JP2006023500A - Wavelength division multiplexing coupler - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wavelength division multiplexing coupler which can be directly attached and detached to/from a twin receptacle type light transmitter-receiver. <P>SOLUTION: The wavelength division multiplexing coupler 1 is provided with a case 101 in which two plugs are arranged on the side surface of a rectangular parallelepiped and a receptacle is arranged on the side surface opposite to the side surface on which the plugs are arranged. The plugs of the wavelength division multiplexing coupler 1 are fitted to the twin receptacle type light transmitter-receiver and the receptacle is fitted to a one-core optical fiber plug. A parallelogram prism 119, an optical filter 120 and a rectangular prism 121 are disposed on the inner part of the rectangular parallelepiped. The wavelength division multiplexing coupler 1 outputs a light signal of wavelength λ1 made incident from one side plug of the two plugs from the receptacle. The wavelength division multiplexing coupler 1 outputs a light signal of wavelength λ2 made incident to the receptacle from the other side plug. The parallelogram prism 119, optical filter 120 and rectangular prism 121 multiplex/demultiplex the light signal of wavelength λ1 and the light signal of wavelength λ2. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an optical component for two-way optical communication, and more particularly to a wavelength multiplexing coupler that transmits a plurality of optical signals having different wavelengths through a single optical fiber.

  When bi-directional optical communication is performed via a single-core optical fiber, the optical signal output from the light emitting element is coupled to the single-core optical fiber, and the optical signal transmitted through the single-core optical fiber is received. In order to transmit to an element, a wavelength multiplexing coupler for demultiplexing / multiplexing optical signals of two wavelengths is required.

  Conventionally, a multiplexer / demultiplexer built in a wavelength multiplexing coupler used for the above-described purposes includes a multiplexer / demultiplexer that demultiplexes / multiplexes an optical signal by melting and stretching a plurality of optical fibers. In addition, there are a multiplexer / demultiplexer that demultiplexes and multiplexes an optical signal using a dielectric multilayer film, and a multiplexer / demultiplexer that divides and multiplexes an optical signal using a grating.

  Such wavelength multiplexing couplers are classified into two types, a pigtil type and a receptacle type.

  One end of an optical fiber is connected to the multiplexer / demultiplexer built in the pigtilt type wavelength division multiplexing coupler. A plug is connected to the other end of the optical fiber connected to the multiplexer / demultiplexer built in the pigtilt type wavelength division multiplexing coupler.

  The receptacle-type wavelength multiplexing coupler includes a multiplexer / demultiplexer and a receptacle that is an optical fiber connector. A receptacle is connected to the multiplexer / demultiplexer built in the receptacle-type wavelength multiplexing coupler.

  There are two types of optical fiber connectors for connecting an optical communication device and an optical fiber: a receptacle and a plug that can be fitted into the receptacle. Plugs and plugs or receptacles and receptacles do not fit together. In this specification, in the case of the pigtil type, one end of an optical fiber is connected to a built-in component (for example, a multiplexer / demultiplexer, a light emitting element, a light receiving element, etc.), and a plug is connected to the other end of the optical fiber. I mean. In the case of a receptacle type, it means a configuration in which a receptacle is connected to a built-in component.

  FIG. 16A is a diagram showing a configuration of a system to which the pigtilt type wavelength division multiplexing coupler 403 is applied. In FIG. 16A, the system includes a receptacle-type optical transmitter 401, a receptacle-type optical receiver 402, and a pigtil-type wavelength multiplexing coupler 403. The optical multiplexer / demultiplexer 431 of the wavelength multiplexing coupler 403 is connected to an optical fiber 432 having a plug 435 connected to the tip, an optical fiber 433 having a plug 436 connected to the tip, and an optical fiber 434 having a plug 437 connected to the tip. Has been. In the optical transmitter 401, a receptacle 411 and a plug 435 are connected. In the optical receiver 402, the receptacle 421 and the plug 436 are connected. The plug 437 of the wavelength division multiplexing coupler 403 is connected to a single-core transmission line optical fiber (not shown) having a receptacle connected to one end. In the system connected in this way, an optical signal output from the optical transmitter 401 is input to the optical multiplexer / demultiplexer 431 via the optical fiber 432 and transmitted to the optical fiber 434. On the other hand, the optical signal transmitted from the transmission line optical fiber is input to the optical multiplexer / demultiplexer 431 via the optical fiber 434. Further, the optical signal is transmitted to the optical fiber 433 and input to the optical receiver 402. In this manner, bidirectional optical communication via a single-core optical fiber is realized.

  FIG. 16B is a diagram showing a configuration of a system to which the receptacle-type wavelength multiplexing coupler 503 is applied. In FIG. 16B, the system includes a pigtilt-type optical transmitter 501, a pigtilt-type optical receiver 502, and a receptacle-type wavelength multiplexing coupler 503. The optical multiplexer / demultiplexer 531 of the wavelength multiplexing coupler 503 is connected to a receptacle 532, a receptacle 533, and a receptacle 534. In the optical transmitter 501, the plug 513 and the receptacle 532 are connected. In the optical receiver 502, a plug 523 and a receptacle 533 are connected. The receptacle 534 of the wavelength multiplexing coupler 503 is connected to a single-core transmission line optical fiber (not shown) having a plug connected to one end. In the system thus connected, the optical signal output from the optical transmitter 501 is input to the optical multiplexer / demultiplexer 531 via the optical fiber 512 and transmitted to the transmission line optical fiber. The optical signal transmitted through the transmission line optical fiber is input to the optical multiplexer / demultiplexer 531 and input to the optical receiver 502 through the optical fiber 522. In this manner, bidirectional optical communication via a single-core optical fiber is realized.

  Patent Document 1 describes an optical wrap connector used for transmission confirmation of an optical transmitter / receiver as a device for directly connecting two optical connectors to an optical transmitter / receiver incorporating a light emitting element and a light receiving element. FIG. 17 is a diagram illustrating a configuration of the optical wrap connector disclosed in Patent Document 1. In FIG. The optical wrap connector 601 is directly connected to an optical transceiver 602 including a light emitting element 621 and a light receiving element 622. In FIG. 17, arrows schematically represent the flow of the optical signal 603 input / output to / from the optical transceiver 602.

The operation of the optical wrap connector 601 will be described with reference to FIG. An optical signal 603 input from the light emitting element 621 to the optical wrap connector 601 is branched into two by the optical coupler 611. One optical signal 603 branched from the optical coupler 611 is input to the light receiving element 622 of the optical transceiver. The other optical signal branched from the optical coupler 611 is input to the light receiving element 612 of the optical wrap connector 601. The light receiving element 612 converts the optical signal into an electric signal and outputs it to the ammeter 613. Therefore, the ammeter 613 can measure the level of the optical signal 603 output from the light emitting element 621.
JP-A-11-64866

  In two-way optical communication, a double receptacle type optical transceiver is often used. Here, the dual-receptacle type optical transceiver is an optical communication device in which two receptacles for accommodating components that handle two optical signals having different wavelengths are arranged to emit one optical signal. This means an optical communication device that includes a light emitting unit for receiving light and a light receiving unit for receiving the other optical signal.

When a bidirectional optical communication system configured by connecting a two-core optical fiber to a double receptacle type optical transceiver is desired to be changed to a bidirectional optical communication system using a single-core optical fiber, for example, FIG. By using a pigtilt type wavelength division multiplexing coupler,
It can be changed to a bidirectional communication system via a single-core optical fiber.

  However, the pigtilt type wavelength division multiplexing coupler must be connected to two receptacle type optical transceivers via an optical fiber. Therefore, there is a problem in mountability because the extra length processing of the optical fiber has to be performed.

  In addition, if you want to change a bidirectional optical communication system configured by connecting a two-core optical fiber to two receptacle optical transceivers to a bidirectional optical communication system via a single-core optical fiber, One end of a two-core optical fiber having two plugs at both ends is connected to the receptacle-type optical transceiver, and a receptacle-type wavelength multiplexing coupler is connected to the other end of the two-core optical fiber. By connecting a single-core optical fiber to the receptacle-type wavelength division multiplexing coupler, it is possible to change to a bidirectional optical communication system via a single-core optical fiber. However, also in this case, the extra length processing of the optical fiber has to be performed, which causes a problem in mountability.

  The optical wrap connector shown in Patent Document 1 can be directly connected to two series of optical transceivers. However, the optical wrap connector is intended for transmission confirmation of the optical transceiver. Therefore, the optical wrap connector cannot be used as a means for demultiplexing / combining optical signals having different wavelengths. Furthermore, Patent Document 1 does not disclose a specific technique regarding the connection portion of the optical wrap connector that is connected to the optical transceiver.

  SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a detachable wavelength multiplexing having a small size and excellent mountability, which is optimal for applying a duplex receptacle type optical transceiver to a bidirectional optical communication system via a single optical fiber. An object is to provide a coupler.

The present invention relates to an optical communication device comprising two receptacles for accommodating parts that handle first and second optical signals having different wavelengths and a plug that can be fitted to the receptacle at one end. A wavelength multiplexing coupler for connecting an optical fiber,
An optical multiplexing / demultiplexing unit for multiplexing / demultiplexing the first and second optical signals;
In the optical multiplexer / demultiplexer, a first transmission unit disposed on the first input / output side for inputting / outputting the first and second optical signals to / from different locations, and transmitting the first optical signal;
A second transmission unit disposed on the first input / output side for transmitting a second optical signal;
In the optical multiplexer / demultiplexer, a third transmission unit is disposed on the second input / output side for inputting / outputting the first and second optical signals to / from a common location, and transmits the first and second optical signals. When,
A housing for incorporating an optical multiplexing / demultiplexing unit, a first transmission unit, a second transmission unit, and a third transmission unit,
The housing is
An optical multiplexing / demultiplexing unit accommodating unit for accommodating the optical multiplexing / demultiplexing unit and a first plug unit that can be fitted into one receptacle of the optical communication device and holds the first transmission unit;
A second plug portion that can be fitted into the other receptacle of the optical communication device and holds the second transmission portion;
And a receptacle portion that can be fitted to a single-core optical fiber plug and holds the third transmission portion.

  According to the present invention, a wavelength division multiplexing coupler according to the present invention includes two plug portions for connecting to an optical communication device including two receptacles in series, and a receptacle portion connected to a single-core optical fiber including the plugs. By providing the housing to be connected, the optical communication device and the single-core optical fiber including the plug can be connected. Accordingly, the wavelength division multiplexing coupler can multiplex / demultiplex two optical signals having different wavelengths handled by the optical communication apparatus. For this reason, it becomes possible to use the optical communication apparatus provided with two receptacles connected to each other in a bidirectional optical communication system using a single-core optical fiber.

Preferably,
An optical multiplexing / demultiplexing unit holding unit that is movable between the first input / output side and the second input / output side and holds the optical multiplexing / demultiplexing unit;
A first elastic body for pressing the first transmission section toward the first input / output side;
A second elastic body for pressing the second transmission section toward the first input / output side;
A third elastic body for pressing the optical multiplexing / demultiplexing portion holding portion toward the first input / output side,
The force by which the third elastic body presses the optical multiplexing / demultiplexing unit holding means to the first input / output side is the force by which the first elastic body presses the first transmission unit to the first input / output side, The second elastic body is larger than the sum of the force that presses the second transmission portion toward the first input / output side.

  Thereby, the first and second elastic bodies are pressed in a direction opposite to the direction in which the third transmission body is pressed. For this reason, the first and second transmission units are always pressed against the optical multiplexing / demultiplexing unit holding unit. Therefore, the first optical signal transmitted through the first transmission unit and the second optical signal transmitted through the second transmission unit are transmitted without loss.

further,
The first elastic body is a spring,
The second elastic body is a spring,
The third elastic body is a spring.

  Thereby, the first transmission unit, the second transmission unit, and the optical multiplexing / demultiplexing unit holding unit can be efficiently performed by using the first elastic body, the second elastic body, and the third elastic body as springs. It becomes possible to press.

Furthermore, the single-core optical fiber plug includes a first optical fiber for transmitting the first and second optical signals, a first ferrule for holding the first optical fiber, A fourth elastic body for pressing the ferrule,
The first transmission unit
A second optical fiber for transmitting the first optical signal;
A second ferrule for holding the first optical fiber therein,
The second transmission unit is
A third optical fiber for transmitting the second optical signal;
A third ferrule for holding the second optical fiber therein,
The third transmission unit
A fourth optical fiber for transmitting the first and second optical signals;
A fourth ferrule that holds the fourth optical fiber therein,
When the plug of the single-core optical fiber and the receptacle part are fitted, the fourth elastic body presses the fourth ferrule toward the second input / output side.

  Accordingly, the first transmission unit, the second transmission unit, and the third transmission unit are configured to have an optical fiber and a ferrule that holds the optical fiber, so that the first and second optical signals are efficient. It is transmitted well.

The optical multiplexing / demultiplexing unit is
The first optical fiber is disposed on the optical axis of the first optical fiber, the end face on the first input / output side of the optical multiplexing / demultiplexing unit holding part is a focal point, and the first optical signal output from the first optical fiber is used as collimator light A first collimator lens to convert;
The second optical fiber is disposed on the optical axis of the second optical fiber, the first input / output side end face of the optical multiplexing / demultiplexing unit holding part is a focal point, and the second optical signal output from the second optical fiber is used as collimator light. A second collimator lens to convert;
The first and second optical signals output from the third optical fiber are arranged on the optical axis of the third optical fiber, the end face on the second input / output side of the optical multiplexing / demultiplexing unit holding unit is a focal point, and A third collimating lens for conversion into collimator light;
An optical filter that reflects the first optical signal and transmits the second optical signal;
A right angle prism having an optical filter disposed on the first inclined surface;
A parallelogram prism having second and third inclined surfaces, wherein the first inclined surface and the second inclined surface of the right-angle prism are in contact with each other through an optical filter;
The parallelogram prism transmits the first optical signal between the first transmission unit and the third transmission unit by reflecting the first optical signal on the second and third inclined surfaces. ,
The parallelogram prism and the right-angle prism transmit the second optical signal on the first and second inclined surfaces, whereby the second optical signal is transmitted between the first transmission unit and the third transmission unit. Is transmitted.

  As a result, the first and second optical signals transmitted through the first optical fiber, the second optical fiber, and the third optical fiber are converted into collimator light by the collimator lens, and are parallelograms. It is multiplexed / demultiplexed by a prism, an optical filter, and a right-angle prism. This eliminates the need for optical fiber processing such as connecting a transmission unit to the optical multiplexing / demultiplexing unit, eliminates the complexity of mounting the bidirectional optical communication system, and enables downsizing of the apparatus.

  Furthermore, the first collimator lens, the third collimator lens, and the parallelogram prism may be integrally molded, and the second collimator lens and the right-angle prism may be integrally molded.

  Accordingly, the first collimator lens, the third collimator lens, and the parallelogram prism are integrally formed, and the second collimator lens and the right-angle prism are integrally molded, so that the collimator function and the optical multiplexing / demultiplexing function are obtained. Integrated. For this reason, adjustment of the position of the collimator lens can be omitted.

  Further, the optical multiplexing / demultiplexing unit guides the first optical signal between the first transmission unit and the third transmission unit, and the second transmission unit between the second transmission unit and the third transmission unit. It may be an optical waveguide that guides the optical signal.

  Thus, by combining the optical multiplexing / demultiplexing portion with the optical waveguide, it is possible to accurately perform multiplexing / demultiplexing of the first optical signal and the second optical signal.

Preferably, furthermore,
A first elastic body for pressing the first transmission section in the direction opposite to the first input / output side;
A second elastic body for pressing the second transmission section in the direction opposite to the first input / output side;
You may provide the 3rd elastic body for pressing a 3rd transmission part in the opposite direction to the 2nd input / output side.

  As a result, the first and second transmission units are pressed against the first and second elastic bodies and correspond to the components handling the first and second optical signals of the optical communication device having two receptacles in series. Touch. In addition, the optical axis of the third transmission unit and the optical axis of the plug included in the transmission line optical fiber are in contact with each other in a matched state. For this reason, the first and second optical signals are transmitted without causing a coupling loss.

further,
The first elastic body is a spring,
The second elastic body is a spring,
The third elastic body is a spring.

  Thereby, the first transmission unit, the second transmission unit, and the optical multiplexing / demultiplexing unit holding unit can be efficiently performed by using the first elastic body, the second elastic body, and the third elastic body as springs. It becomes possible to press.

Furthermore, the first transmission unit is
A first optical fiber for transmitting a first optical signal;
A first ferrule for holding the first optical fiber therein,
The second transmission unit is
A second optical fiber for transmitting a second optical signal;
A third ferrule for holding the second optical fiber therein,
The third transmission unit
A third optical fiber for transmitting the first and second optical signals;
You may make the 3rd ferrule which hold | maintains a 4th optical fiber inside.

  As a result, the first transmission unit, the second transmission unit, and the third transmission unit are configured as ferrules that hold the optical fiber and the optical fiber, so that the first and second optical signals have an efficiency. It is transmitted well.

The optical multiplexing / demultiplexing unit is
A first collimator lens disposed on an end face of the first optical fiber on the first input / output side and converting a first optical signal output from the first optical fiber into collimator light;
A second collimator lens that is disposed on the first input / output end face of the second optical fiber and converts the second optical signal output from the second optical fiber into collimator light;
A third collimating lens disposed on the second input / output side end face of the third optical fiber and converting the first and second optical signals output from the third optical fiber into collimator light;
An optical filter that reflects the first optical signal and transmits the second optical signal;
A right angle prism having an optical filter disposed on the first inclined surface;
A parallelogram prism having second and third inclined surfaces, wherein the first inclined surface and the second inclined surface of the right-angle prism are in contact with each other through an optical filter;
The parallelogram prism transmits the first optical signal between the first transmission unit and the third transmission unit by reflecting the first optical signal on the second and third inclined surfaces. ,
The parallelogram prism and the right-angle prism transmit the second optical signal on the first and second inclined surfaces, whereby the second optical signal is transmitted between the first transmission unit and the third transmission unit. Is transmitted.

  As a result, the first and second optical signals transmitted through the first optical fiber, the second optical fiber, and the third optical fiber are converted into collimator light by the collimator lens, and are parallelograms. It is multiplexed / demultiplexed by a prism, an optical filter, and a right-angle prism. This eliminates the need for processing of the optical fiber when connecting the transmission unit to the optical multiplexing / demultiplexing unit, and prevents the optical axis from being shifted between the collimator lens and the optical fiber. At the same time, the complexity of the apparatus is eliminated and the apparatus can be miniaturized.

  Furthermore, the first optical fiber, the second optical fiber, and the third optical fiber may be TEC (Thermal Expanded Core) fibers.

  Thereby, the first optical fiber, the second optical fiber, and the third optical fiber can be configured to have a collimator function. This eliminates the need for adjustment of the optical axes of the collimator lens and the optical fiber, so that a wavelength multiplexing coupler can be produced economically.

  The optical multiplexing / demultiplexing unit includes an optical fiber for transmitting the first optical signal between the first transmission unit and the third transmission unit, and a second transmission unit and a third transmission unit. A fiber type optical coupler including an optical fiber for transmitting the second optical signal therebetween may be used.

  Thereby, the optical multiplexing / demultiplexing unit is a fiber-type optical coupler, so that the multiplexing / demultiplexing of the first optical signal and the second optical signal can be performed with high accuracy.

Preferably, the two receptacles included in the optical communication device include an attachment direction limiting unit for limiting the attachment direction of the first and second plug parts to be mated with each other,
The first and second plug parts include attachment direction guiding means for guiding the first and second plug parts in the attachment direction restricted by the attachment direction restriction means,
The mounting direction guiding means is characterized in that the first and second plug portions can be reversed to be guided in the mounting direction restricted by the mounting direction limiting means.

  Thus, the orientation of the wavelength division multiplexing coupler when it is attached to the optical communication apparatus including two receptacles is restricted by including the attachment direction guiding means for restricting the direction of the wavelength division multiplexing coupler. Since the wavelength multiplexing coupler mounting direction guiding means can be reversed left and right, when the wavelength multiplexing coupler is connected to the optical communication apparatus, it can be connected to the optical communication apparatus without changing the configuration of the wavelength multiplexing coupler.

Furthermore, the mounting direction limiting means is a first slit and a second slit provided in common on one side surface of the two receptacles,
The mounting direction guiding means is
Removable first and second positioning pins for guiding the first and second plug portions to the first and second slits,
Both are provided on the same plane, and first and second grooves for attaching and detaching the first and second positioning pins;
It is provided on the surface opposite to the surface on which the first and second grooves are provided, and includes third and fourth grooves for attaching and detaching the first and second positioning pins.

  Thereby, the attachment direction limiting means is constituted by a positioning pin and grooves provided in the first and second plugs to which the positioning pin can be attached and detached. For this reason, it is easy to change the mounting direction of the wavelength multiplexing coupler by the mounting direction guiding means.

Preferably, the optical multiplexing / demultiplexing unit is
A first collimator lens disposed on the optical axis of the first transmission unit and converting a first optical signal output from the first transmission unit into collimator light;
A second collimator lens disposed on the optical axis of the second transmission unit and converting the second optical signal output from the second transmission unit into collimator light;
A third collimating lens disposed on the optical axis of the third transmission unit and converting the first and second optical signals output from the third transmission unit into collimator light;
An optical filter that reflects the first optical signal and transmits the second optical signal;
A right angle prism having an optical filter disposed on the first inclined surface;
A parallelogram prism having second and third inclined surfaces, wherein the first inclined surface and the second inclined surface of the right-angle prism are in contact with each other through an optical filter;
The parallelogram prism transmits the first optical signal between the first transmission unit and the third transmission unit by reflecting the first optical signal on the second and third inclined surfaces. ,
The parallelogram prism and the right-angle prism transmit the second optical signal on the first and second inclined surfaces, whereby the second optical signal is transmitted between the first transmission unit and the third transmission unit. Is transmitted.

  As a result, the first and second optical signals transmitted through the first optical fiber, the second optical fiber, and the third optical fiber are converted into collimator light by the collimator lens, and are parallelograms. It is multiplexed / demultiplexed by a prism, an optical filter, and a right-angle prism. For this reason, the processing of the optical fiber for connecting the transmission unit to the optical multiplexing / demultiplexing unit becomes unnecessary, and the optical axis shift between the collimator lens and the optical fiber does not occur. At the same time, the complexity of the apparatus is eliminated and the apparatus can be miniaturized.

  The first collimator lens and the third collimator lens may be disposed in contact with the parallelogram prism, and the second collimator lens may be disposed in contact with the right-angle prism.

  Accordingly, the first collimator lens and the third collimator lens are in contact with the parallelogram prism, and the second collimator lens is disposed on the right-angle prism. For this reason, it becomes possible to arrange | position the 1st collimator lens, the 2nd collimator lens, and the 3rd collimator lens in the stable position.

  Further, the first collimator lens, the third collimator lens, and the parallelogram prism may be integrally molded, and the second collimator lens and the right-angle prism may be integrally molded.

  Accordingly, the first collimator lens, the third collimator lens, and the parallelogram prism are integrally formed, and the second collimator lens and the right-angle prism are integrally molded, so that the collimator function and the optical multiplexing / demultiplexing function are obtained. Integrated. For this reason, adjustment of the position of the collimator lens can be omitted.

The first collimator lens is disposed on the first input / output side of the first transmission unit,
The second collimator lens is disposed on the first input / output side of the second transmission unit,
The third collimator lens may be disposed on the second input / output side of the third transmission unit.

  Thereby, since the focal point of the collimator lens is configured to be disposed on the end face of the transmission unit, it is possible to reduce the influence on the optical axis shift between the components constituting the optical multiplexing / demultiplexing unit. For this reason, it becomes possible to reduce the influence of the loss of the first and second optical signals due to the deviation of the optical axis.

  Furthermore, the first transmission unit, the second transmission unit, and the third transmission unit may be a TEC (Thermal Expanded Core) fiber.

  Thereby, the first optical fiber, the second optical fiber, and the third optical fiber can be configured to have a collimator function. This eliminates the need for adjustment of the optical axes of the collimator lens and the optical fiber, so that a wavelength multiplexing coupler can be produced economically.

  Preferably, in the optical multiplexing / demultiplexing unit, the first optical signal is guided between the first transmission unit and the third transmission unit, and between the second transmission unit and the third transmission unit. It may be an optical waveguide in which two optical signals are guided.

  Thus, by combining the optical multiplexing / demultiplexing portion with the optical waveguide, it is possible to accurately perform multiplexing / demultiplexing of the first optical signal and the second optical signal.

  Preferably, the optical multiplexing / demultiplexing unit includes an optical fiber for transmitting the first optical signal between the first transmission unit and the third transmission unit, a second transmission unit, and a third transmission unit. A fiber type optical coupler comprising an optical fiber for transmitting a second optical signal between the two.

  Thereby, the optical multiplexing / demultiplexing unit is a fiber-type optical coupler, so that the first and second optical signals can be multiplexed / demultiplexed with high accuracy.

Preferably, the optical communication device includes a light emitting unit for emitting the first optical signal and a light receiving unit for receiving the second optical signal as components for handling the first and second optical signals. ,
One receptacle of the optical communication device accommodates the light emitting unit,
The other receptacle of the optical communication device accommodates the light receiving unit,
The first plug portion is fitted with one of the receptacles for coupling the first optical signal emitted from the light emitting portion to the first transmission portion,
The second plug portion is fitted with the other receptacle so that the second optical signal transmitted through the second transmission portion is incident on the light receiving portion.

  Accordingly, the optical communication device including the light emitting unit for emitting the first optical signal and the light emitting unit for emitting the second optical signal and the wavelength multiplexing coupler are coupled to each other from the optical communication device. The first optical signal to be transmitted and the second optical signal transmitted through the transmission line optical fiber are multiplexed / demultiplexed and transmitted through a single optical fiber in a multiplexed state. For this reason, it is easy to change the optical communication device used for the bidirectional optical communication system using the two-core optical fiber to the bidirectional optical communication system using the single-core optical fiber by using the wavelength multiplexing coupler. It becomes.

Preferably, the optical communication device includes a light receiving unit for receiving the first optical signal and a light emitting unit for emitting the second optical signal as components for handling the first and second optical signals. ,
One receptacle of the optical communication device accommodates the light receiving unit,
The other receptacle of the optical communication device accommodates the light emitting unit,
The first plug portion is fitted with one receptacle for causing the first optical signal transmitted through the first transmission portion to enter the light receiving portion,
The second plug portion is fitted with the other receptacle in order to couple the second optical signal emitted from the light emitting portion to the second transmission portion.

  As a result, an optical communication device including a light receiving unit for receiving the first optical signal and a light emitting unit for emitting the second optical signal is connected to the wavelength multiplexing coupler, thereby transmitting the transmission line optical fiber. The first optical signal for transmitting the optical signal and the second optical signal transmitted from the optical communication apparatus are multiplexed and demultiplexed and transmitted through a single optical fiber in a multiplexed state. For this reason, the use of the wavelength multiplexing coupler makes it possible to use an optical communication device used in a bidirectional optical communication system using a two-core optical fiber in a bidirectional optical communication system using a single-core optical fiber.

Preferably, the optical communication device is a component that handles the first and second optical signals, and a first light emitting unit for emitting the first optical signal and a second for emitting the second optical signal. With a light emitting part,
One receptacle of the optical communication device accommodates the first light emitting unit,
The other receptacle of the optical communication device accommodates the second light emitting unit,
The first plug portion is fitted with one receptacle for coupling the first optical signal emitted from the first light emitting portion to the first transmission portion,
The second plug portion is fitted with the other receptacle for coupling the second optical signal emitted from the second light emitting portion to the second transmission portion.

  Thus, by connecting the wavelength multiplexing coupler and the optical communication device including the first light emitting unit for emitting the first optical signal and the second light emitting unit for emitting the second optical signal, The first and second optical signals transmitted by the optical communication apparatus are combined and transmitted through a single optical fiber in a multiplexed state. For this reason, the use of the wavelength multiplexing coupler makes it possible to use an optical communication device used in a bidirectional optical communication system using a two-core optical fiber in a bidirectional optical communication system using a single-core optical fiber.

Preferably, the optical communication device is a component that handles the first and second optical signals, and includes a first light receiving unit for receiving the first optical signal and a second for receiving the second optical signal. With a light receiving part,
One receptacle of the optical communication device accommodates the first light receiving unit,
The other receptacle of the optical communication device accommodates the second light receiving unit.
The first plug portion is fitted with one receptacle for causing the first optical signal transmitted through the first transmission portion to enter the first light receiving portion,
The second plug portion is fitted with one receptacle so that the second optical signal transmitted through the second transmission portion is incident on the second light receiving portion.

  Thus, by connecting the wavelength division multiplexing coupler and the optical communication device including the first light receiving unit for receiving the first optical signal and the second light receiving unit for receiving the second optical signal, The multiplexed first and second optical signals transmitted through the transmission line optical fiber are demultiplexed by the wavelength multiplexing coupler and coupled to the first and second light receiving units of the optical communication apparatus. For this reason, the use of the wavelength multiplexing coupler makes it possible to use an optical communication device used in a bidirectional optical communication system using a two-core optical fiber in a bidirectional optical communication system using a single-core optical fiber.

  According to the present invention, a wavelength division multiplexing coupler according to the present invention includes two plug portions for connecting to an optical communication device including two receptacles in series, and a receptacle portion connected to a single-core optical fiber including the plugs. By providing the housing to be connected, the optical communication device and the single-core optical fiber including the plug can be connected. Accordingly, the wavelength division multiplexing coupler can multiplex / demultiplex two optical signals having different wavelengths handled by the optical communication apparatus. For this reason, it becomes possible to use the optical communication apparatus provided with two receptacles connected to each other in a bidirectional optical communication system using a single-core optical fiber.

(First embodiment)
FIG. 1 is a perspective view showing the configuration of the wavelength multiplexing coupler 1. 2 is a cross-sectional view of the wavelength multiplexing coupler 1 taken along line A1-A2 shown in FIG. 1 and 2, the same reference numerals are given to the same parts.

  The wavelength multiplexing coupler 1 includes a housing 101, a first ferrule 112a, a second ferrule 112b, a third ferrule 112c, a first optical fiber 113a, a second optical fiber 113b, and a third Optical fiber 113c, first spring 114a, second spring 114b, first collimator lens 118a, second collimator lens 118b, third collimator lens 118c, and parallelogram prism 119, , An optical filter 120, a right-angle prism 121, a movable base 122, a first compression spring 123, a split sleeve 124, a first positioning pin 111a, and a second positioning pin 111b. The housing 101 includes a first plug portion 102, a second plug portion 103, a receptacle portion 104, and a multiplexing / demultiplexing portion storage portion 105.

  In the housing 101, the first plug portion 102 and the second plug 103 have a plug shape. The receptacle part 104 has a shape of a receptacle. The optical multiplexing / demultiplexing unit storage unit 105 has a rectangular parallelepiped shape. A first plug portion 102 and a second plug portion 103 are arranged in parallel on the side surface in the arrow A direction of the optical multiplexing / demultiplexing portion storage portion 105 that is a rectangular parallelepiped. On the side surface opposite to the direction A of the optical multiplexing / demultiplexing portion storage portion 105, the receptacle portion 104 is disposed. The second plug portion 103 and the receptacle portion 104 are arranged on a straight line. The housing 101 can be divided into two along the cross section along line A1-A2 shown in FIG.

  Dovetail grooves 115 are formed in the upper and lower surfaces of the first plug portion 102 and the second plug portion 103. The housing 101 has two dents, a first dent part 117a and a second dent part 117b, on the side surfaces of the two plug parts. The dovetail groove 115 is a groove having a trapezoidal cross section in which the length of the upper base is shorter than that of the lower base. The first positioning pin 111 a and the second positioning pin 111 b are attached to the dovetail groove 115. The first positioning pin 111a and the second positioning pin are rod-like elongated objects. The first positioning pin 111a has a rectangular cross section at the top. The lower part of the cross section of the first positioning pin 111a has a trapezoidal shape in which the length of the upper base called an ant is shorter than the lower base. The second positioning pin 11b has the same shape as the first positioning pin 111a.

  Inside the first plug portion 102, a first transmission portion including a first ferrule 112a and a first optical fiber 113a, and a first spring 114a are disposed. The first ferrule 112a holds the first optical fiber 113a inside. The first spring 114a presses the first ferrule 112a in the direction opposite to the arrow A.

  Inside the second plug portion 103, a second transmission portion including the second ferrule 112b and the second optical fiber 113b, and a second spring 114b are arranged. The second ferrule 112b holds the second optical fiber 113b inside. The second spring 114b presses the second ferrule 112b in the direction opposite to the arrow A.

  Inside the receptacle section 104, a third transmission section including a third ferrule 112c and a third optical fiber 113c, and a split sleeve 124 are disposed. The split sleeve 124 is formed between a ferrule (not shown) included in the transmission line optical fiber plug and the third ferrule 112c when the plug (not shown) of the transmission line optical fiber and the receptacle 104 are fitted. Axis deviation that occurs in The third ferrule 112c holds the third optical fiber 113c.

  The optical multiplexing / demultiplexing unit storage unit 105 is hollow. A movable base 122 and a first compression spring 123 are stored in the optical multiplexing / demultiplexing unit storage unit 105. The first collimator lens 118a, the second collimator lens 118b, the third collimator lens 118c, the parallelogram prism 119, the optical filter 120, and the right-angle prism 121 constitute an optical multiplexing / demultiplexing unit. The optical multiplexing / demultiplexing unit receives optical signals from the first input / output side in the direction of arrow A and the second input / output side in the direction opposite to arrow A, respectively. The movable base 122 is an optical multiplexing / demultiplexing unit holding unit for holding the optical multiplexing / demultiplexing unit. The first compression spring 123 is installed on the inner side surface of the optical multiplexing / demultiplexing unit storage unit 105. The first compression spring 123 presses the movable base 122 in the direction of arrow A.

  The first collimator lens 118a is in contact with the parallelogram prism 119 so as to be positioned on the optical axis of the first optical fiber 113a. The second collimator lens 118b is in contact with the right-angle prism 121 so as to be positioned on the optical axis of the second optical fiber 113b. The third collimator lens 118c is in contact with the parallelogram prism 119 so as to be positioned on the optical axis of the third optical fiber 113c. The right-angle prism 121 is installed on the movable base 122. At this time, the direction of the right-angle prism 121 is the top side of the hypotenuse that is the first inclined surface. The parallelogram prism 119 is installed in contact with the first inclined surface of the right-angle prism 121. In the parallelogram prism 119, a surface in contact with the first inclined surface of the right-angle prism 121 is defined as a second inclined surface, and a surface opposite to the first inclined surface is defined as a third inclined surface. The right-angle light filter 120 is inserted between the first inclined surface of the right-angle prism 121 and the second inclined surface of the parallelogram prism 119.

  The first collimator lens 118a converts light emitted from the first optical fiber 113a into collimated light and inputs the collimated light to the parallelogram prism 119. The second collimator lens 118b condenses the collimated light emitted from the third collimator lens 118c and inputs it to the second optical fiber 113b. The third collimator lens 118 c converts light emitted from the third optical fiber 113 c into collimated light and inputs the collimated light to the parallelogram prism 119. The parallelogram prism 119 changes the optical path by reflecting the optical signals incident from the first collimator lens 118a and the third collimator lens 118c on the second inclined surface and the third inclined surface. The right-angle prism 121 changes the optical path of the optical signal incident from the third collimator lens 118c. The optical filter 120 reflects the signal of wavelength λ1 and transmits the optical signal of wavelength λ2 in the optical signal input and output by the wavelength multiplexing coupler 1.

  FIG. 3 is a perspective view showing a state when the single-core plug 300 and the double receptacle-type optical transceiver 200 are connected using the wavelength division multiplexing coupler 1. A method of using the wavelength multiplexing coupler 1 will be described.

  In FIG. 3, a duplex receptacle-type optical transceiver 200 includes a light emitting element 201, a light receiving element 202, and a duplex receptacle 203. The two receptacles 203 are provided with a first positioning slit 204a and a second positioning slit 204b. In the double receptacle type optical transceiver 200, display of circuit configurations other than the light emitting element 201 and the light receiving element 202 is omitted. The plug 300 is connected to a transmission line side optical fiber (not shown).

  FIG. 4 is a cross-sectional view taken along line B1-B2 of the dual-receptacle optical transceiver 200 shown in FIG. As shown in FIG. 4, the double receptacle 203 includes a first position restricting portion 205a, a second position restricting portion 205b, a first lock portion 206a, and a second lock portion 206b. The light emitting element 201 emits an optical signal having a wavelength λ1. The light receiving element 202 receives an optical signal having a wavelength λ2.

  5 is a cross-sectional view taken along line C1-C2 of the plug 300 shown in FIG. The plug 300 includes a fourth ferrule 301, a fourth optical fiber 302, and a fourth spring 303. The fourth ferrule 301 holds the fourth optical fiber 302. The fourth spring 303 presses the fourth ferrule 301 in the direction of arrow A. The optical fiber jacket portion 304 covers and protects the fourth optical fiber.

  As shown in FIG. 3, the first plug portion 102 and the second plug portion 103 in the casing 101 of the wavelength division multiplexing coupler 1 are fitted with the two receptacles 203 of the two receptacle optical transceivers 200. . When the wavelength division multiplexing coupler 1 is connected to the double receptacle type optical transceiver 200, the direction of the wavelength division multiplexing coupler 1 is such that the projecting portion composed of the first positioning pin 111a and the second positioning pin 111b, and the double receptacle. The groove formed by the first positioning slit 204a and the second positioning slit 204b of the type optical transmitter / receiver 200 is in the same direction. As described above, the first positioning slit 204a and the second positioning slit 204b serve as plug attachment direction limiting means for determining the orientation of the plug fitted to the two receptacles 203. The receptacle 104 arranged in the housing 101 of the wavelength division coupler 1 is fitted with the plug 300.

  6 is a cross-sectional view taken along line B1-B2 shown in FIG. 3 when the wavelength division multiplexing coupler 1, the double receptacle type optical transceiver 200, and the plug 300 are connected. The connection between the wavelength division multiplexing coupler 1 and the double receptacle-type optical transceiver 200 will be described in detail with reference to FIG.

  When the wavelength multiplexing coupler 1 is connected to the duplex receptacle-type optical transceiver 200, first, the first ferrule 112a of the wavelength multiplexing coupler 1 is the first position restricting unit of the duplex receptacle-type optical transceiver 200. It abuts on 205a. Further, the second ferrule 112b abuts on the second position restricting portion 205b. In this state, when the wavelength multiplexing coupler 1 is continuously pushed to the double receptacle type optical transceiver 200, the first lock unit 206a of the double receptacle type optical transceiver 200 causes the first locking unit 206a of the wavelength multiplexing coupler 1 to It fits into the recess 117a. Similarly, the second lock portion 206b is fitted into the second dent portion 117b. In this state, the wavelength division multiplexing coupler 1 and the double receptacle type optical transceiver 200 are connected.

  In a state where the wavelength division multiplexing coupler 1 and the double receptacle type optical transceiver 200 are connected, the first ferrule 112a of the wavelength division multiplexing coupler 1 is pressed by the first spring 114a so as to contact the surface of the movable base 122. It is done. The end of the second ferrule 112b is pressed by the second spring 114b so as to contact the surface of the movable base 122. In the wavelength multiplexing coupler 1, the force by which the first compression spring 123 presses the movable base 122 in the direction of the arrow A is that the first spring 114a and the second spring 114b are the first ferrule 112a and the second ferrule. It is greater than the force pressing 112b in the direction opposite to arrow A. For this reason, the end face of the first ferrule 112 a and the end face of the second ferrule 112 b are always in close contact with the end face of the movable base 122. Therefore, the focal position of the first collimator lens 118a is always the end face of the first optical fiber 113a. Similarly, the focal position of the second collimator lens 118b is always the end face of the second optical fiber 113b.

  When the wavelength multiplexing coupler 1 and the plug 300 are connected, the end of the third ferrule 112c and the end of the fourth ferrule 301 of the plug are aligned with each other in the split sleeve 124 of the wavelength multiplexing coupler 1. Abut in state. In the plug 300, the fourth spring 303 presses the fourth ferrule 301 in the direction of arrow A. In the wavelength multiplexing coupler 1, the third ferrule 112 c is pressed against the movable base 122 by the fourth spring 303 of the plug 300. Therefore, the end face of the third optical fiber 113c is always located at the focal point of the third collimator lens 118c.

  Next, details of the operation of the wavelength division multiplexing coupler 1 will be described with reference to FIG.

  The wavelength multiplex coupler 1 receives an optical signal having a wavelength λ1 that is emitted from the light emitting element 201 of the double receptacle type optical transceiver 200. The optical signal having the wavelength λ1 is incident on the first collimator lens 118a via the first optical fiber 113a. The first collimator lens 118a converts the optical signal having the wavelength λ1 into collimated light. The parallelogram prism 119 receives an optical signal having a wavelength λ1 that is collimated light. The parallelogram prism 119 is reflected by the second inclined surface and the third inclined surface, and changes the optical signal optical path of the wavelength λ1 which is collimated light. When the parallelogram prism 119 changes the optical path, the optical signal having the wavelength λ1, which is collimated light, is reflected in the direction of the third collimator lens 118c on the surface where the optical filter 120 and the parallelogram prism 119 are in contact with each other. . The third collimator lens 118c collects an optical signal having a wavelength λ1 that is collimated light on the end face of the third ferrule 112c that incorporates the third optical fiber 113c, and inputs the condensed optical signal to the third optical fiber 113c. The collected optical signal having the wavelength λ1 is input to the fourth optical fiber 302 of the plug 300 from the third optical fiber 113c and transmitted.

  The optical signal of wavelength λ2 output from the fourth fiber 302 is input to the third optical fiber 113c of the wavelength multiplexing coupler 1 through the third optical fiber 113c. An optical signal having a wavelength λ2 is input from the third optical fiber 113c to the third collimator lens 118c. The third collimator lens 118c converts the optical signal having the wavelength λ2 into collimated light. The optical signal of wavelength λ2, which is collimated light, passes through the parallelogram prism 119, the optical filter 120, and the right-angle prism 121, and is input to the second collimator lens 118b. The second collimator lens 118b collects an optical signal having a wavelength λ2 that is collimated light on the end face of the second ferrule 112b. The light signal 202 having the wavelength λ2 output from the second optical fiber 113b is input to the light receiving element 202 of the double receptacle type optical transceiver 200. In this way, the wavelength division multiplexing coupler 1 can transmit an optical signal input / output to / from the double receptacle type optical transceiver in a bidirectional optical communication system using a single-core optical fiber.

  FIG. 7 is a diagram illustrating attachment / detachment of the first positioning pin 111a of the wavelength division multiplexing coupler 1. The functions of the positioning pin and the dovetail in the wavelength multiplexing coupler 1 will be described.

  As shown in FIG. 7, the first positioning pin 111 a is attached to the wavelength multiplexing coupler 1 by inserting the ant portion of the first positioning pin 111 a into the dovetail groove 115. The second positioning pin 111 b is attached to the wavelength multiplexing coupler 1 by being inserted into the dovetail groove 115. The first positioning pin 111a and the second positioning pin 111b are mounted on the upper surface or the lower surface of the wavelength multiplexing coupler 1 so as to determine the direction of connection to the double receptacle type optical transceiver. It becomes.

  In FIG. 3, the first positioning pin 111 a and the second positioning pin 111 b are attached to the upper surface of the wavelength multiplexing coupler 1. For this reason, the direction of the wavelength multiplexing coupler 1 is such that the first ferrule 112a and the light emitting element 201 are connected, and the second ferrule 112b and the light receiving element 202 are connected. When the first positioning pin 111a and the second positioning pin 111b are attached to the lower surface of the wavelength multiplexing coupler 1, the direction of the wavelength multiplexing coupler 1 is such that the first ferrule 112a and the light receiving element 202 are connected to each other. The orientation is such that the ferrule 112b and the light emitting element 201 are connected.

  FIGS. 8A to 8C are diagrams illustrating the function of the positioning pin of the wavelength multiplexing coupler 1. A problem that occurs when the mounting positions of the first positioning pin 111a and the second positioning pin 111b cannot be changed in the wavelength multiplexing coupler 1 will be described with reference to FIGS. 8A to 8C.

  Consider a case in which two receptacle-type optical transceivers are used to perform bi-directional optical communication using a single-core optical fiber. FIG. 8A is a diagram for realizing bidirectional optical communication using a two-core optical fiber. The first duplex receptacle-type optical transceiver 210 includes a first light emitting unit 211 and a second light receiving unit 212. The second duplex receptacle-type optical transceiver 220 includes a second light emitting unit 221 and a second light receiving unit 222. The first transmission line optical fiber 310 includes a first plug 311 and a second plug 312. The second transmission line optical fiber 320 includes a third plug 321 and a fourth plug 322.

  The first light emitting unit emits 1.3 μm light. The second light emitting unit emits light of 1.55 μm. In FIG. 8, the description will be made assuming that λ1 = 1.3 μm and λ2 = 1.55 μm. The first plug 311 and the second plug 312 are connected to both ends of the first transmission line optical fiber 310. The third plug 321 and the fourth plug 322 are connected to both ends of the second transmission line optical fiber 320.

  In FIG. 8A, the first transmission line optical fiber 310 is connected to the first light emitting unit 211 and the second light receiving unit 222. The second transmission line optical fiber 320 is connected to the second light emitting unit 221 and the first light receiving unit 212. At this time, the first transmission line optical fiber 310 and the second transmission line optical fiber 320 are connected to the light emitting unit and the light receiving unit of the respective receptacle type optical transceivers to perform bidirectional optical communication.

  FIG. 8B is a diagram for explaining the flow of an optical signal when the positioning pin of the wavelength multiplexing coupler 1 is not changed. In FIG. 8B, the third transmission line optical fiber 330 includes a fifth plug 331 and a sixth plug 332. The fifth plug 331 and the sixth plug 332 are connected to both ends of the third transmission line optical fiber 330. The first duplex receptacle-type optical transceiver 210 is connected to the first wavelength multiplexing coupler 1a. The second duplex receptacle type optical transceiver 220 is connected to the second wavelength multiplexing coupler 1b. The first wavelength multiplexing coupler 1 a and the second wavelength multiplexing coupler 1 b are connected via a third transmission line optical fiber 330. The arrow schematically shows the path of the optical signal 40 having the wavelength λ1 in the first wavelength division coupler 1a and the second wavelength division coupler 1b.

  It is assumed that the first wavelength multiplexing coupler 1a and the second wavelength multiplexing coupler 1b both have a first positioning pin 111a and a second positioning pin 111b attached to the upper surface. At this time, the direction in which the first wavelength multiplexing coupler 1a is connected to the first duplex receptacle-type wavelength multiplexing coupler 210, and the second wavelength multiplexing coupler 1b is coupled to the second duplex receptacle-type wavelength multiplexing coupler 220. The direction of connection is the same. Both the first wavelength multiplexing coupler 1a and the second wavelength multiplexing coupler 1b are provided with an optical filter 120 that reflects an optical signal of λ1 = 1.3 μm.

  The optical signal of wavelength λ1 emitted from the first light emitting unit 211 of the first duplex receptacle type optical transceiver 210 is input to the first wavelength multiplexing coupler 1a. The optical signal 40 having the wavelength λ1 is output from the first wavelength multiplexing coupler 1a and input to the second wavelength multiplexing coupler 1b via the optical fiber 330 cable. The optical signal of wavelength λ1 input to the second wavelength multiplexing coupler 1b is output from the second wavelength multiplexing coupler 1b through a path opposite to that of the first wavelength multiplexing coupler 1. At this time, the optical signal 40 having the wavelength λ1 output from the second wavelength multiplexing coupler 1b is output to the light emitting unit 221 of the second duplex receptacle type optical transceiver. For this reason, when the positioning pin of the wavelength multiplexing coupler 1 is not changed, there arises a problem that a signal is input to the light emitting unit.

  FIG. 8C is a diagram for explaining the flow of an optical signal when the positioning pin of the wavelength multiplexing coupler 1 is changed. In FIG. 8C, the first duplex receptacle-type optical transceiver 210 is connected to the third wavelength multiplexing coupler 1c. The second duplex receptacle type optical transceiver 220 is connected to the fourth wavelength multiplexing coupler 1d. The third wavelength multiplexing coupler 1 c and the fourth wavelength multiplexing coupler 1 d are connected via a transmission line optical fiber 330. The arrow schematically shows the path of the optical signal 40 having the wavelength λ1 in the first wavelength multiplexing coupler 1a.

  The third wavelength multiplexing coupler 1c is assumed to have a first positioning pin 111a and a second positioning pin 111b attached to the upper surface. The fourth wavelength multiplexing coupler 1d is assumed to have a first positioning pin 111a and a second positioning pin 111b attached to the lower surface. At this time, the direction in which the third wavelength multiplexing coupler 1c is connected to the first duplex receptacle-type optical transceiver 210 and the fourth wavelength multiplexing coupler 1d are connected to the second duplex receptacle-type optical transceiver. The direction to do is the opposite direction. Each of the third wavelength multiplexing coupler 1c and the fourth wavelength multiplexing coupler 1d includes an optical filter 120 that reflects an optical signal of λ1 = 1.3 μm.

  The optical signal having the wavelength λ1 emitted from the first light emitting unit 211 of the first duplex receptacle-type optical transceiver 210 is input to the third wavelength multiplexing coupler 1c. The optical signal 40 having the wavelength λ1 is output from the third wavelength multiplexing coupler 1c and is input to the fourth wavelength multiplexing coupler 1d via the optical fiber cable 330. The optical signal 40 having the wavelength λ1 input to the fourth wavelength multiplexing coupler 1d is output from the fourth wavelength multiplexing coupler 1d through a path opposite to that of the third wavelength multiplexing coupler 1c. At this time, the optical signal having the wavelength λ1 incident on the fourth wavelength multiplexing coupler 1d is incident on the second light receiving unit 222 of the second duplex receptacle-type optical transceiver 220. Therefore, by changing the mounting position of the positioning pin of the third wavelength multiplexing coupler 1c and the mounting position of the positioning pin of the fourth wavelength multiplexing coupler 1d, the second duplex receptacle type optical transceiver 220 can be obtained. It becomes possible to receive light from the first duplex receptacle-type optical transceiver 210.

  As described above, the wavelength multiplexing coupler 1 according to the present embodiment includes the two plugs connected to the two-core receptacle, the receptacle connected to the one-core plug, and the optical multiplexing / demultiplexing that demultiplexes / multiplexes the optical signal. A wavelength division multiplexing coupler suitable for applying a duplex receptacle type optical transceiver to a bidirectional optical communication system via a single optical fiber. The first spring 114a presses the first ferrule 112a, the second spring 114b presses the second ferrule 112b, and the compression spring 123 presses the movable base 122, so that the first collimator Since the focal points of the lens and the second collimator lens can always be maintained on the end faces of the first optical fiber and the second optical fiber, the coupling loss of the optical signal can be reduced.

  In the present embodiment, the wavelength multiplexing coupler 1 has been described as being connected to a double receptacle type optical transceiver, but may be used for other components. For example, the wavelength multiplexing coupler 1 may be used instead of the receptacle-type wavelength multiplexing coupler 503 shown in FIG.

  The first spring, the second spring, and the third spring may be other elastic bodies. For example, instead of the first spring, the second spring, and the third spring, a ring-shaped elastic rubber can be used.

  Further, the shape of the cross section of the dovetail groove 115 may not be a trapezoid. For example, the cross section of the dovetail groove 115 may have a convex shape. At this time, the shape of the lower part of the cross section of the first positioning pin 111a and the second positioning pin 111b is a convex shape.

  Further, the wavelength multiplexing coupler 1 may be connected to a double receptacle type optical transmitter having two light emitting elements. In this case, it is possible to multiplex two optical signals having different wavelengths emitted from the two receptacle-type optical transmitters and transmit them through a single-core transmission line optical fiber. Two optical signals having different wavelengths emitted from the dual receptacle-type optical transmitters are incident on the first optical fiber 113a and the second optical fiber 113b, multiplexed by the optical multiplexing / demultiplexing unit, The light is emitted from the optical fiber 113c.

  Further, the wavelength multiplexing coupler 1 may be connected to a double receptacle type optical receiver including two light receiving elements. An optical signal in which two optical signals having different wavelengths are multiplexed can be received by a dual-receptacle optical receiver. In this case, the optical signal in which two optical signals having different wavelengths transmitted from the transmission line optical fiber are multiplexed is incident on the third optical fiber 113c, and is demultiplexed by the optical multiplexing / demultiplexing unit. By exiting from the fiber 113a and the second optical fiber 113b, the light is input to the light receiving element of the double receptacle type optical receiver.

(Second Embodiment)
FIG. 9 is a cross-sectional view of the wavelength multiplexing coupler 2 according to the second embodiment of the present invention. The cross-sectional view of the wavelength multiplexing coupler 2 shown in FIG. 9 corresponds to the cross-sectional view taken along the line A1-A2 of the wavelength multiplexing coupler 1 shown in FIG. FIG. 10 is a cross-sectional view of the wavelength multiplexing coupler 2. The cross section of the wavelength multiplexing coupler 2 shown in FIG. 10 corresponds to the cross section along line A3-A4 of the wavelength multiplexing coupler 1 shown in FIG. Note that the same reference numerals are assigned to the same components as those in the first embodiment. Below, only a different part from 1st Embodiment is demonstrated.

  The difference between the wavelength multiplexing coupler 2 and the wavelength multiplexing coupler 1 is the following two points. The first point is that instead of the first collimator lens 118a, the third collimator lens 118c, and the parallelogram prism 119 of the wavelength multiplexing coupler 1, the first collimating lens is used in the optical multiplexing / demultiplexing unit of the wavelength multiplexing coupler 2. 118 a, a second collimator lens 118 b, and a parallelogram prism 119 are integrally formed, and an integrated parallelogram prism 131 is provided. The integrated parallelogram prism 131 includes a collimator lens part 131a and a collimator lens part 131b. The second point is that, in the wavelength division multiplexing coupler 2, the second collimator lens 118b and the right angle prism 121 are integrally formed in place of the second collimator lens 118b and the right angle prism 121 used in the wavelength division multiplexing coupler 1. This is a point provided with an integrated right-angle prism 132. The integrated right-angle prism 132 includes a collimator lens portion 132a. The integrated parallelogram prism 131 and the integrated right-angle prism 132 are fixed on the movable base 122.

  In the wavelength multiplexing coupler 2, the optical signal having the wavelength λ1 emitted from the first optical fiber 113a is directly incident on the collimator lens portion 131a of the integrated parallelogram prism 131. The optical signal having the wavelength λ1 incident on the integrated parallelogram prism 131 is converted into collimated light by the collimator lens unit 131a. The optical signal having the wavelength λ1 that is collimated light is reflected in the direction opposite to the arrow A by the optical filter 120 when the integrated parallelogram prism 131 changes the optical path. The optical signal of wavelength λ1, which is collimated light, is emitted from the collimator lens portion 131b of the integrated parallelogram prism 131 and enters the third optical fiber 113c. When an optical signal having a wavelength λ1, which is collimated light, is emitted from the integrated parallelogram prism 131, the optical signal having a wavelength λ1 is collected on the end surface of the third optical fiber 113c by the collimator lens portion 131b.

  The optical signal having the wavelength λ <b> 2 emitted from the third optical fiber 113 c is incident on the collimator lens portion 131 b of the integrated parallelogram prism 131. The optical signal having the wavelength λ2 incident on the collimator lens unit 131b is converted into collimated light. The optical signal having the wavelength λ 2 that is collimated light passes through the integrated parallelogram prism 131 and the optical filter 120 and is input to the integrated right-angle prism 132. When an optical signal having a wavelength λ2 that is collimated light is emitted from the integrated parallelogram prism, the optical signal having a wavelength λ2 that is collimated light is condensed on the end face of the second optical fiber 112 by the collimator lens unit 131b. .

  As described above, the wavelength multiplexing coupler 2 according to the second embodiment uses the integrated parallelogram prism 131 and the integrated right-angle prism 132, thereby eliminating the need to adjust the optical axis of the collimator lens, thereby increasing mass productivity. An excellent wavelength multiplexing coupler can be provided.

(Third embodiment)
FIG. 11 is a cross-sectional view of the wavelength multiplexing coupler 3 according to the third embodiment of the present invention. The cross-sectional view shown in FIG. 11 corresponds to the cross-sectional view taken along the line A1-A2 of the wavelength multiplexing coupler 1 shown in FIG. FIG. 13 is a sectional view of the wavelength division multiplexing coupler 3. 13 corresponds to a cross-sectional view taken along line A3-A4 of the wavelength multiplexing coupler 1 shown in FIG. Note that the same reference numerals are assigned to the same components as those in the first embodiment. Below, only a different part from 1st Embodiment is demonstrated.

  The wavelength multiplexing coupler 1 according to the first embodiment is different from the wavelength multiplexing coupler 3 in the following three points. The first point is that the wavelength multiplexing coupler 3 shown in FIG. 9 includes a housing 106 in which the position of the receptacle 104 is different. The receptacle 104 is disposed at the center of the side surface facing away from the cuboid arrow A. The second point is that the wavelength multiplexing coupler 1 includes the first compression spring 123, whereas the wavelength multiplexing coupler 3 includes the second compression spring 142 and the third compression spring 143. The third point is that the wavelength multiplexing coupler 1 is an optical multiplexing / demultiplexing unit, and the first collimator lens 118a, the second collimator lens 118b, the third collimator lens 118c, the parallelogram prism 119, and the right angle prism 121. And the optical filter 120, the wavelength multiplexing coupler 3 is provided with an optical waveguide 141. The optical waveguide 141 satisfies the mode coupling condition of the optical signal having the wavelength λ1 and the optical signal having the wavelength λ2.

  The second compression spring 142 and the third compression spring 143 press the movable base 122 in the direction of arrow A. The force that the two springs of the second compression spring 142 and the third compression spring 143 press the movable base 122 in the direction of arrow A is that the first spring 114a and the second spring 114b are the first ferrule. The force is greater than the force pressing the 112 a and the second ferrule 112 b against the movable base 122. For this reason, the end face of the first ferrule 112 a and the end face of the second ferrule 112 b are always in contact with the movable base 122.

  The optical signal of λ1 emitted from the first optical fiber 113a is input to the optical waveguide 141. The optical signal having the wavelength λ1 output from the optical waveguide 141 is input to the third optical fiber 113c. In the optical waveguide 141, the light of wavelength λ1 is guided in the direction of the third optical fiber 113c by generating mode coupling, and is output to the third optical fiber 113c. An optical signal of wavelength λ1 output from the third optical fiber 113c is input to a transmission line optical fiber (not shown).

  The optical signal having the wavelength λ2 output from the transmission line optical fiber (not shown) is input to the third optical fiber 113c. An optical signal having a wavelength λ2 is input to the optical waveguide 141 from the third optical fiber 113c. In the optical waveguide 141, the optical signal having the wavelength λ2 is guided in the direction of the second optical fiber 113b by generating mode coupling, and is output to the second optical fiber 113b. The second optical fiber 113b outputs an optical signal having a wavelength λ2.

  Thus, since the wavelength multiplexing coupler 3 according to the third embodiment uses the optical waveguide 141, it is not necessary to use a collimator lens. The optical waveguide 141 can be manufactured with a mask pattern, and can be manufactured with a higher precision pitch. Further, by using the optical waveguide 141, it is possible to realize a wavelength division multiplexing coupler with excellent mass productivity.

(Fourth embodiment)
FIG. 13 is a cross-sectional view of the wavelength multiplexing coupler 4 according to the fourth embodiment of the present invention. The cross-sectional view shown in FIG. 13 corresponds to the cross-sectional view taken along the line A1-A2 of the wavelength multiplexing coupler 1 shown in FIG. Note that the same reference numerals are assigned to the same components as those in the first embodiment. Below, only a different part from 1st Embodiment is demonstrated.

  The wavelength multiplexing coupler 4 according to the fourth embodiment differs from the first embodiment in three points. The first point is that in the wavelength multiplexing coupler 4, the position of the first collimator lens 118a, the position of the second collimator lens 118b, and the position of the third collimator lens 118c are changed. The second point is that there is no movable base 122 provided in the wavelength division multiplexing coupler 1. The third point is that a third spring 114c is provided instead of the first compression spring in the wavelength multiplexing coupler 1. The third spring is installed in the receptacle part 104. The third spring 114c presses the third ferrule 112c in the direction opposite to the direction A.

  In the wavelength multiplexing coupler 4, the first collimator lens 151a is installed on the end face of the first ferrule 112a. The second collimator lens 151b is installed on the end face of the second ferrule 112b. The third collimator lens 151c is installed on the end face of the third ferrule 112c. The first collimator lens 151a converts light emitted from the first optical fiber 113a into collimated light. The second collimator lens 151b converts light emitted from the second optical fiber 113b into collimated light. The third collimator lens 151c converts light emitted from the third optical fiber 113c into collimated light.

  By installing the first collimator lens 151a, the second collimator lens 151b, and the third collimator lens 151c on the end face of the ferrule, it is not necessary to move the ferrule to the focal plane of the lens. Therefore, in the wavelength multiplexing coupler 4, the right-angle prism 121 is installed on the casing 101 of the wavelength multiplexing coupler 4.

  FIG. 14 is a diagram showing a state where the wavelength division multiplexing coupler 4 according to the fourth embodiment is connected to the two receptacle-type optical transceivers 200 and the plugs 300. The end face of the first ferrule 112a is fixed by the first position restricting portion 205a of the double receptacle type optical transceiver 200. Similarly, the end face of the second ferrule 112b is fixed by the second position restricting portion 205b of the double receptacle type optical transceiver 200. When the wavelength multiplexing coupler 4 is inserted into the double receptacle type optical transceiver 200, the wavelength multiplexing coupler 4 includes the first lock unit 206 a of the dual receptacle type optical transceiver 200. The second locking portion 206b of the double receptacle type optical transceiver 200 is fixed by being fitted to the second dent portion 117b of the wavelength multiplexing coupler 4 while being fitted to the dent portion 117a. The first spring 114a presses the first ferrule 112a in the direction of arrow A. The second ferrule 112b is fixed while being pressed by the position restricting portion 205a of the double receptacle type optical transceiver 200. The second spring 112b presses the second ferrule 112b in the direction of arrow A. The second ferrule 112b is fixed in a state of being pressed by the position restricting portion 205b of the double receptacle type optical transceiver 200.

  The wavelength multiplex coupler 4 and the plug 300 are brought into contact with the third ferrule 112c and the fourth ferrule 301 with their axes aligned by the split sleeve 124 of the wavelength multiplex coupler 4. The fourth spring 303 of the plug 300 presses the fourth ferrule 301 in the direction of arrow A. Further, the third spring 114 c of the wavelength multiplexing coupler 4 presses the third ferrule 112 c in the direction opposite to the arrow A. Therefore, the end face of the third ferrule 112c and the end face of the fourth ferrule 301 of the plug 300 are always brought into contact with each other.

  In the wavelength multiplexing coupler 4, the optical signal having the wavelength λ 1 emitted from the light emitting element 201 of the double receptacle type optical transceiver 200 is incident on the first optical fiber 113 a. An optical signal having a wavelength λ1 is input from the first optical fiber 113a to the first collimator lens 151a. The first collimator lens 151a converts an optical signal having a wavelength λ1 into collimated light. The parallelogram prism 119 receives an optical signal having a wavelength λ1 that is collimated light. The parallelogram prism 119 changes the optical path of the optical signal having the wavelength λ1 that is collimated light. When the parallelogram prism 119 changes the optical path, the optical signal having the wavelength λ1, which is collimated light, is reflected in the direction of the third collimator lens 151c on the surface where the optical filter and the parallelogram prism 119 are in contact with each other. The third collimator lens 151c condenses the optical signal having the wavelength λ1, which is collimated light, on the end face of the third ferrule 112c that incorporates the third optical fiber 113c, and inputs it to the third optical fiber 113c. The collected optical signal having the wavelength λ1 is input to the fourth optical fiber 302 of the plug 300 from the third optical fiber 113c and transmitted.

  In the wavelength multiplexing coupler 4, the optical signal having the wavelength λ <b> 2 output from the fourth optical fiber 302 is input to the third optical fiber 113 c of the wavelength multiplexing coupler 4. An optical signal having a wavelength λ2 is input from the third optical fiber 113c to the third collimator lens 151c. The third collimator lens 151c converts the optical signal having the wavelength λ2 into collimated light. The optical signal of wavelength λ2, which is collimated light, passes through the parallelogram prism, the optical filter, and the right-angle prism 121, and is input to the second collimator lens 151b. The second collimator lens 151b collects the optical signal having the wavelength λ2 that is collimated light on the end face of the second ferrule 112b. The light signal 202 having the wavelength λ2 output from the second optical fiber 113b is input to the light receiving element 202 of the double receptacle type optical transceiver 200. In this manner, the wavelength division multiplexing coupler 4 enables transmission of an optical signal input / output to / from the double receptacle type optical transceiver in a bidirectional optical communication system using a single-core optical fiber.

  Thus, in the fourth embodiment, the first collimator lens 151a, the second collimator lens 151b, and the third collimator lens 151c are installed integrally with the ferrule, so that the collimator lens Coupling is performed in a state where the beam width of an incident or outgoing optical signal is expanded. For this reason, when the optical signal is collected on the end face of the optical fiber like the wavelength multiplexing coupler 1, it is possible to reduce the influence on the coupling loss caused by the deviation of the optical axis.

  In addition, the 1st optical fiber 113a, the 2nd optical fiber 113b, and the 3rd optical fiber 113c use the TEC (Thermal Expanded Core) fiber which expanded the mode field diameter of the optical fiber locally. Also good. Thereby, the 1st collimator lens 151a, the 2nd collimator lens 151b, and the 3rd collimator lens 151c become unnecessary. Further, since the lens positioning step is not required, the distance between the optical system including the parallelogram prism 119, the optical filter, and the right-angle prism 121, and the first optical fiber 113a is set in the first embodiment. It becomes possible to make it shorter than the wavelength multiplexing coupler 1 concerned. Similarly, the distance between the second optical fiber 113b and the optical system and the distance between the third optical fiber 113c and the optical system may be shorter than those of the wavelength multiplexing coupler 1 according to the first embodiment. It becomes possible. Therefore, the wavelength multiplexing coupler 4 can be further downsized than the wavelength multiplexing coupler 1.

(Fifth embodiment)
FIG. 15 is a cross-sectional view of the wavelength multiplexing coupler 5 according to the fifth embodiment of the present invention. The cross-sectional view shown in FIG. 13 corresponds to the cross-sectional view taken along the line A1-A2 of the wavelength multiplexing coupler 1 shown in FIG. Note that the same reference numerals are assigned to the same components as those in the first embodiment. Below, only a different part from 1st Embodiment is demonstrated.

  The wavelength multiplexing coupler 5 according to the fifth embodiment is different from the wavelength multiplexing coupler 1 in two points. The first point is that the position of the receptacle 104 of the casing 102 of the wavelength multiplexing coupler 5 is different from that of the casing 101 of the wavelength multiplexing coupler 1. The receptacle 104 is disposed at the center of the side of the rectangular parallelepiped facing away from the arrow A. The second point is that the wavelength multiplexing coupler 1 includes a first collimator lens 118a, a second collimator lens 118b, a third collimator lens 118c, a parallelogram prism 119, an optical filter 120, and a right angle prism 121. The wavelength multiplexing coupler 5 is provided with a fiber-type optical coupler 161, whereas the movable base 122 is provided. The fiber type optical coupler 161 is installed on the housing 106 of the wavelength division multiplexing coupler 5. The fiber type optical coupler 161 is an optical coupler having wavelength selectivity.

  In the wavelength multiplexing coupler 5, the optical signal having the wavelength λ1 is input to the first optical fiber 113a. The optical signal of λ1 emitted from the first optical fiber 113a is input to the fiber type optical coupler 161. The optical signal having the wavelength λ1 output from the fiber-type optical coupler 161 is input to the third optical fiber 113c. The third optical fiber 113c outputs an optical signal having a wavelength λ1 to a transmission line optical fiber (not shown).

  In the wavelength multiplexing coupler 5, the optical signal having the wavelength λ2 input from the transmission line optical fiber (not shown) through the plug 300 is input to the third optical fiber 113c. An optical signal having a wavelength λ2 is input from the third optical fiber 113c to the fiber type optical coupler 161. The fiber type optical coupler 161 has wavelength selectivity. The optical signal of wavelength λ2 input to the fiber type optical coupler 161 is output to the second optical fiber 113b by causing mode coupling in the fiber type optical coupler.

  As described above, the fifth embodiment according to the present invention uses the fiber-type optical coupler 161 having wavelength selectivity, so that it is not necessary to use a collimator lens. For this reason, it becomes possible to realize a wavelength multiplexing coupler with excellent mass productivity.

  The wavelength division multiplexing coupler according to the present invention connects an optical communication device including two receptacles in series with an optical fiber including a plug, and combines and demultiplexes two optical signals having different wavelengths handled by the optical communication device. And is useful as an optical component for bidirectional optical communication.

1 is a perspective view of a wavelength multiplexing coupler 1 according to a first embodiment of the present invention. Cross-sectional view of wavelength multiplexing coupler 1 Wavelength multiplexing coupler 1 connection diagram Cross-sectional view of dual receptacle type optical transceiver Cross section of plug type connector Sectional drawing of the state where the wavelength division multiplexing coupler 1 is connected to the receptacle type optical transceiver and the plug type connector Diagram showing positioning pin attachment / detachment Diagram explaining the function of the positioning pin Sectional drawing of the wavelength division multiplexing coupler 2 which concerns on the 2nd Embodiment of this invention Sectional drawing of the wavelength division multiplexing coupler 2 which concerns on the 2nd Embodiment of this invention Sectional view of wavelength division multiplexing coupler 3 Sectional drawing of the wavelength division multiplexing coupler 3 which concerns on the 3rd Embodiment of this invention. Sectional view of wavelength multiplexing coupler 4 Sectional view of the state where the wavelength multiplexing coupler 4 is connected to the receptacle type optical transceiver and the plug type connector Sectional drawing of the wavelength division multiplexing coupler 5 which concerns on the 5th Embodiment of this invention The figure which shows the structure of the system to which the conventional wavelength division multiplexing coupler is applied Optical wrap connector configuration diagram

Explanation of symbols

1, 2, 3, 4, 5, 1a, 1b, 1c, 1d Wavelength multiplexing coupler 101, 106 Case 102, 103 Plug part 104 Receptacle part 105 Optical multiplexing / demultiplexing part storage part 111 Positioning pin 112, 301 Ferrule 113, 302 , 310, 320, 330 Optical fiber 114, 303 Spring 115 Dovetail 117 Indentation 118, 151 Collimator lens 119 Parallelogram prism 120 Optical filter 121 Right angle prism 122 Movable base 123, 142, 143 Compression spring 124 Split sleeve 131 Integrated Parallelogram prism 132 Integrated right-angle prism 141 Optical waveguide 161 Fiber type optical coupler 200, 210, 220 Optical transceiver 201, 211, 221 Light emitting element 202, 212, 222 Light receiving element 204a, 204b Positioning slit 205a 205b position regulating portion 300,311,312,321,322,331,332 plug 304 optical fiber jacket

Claims (26)

An optical communication apparatus comprising two receptacles for accommodating parts that handle first and second optical signals having different wavelengths, and a single-core optical fiber that connects a plug that can be fitted to the receptacle to one end. A wavelength multiplexing coupler for coupling,
An optical multiplexing / demultiplexing unit for multiplexing / demultiplexing the first and second optical signals;
In the optical multiplexer / demultiplexer, a first transmission unit disposed on a first input / output side for inputting / outputting the first and second optical signals to / from different locations, and transmitting the first optical signal When,
A second transmission unit disposed on the first input / output side for transmitting the second optical signal;
The optical multiplexer / demultiplexer is disposed on a second input / output side for inputting / outputting the first and second optical signals to a common location, and transmits a first optical signal and a second optical signal. A transmission section of
A housing for incorporating the optical multiplexing / demultiplexing unit, the first transmission unit, the second transmission unit, and the third transmission unit;
The housing is
An optical multiplexing / demultiplexing part accommodating part for accommodating the optical multiplexing / demultiplexing part,
A first plug portion that can be fitted into one of the receptacles of the optical communication device and holds the first transmission portion;
A second plug portion that can be fitted into the other receptacle of the optical communication device and holds the second transmission portion;
A wavelength multiplexing coupler that can be fitted into the plug of the single-core optical fiber and includes a receptacle for holding the third transmission unit. further,
An optical multiplexing / demultiplexing unit holding unit that is movable between the first input / output side and the second input / output side, and holds the optical multiplexing / demultiplexing unit;
A first elastic body for pressing the first transmission section toward the first input / output side;
A second elastic body for pressing the second transmission portion toward the first input / output side;
A third elastic body for pressing the optical multiplexing / demultiplexing portion holding portion toward the first input / output side,
The force with which the third elastic body presses the optical multiplexing / demultiplexing portion holding portion toward the first input / output side is such that the first elastic body brings the first transmission portion toward the first input / output side. 2. The wavelength division multiplexing according to claim 1, wherein the sum of a pressing force and a force by which the second elastic body presses the second transmission unit toward the first input / output side is greater than the sum of the pressing force and the second multiplexing unit. Coupler. The first elastic body is a spring;
The second elastic body is a spring;
The wavelength multiplexing coupler according to claim 2, wherein the third elastic body is a spring. The plug of the one-core optical fiber includes a first optical fiber for transmitting the first and second optical signals, a first ferrule for holding the first optical fiber, A fourth elastic body for pressing the first ferrule,
The first transmission unit includes:
A second optical fiber for transmitting the first optical signal;
A second ferrule for holding the first optical fiber therein,
The second transmission unit includes:
A third optical fiber for transmitting the second optical signal;
A third ferrule for holding the second optical fiber therein,
The third transmission unit includes:
A fourth optical fiber for transmitting the first and second optical signals;
A fourth ferrule that holds the fourth optical fiber therein,
The fourth elastic body presses the fourth ferrule toward the second input / output side when the plug of the one-core optical fiber and the receptacle portion are fitted to each other. The wavelength division multiplexing coupler according to claim 3. The optical multiplexing / demultiplexing unit is
The first optical signal disposed on the optical axis of the first optical fiber, the first input / output side end face of the optical multiplexing / demultiplexing unit holding part being a focal point, and being output from the first optical fiber A first collimator lens for converting the light into collimator light;
The second optical signal that is arranged on the optical axis of the second optical fiber, the end face on the first input / output side of the optical multiplexing / demultiplexing unit holding part is a focal point, and is output from the second optical fiber A second collimator lens that converts the light into collimator light;
The first and second optical fibers are arranged on the optical axis of the third optical fiber, the end face on the second input / output side of the optical multiplexing / demultiplexing unit holding part is a focal point, and the first and the second output from the third optical fiber A third collimator lens that converts the optical signal of 2 into collimator light;
An optical filter that reflects the first optical signal and transmits the second optical signal;
A right angle prism in which the optical filter is disposed on a first inclined surface;
A parallelogram prism having second and third inclined surfaces, wherein the first inclined surface of the right-angle prism and the second inclined surface are in contact with each other through the optical filter;
The parallelogram prism reflects the first optical signal on the second and third inclined surfaces, so that the first transmission unit and the third transmission unit transmit the first transmission signal between the first transmission unit and the third transmission unit. The optical signal of
The parallelogram prism and the right-angle prism transmit the second optical signal between the first transmission unit and the third transmission unit on the first and second inclined surfaces. The wavelength division multiplexing coupler according to claim 4, wherein the second optical signal is transmitted through the wavelength multiplexing coupler.   The first collimator lens, the third collimator lens, and the parallelogram prism are integrally molded, and the second collimator lens and the right-angle prism are integrally molded. The wavelength division multiplexing coupler according to claim 5.   In the optical multiplexing / demultiplexing unit, the first optical signal is guided between the first transmission unit and the third transmission unit, and the second transmission unit and the third transmission unit 5. The wavelength division multiplex coupler according to claim 4, wherein the second optical signal is an optical waveguide. further,
A first elastic body for pressing the first transmission section in a direction opposite to the first input / output side;
A second elastic body for pressing the second transmission portion in the direction opposite to the first input / output side;
The wavelength division multiplexing coupler according to claim 1, further comprising a third elastic body for pressing the third transmission unit in a direction opposite to the second input / output side. The first elastic body is a spring;
The second elastic body is a spring;
The wavelength multiplexing coupler according to claim 8, wherein the third elastic body is a spring. The first transmission unit includes:
A first optical fiber for transmitting the first optical signal;
A first ferrule for holding the first optical fiber therein,
The second transmission unit includes:
A second optical fiber for transmitting the second optical signal;
A third ferrule for holding the second optical fiber therein,
The third transmission unit includes:
A third optical fiber for transmitting the first and second optical signals;
The wavelength division multiplexing coupler according to claim 9, further comprising a third ferrule that holds the fourth optical fiber therein. The optical multiplexing / demultiplexing unit is
A first collimator lens disposed on an end face of the first optical fiber on the first input / output side and converting the first optical signal output from the first optical fiber into collimator light;
A second collimator lens that is disposed on the first input / output end face of the second optical fiber and converts the second optical signal output from the second optical fiber into collimator light;
A third collimator lens disposed on an end face of the third optical fiber on the second input / output side, which converts the first and second optical signals output from the third optical fiber into collimator light. When,
An optical filter that reflects the first optical signal and transmits the second optical signal;
A right angle prism in which the optical filter is disposed on a first inclined surface;
A parallelogram prism having second and third inclined surfaces, wherein the first inclined surface of the right-angle prism and the second inclined surface are in contact with each other through the optical filter;
The parallelogram prism reflects the first optical signal on the second and third inclined surfaces, so that the first transmission unit and the third transmission unit transmit the first transmission signal between the first transmission unit and the third transmission unit. The optical signal of
The parallelogram prism and the right-angle prism transmit the second optical signal between the first transmission unit and the third transmission unit on the first and second inclined surfaces. The wavelength division multiplexing coupler according to claim 11, wherein the second optical signal is transmitted through the wavelength multiplexing coupler.   The wavelength division multiplexing coupler according to claim 8, wherein the first optical fiber, the second optical fiber, and the third optical fiber are TEC (Thermal Expanded Core) fibers.   The optical multiplexing / demultiplexing unit includes an optical fiber for transmitting the first optical signal between the first transmission unit and the third transmission unit, the second transmission unit, and the third transmission unit. The wavelength division multiplexing coupler according to claim 11, wherein the wavelength division multiplexing coupler is a fiber type optical coupler including an optical fiber for transmitting the second optical signal to and from a transmission unit. The two receptacles provided in the optical communication device include attachment direction limiting means for restricting the attachment direction of the first and second plug parts to be mated,
The first and second plug parts include attachment direction guiding means for guiding the first and second plug parts in an attachment direction restricted by the attachment direction restriction means,
2. The wavelength division multiplexing according to claim 1, wherein the mounting direction guiding unit can guide the mounting direction restricted by the mounting direction limiting unit by inverting the first and second plug portions. Coupler. The attachment direction limiting means is a first and a second slit provided in common on one side of the two receptacles,
The mounting direction guiding means is
Removable first and second positioning pins for guiding the first and second plug portions into the first and second slits,
Both are provided on the same surface, and first and second grooves for attaching and detaching the first and second positioning pins;
It is provided on the surface opposite to the surface on which the first and second grooves are provided, and includes third and fourth grooves for attaching and detaching the first and second positioning pins. The wavelength division multiplexing coupler according to claim 14, wherein: The optical multiplexing / demultiplexing unit is
A first collimator lens disposed on the optical axis of the first transmission unit and converting the first optical signal output from the first transmission unit into collimator light;
A second collimator lens that is disposed on the optical axis of the second transmission unit and converts the second optical signal output from the second transmission unit into collimator light;
A third collimator lens that is disposed on the optical axis of the third transmission unit and converts the first and second optical signals output from the third transmission unit into collimator light;
An optical filter that reflects the first optical signal and reflects the second optical signal;
A right angle prism in which the optical filter is disposed on a first inclined surface;
A parallelogram prism having second and third inclined surfaces, wherein the first inclined surface of the right-angle prism and the second inclined surface are in contact with each other through the optical filter;
The parallelogram prism reflects the first optical signal on the second and third inclined surfaces, so that the first transmission unit and the third transmission unit transmit the first transmission signal between the first transmission unit and the third transmission unit. The optical signal of
The parallelogram prism and the right-angle prism transmit the second optical signal between the first transmission unit and the third transmission unit on the first and second inclined surfaces. The wavelength division multiplexing coupler according to claim 1, wherein the second optical signal is transmitted through the wavelength division coupler.   The first collimator lens and the third collimator lens are disposed in contact with the parallelogram prism, and the second collimator lens is disposed in contact with the right-angle prism. Item 17. A wavelength division multiplexing coupler according to Item 16.   The first collimator lens, the third collimator lens, and the parallelogram prism are integrally molded, and the second collimator lens and the right-angle prism are integrally molded. The wavelength division multiplexing coupler according to claim 17. The first collimator lens is disposed on the first input / output side of the first transmission unit,
The second collimator lens is disposed on the first input / output side of the second transmission unit,
The wavelength division multiplexing coupler according to claim 16, wherein the third collimator lens is disposed on the second input / output side of the third transmission unit.   The wavelength division multiplexing coupler according to claim 19, wherein the first transmission unit, the second transmission unit, and the third transmission unit are TEC (Thermal Expanded Core) fibers.   In the optical multiplexing / demultiplexing unit, the first optical signal is guided between the first transmission unit and the third transmission unit, and the second transmission unit and the third transmission unit 2. The wavelength division multiplexing coupler according to claim 1, wherein the second optical signal is an optical waveguide between which the optical signal is guided.   The optical multiplexing / demultiplexing unit includes an optical fiber for transmitting the first optical signal between the first transmission unit and the third transmission unit, the second transmission unit, and the third transmission unit. 2. The wavelength division multiplexing coupler according to claim 1, wherein the wavelength division multiplexing coupler is a fiber-type optical coupler including an optical fiber for transmitting the second optical signal to and from a transmission unit. The optical communication device includes a light emitting unit for emitting the first optical signal and a light receiving unit for receiving the second optical signal as components for handling the first and second optical signals. Prepared,
The one receptacle of the optical communication device accommodates the light emitting unit,
The other receptacle of the optical communication device accommodates the light receiving unit,
The first plug portion is fitted with the one receptacle for coupling the first optical signal emitted from the light emitting portion to the first transmission portion,
The said 2nd plug part is fitted with said other receptacle in order to make the said 2nd optical signal which transmits the said 2nd transmission part enter into the said light-receiving part, The said 1st receptacle is characterized by the above-mentioned. The wavelength division multiplexing coupler described in 1. The optical communication device includes a light receiving unit for receiving the first optical signal and a light emitting unit for emitting the second optical signal as components for handling the first and second optical signals. Prepared,
One of the receptacles of the optical communication device accommodates the light receiving unit,
The other receptacle of the optical communication device accommodates the light emitting unit,
The first plug portion is fitted with the one receptacle for causing the first optical signal transmitted through the first transmission portion to enter the light receiving portion,
The said 2nd plug part is fitted with said other receptacle in order to couple | bond the said 2nd optical signal which the said light emission part light-emits with a said 2nd transmission part, The 1st characterized by the above-mentioned. The wavelength division multiplexing coupler described in 1. The optical communication device includes a first light emitting unit for emitting the first optical signal and a first light emitting unit for emitting the second optical signal as components for handling the first and second optical signals. Two light emitting units,
The one receptacle of the optical communication device accommodates the first light emitting unit,
The other receptacle of the optical communication device accommodates the second light emitting unit,
The first plug part is fitted with the one receptacle for coupling the first optical signal emitted from the first light emitting part to the first transmission part,
The second plug part is fitted with the other receptacle for coupling the second optical signal emitted from the second light emitting part to the second transmission part, The wavelength division multiplexing coupler according to claim 1. The optical communication device includes a first light receiving unit for receiving the first optical signal and a first light receiving unit for receiving the second optical signal as components for handling the first and second optical signals. Two light receiving parts,
The one receptacle of the optical communication apparatus accommodates the first light receiving unit,
The other receptacle of the optical communication device accommodates the second light receiving unit.
The first plug portion is fitted with the one receptacle so that the first optical signal transmitted through the first transmission portion is incident on the first light receiving portion,
The second plug part is fitted with the one receptacle so that the second optical signal transmitted through the second transmission part is incident on the second light receiving part. The wavelength division multiplexing coupler according to claim 1.

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