiver pairs according to the signal level of the electrical signal sent from the second optical receiver to the signal output unit. An optical transmission module comprising: a first arithmetic circuit that transmits an electric signal input to the signal input unit to an optical transmission unit included in the signal transmission unit. A light-shielding unit is provided between the first optical transmission unit and the first optical reception unit and between the second optical transmission unit and the second optical reception unit. Item 7. The optical transmission module according to Item 6. The first arithmetic circuit includes:
An OR circuit having two input terminals respectively connected to the first and second optical receiving units and an output terminal connected to the signal output unit;
A first AND circuit having two input terminals respectively connected to the output terminal of the OR circuit and the signal input unit; and an output terminal for outputting a logical product of signals from the signal input unit and the OR circuit; ,
The signal output from the output terminal of the first AND circuit is transmitted to the first optical transmitter according to the signal level of the electric signal input from the first optical receiver to the OR circuit. Or a first signal control circuit to stop;
The signal output from the output terminal of the first AND circuit is transmitted to the second optical transmitter according to the signal level of the electric signal input from the second optical receiver to the OR circuit. The optical transmission module according to claim 6, further comprising a second signal control circuit that stops. The first arithmetic circuit includes:
An OR circuit having two input terminals respectively connected to the first and second optical receiving units and an output terminal connected to the signal output unit;
A first level holding circuit having one end connected to the output terminal of the OR circuit, holding the signal level of the electric signal output from the OR circuit for a certain period, and outputting the electric signal from the other end;
Outputs the logical product of two input terminals respectively connected to the other ends of the signal input unit and the first level holding circuit, and a signal from the signal input unit and a signal from the first level holding circuit. A first AND circuit having an output terminal;
Transmitting the signal output from the output terminal of the first AND circuit to the first optical transmitter according to the signal level of the electric signal input from the first optical receiver to the OR circuit; or A first signal control circuit for stopping the transmission;
Transmitting the signal output from the output terminal of the first AND circuit to the second optical transmitter according to the signal level of the electric signal input from the second optical receiver to the OR circuit; or The optical transmission module according to claim 6, further comprising a second signal control circuit that stops the transmission. The first signal control circuit includes:
One end is connected between the first optical receiver and the OR circuit, and a second level maintaining is performed for holding the signal level of the electric signal input from the one end for a certain period and outputting the electric signal from the other end. Circuit,
A first inverter circuit having one end connected to the other end of the second level maintaining circuit, inverting the signal level of the electric signal input from the one end, and outputting the electric signal from the other end;
A second input terminal connected to each of the other end of the first inverter circuit and an output terminal of the first AND circuit; and an output terminal connected to the first optical transmitter. An AND circuit,
The second signal control circuit includes:
One end is connected between the second optical receiving unit and the OR circuit, and a third level maintaining that maintains the signal level of the electric signal input from the one end for a certain period and outputs the electric signal from the other end. Circuit,
A second inverter circuit having one end connected to the other end of the third level maintaining circuit, inverting the signal level of the electric signal input from the one end, and outputting the electric signal from the other end;
A third input terminal having two input terminals connected to the other end of the second inverter circuit and an output terminal of the first AND circuit, and an output terminal connected to the second optical transmitter. The optical transmission module according to claim 8, further comprising an AND circuit. Electricity connected between the first arithmetic circuit and the first transceiver pair and converted in the first optical receiver according to the signal level of the electric signal output from the second AND circuit A second arithmetic circuit that executes or stops transmitting a signal to the OR circuit;
Electricity connected between the first arithmetic circuit and the second transceiver pair and converted in the second optical receiver according to the signal level of the electric signal output from the third AND circuit The optical transmission module according to claim 6, further comprising: a third arithmetic circuit that executes or stops transmission of a signal to the OR circuit. The second arithmetic circuit includes:
One end is connected between the second AND circuit and the first optical transmitter, and a signal level of an electric signal input from the one end is held for a certain period, and the electric signal is output from the other end. Level holding circuit,
A third inverter circuit having one end connected to the other end of the fourth level holding circuit, inverting the signal level of the electric signal input from the one end, and outputting the electric signal from the other end;
A fourth AND circuit having two input terminals connected to the other end of the third inverter circuit and each of the first optical receivers, and an output terminal connected to the OR circuit;
The third arithmetic circuit includes:
One end is connected between the third AND circuit and the second optical transmitter, and a signal level of an electric signal input from the one end is held for a certain period, and the electric signal is output from the other end. Level holding circuit,
A fourth inverter circuit having one end connected to the other end of the fifth level holding circuit, inverting the signal level of the electric signal input from the one end, and outputting the electric signal from the other end;
A fifth AND circuit having two input terminals connected to the other end of the fourth inverter circuit and each of the second optical receivers, and an output terminal connected to the OR circuit; The optical transmission module according to claim 11. The first arithmetic circuit includes:
When the electrical signal sent from the first optical receiving unit to the signal output unit is at a high level, the electrical signal input to the signal input unit is transmitted to the second optical transmission unit. The optical transmission module according to claim 6. The optical transmission module according to claim 6, wherein digital signals are transmitted and received by a full-duplex transmission method.

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