KR101473651B1 - Coarse wavelength division multiplexing optical subassembly moudle and manufacturing method therof - Google Patents

Abstract

The present invention relates to a multi-wavelength optical subassembly module, and more particularly, to a multi-wavelength optical subassembly module that includes a housing part connected to an optical cable, a plurality of optical filter parts coupled to the housing part and guiding an optical signal, A plurality of transmission / reception units for receiving or transmitting optical signals to the optical filter unit, and a substrate unit to which the transmission / reception units are respectively coupled, thereby suppressing optical signal distortion and reducing the product defect rate through reliability evaluation.

Description

[0001] COARSE WAVELENGTH DIVISION MULTIPLEXING OPTICAL SUBASSEMBLY MOUDLE AND MANUFACTURING METHOD THEROF [0002]

The present invention relates to a multi-wavelength optical sub-assembly module, and more particularly, to a multi-wavelength optical sub-assembly module that can be replaced when a partial defect occurs, reliability evaluation can be performed for each device, and overheating is prevented.

Generally, an optical transmission / reception module is a module that is applied to an optical transmission system, and transmits an optical signal emitted from a light emitting device through an optical fiber and detects an optical signal received from the optical fiber as a light receiving element.

The optical transmission / reception module basically comprises a light emitting element and a light receiving element packaged in a TO-CAN form, a printed circuit board for driving the light emitting element and receiving a detection signal of the light receiving element, A case in which the circuit board is mounted, and a pin connector for electrical signal connection.

Each of the light emitting element and the light receiving element is formed inside a receptacle type optical subassembly which is easy to handle as an optical interface with an optical path, and is packaged in a metal-made thio-can (TO-CAN).

The plurality of fins connected to the optical sub-assembly are connected to the anode and the cathode of the laser diode or the photodiode, respectively, which are formed in the light-emitting element and the light-receiving element.

The optical fiber can simultaneously transmit optical signals having different wavelengths, and the multi-wavelength optical subassembly module transmits and receives a plurality of optical signals having different wavelengths through one optical fiber.

On the other hand, the background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 2012-0030265 (published on March 28, 2012, entitled Wavelength Division Multiplexing and Demultiplexing Apparatus).

In the conventional multi-wavelength optical sub-assembly module, a plurality of chips are mounted on a single substrate and they are simultaneously aligned through the lens array, which makes optical alignment difficult and requires a long optical alignment time.

In addition, since the conventional multi-wavelength optical subassembly module has a plurality of chips mounted on a single substrate, the conventional multi-wavelength optical subassembly module causes a product failure due to overheating.

Meanwhile, in the conventional multi-wavelength optical sub-assembly module, if any one of a plurality of chips is defective, the entire product must be discarded.

In addition, reliability evaluation of individual optical devices is not possible, so that there is a problem in that it is not possible to perform a process of filtering out samples with poor reliability at the time of product production.

Therefore, there is a need to improve this.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a method of manufacturing a semiconductor device, in which a defective substrate can be replaced only during a manufacturing process, And to provide a multi-wavelength optical subassembly module for suppressing overheating by dispersing a substrate.

According to an aspect of the present invention, a multi-wavelength optical sub-assembly module includes: a housing part connected to an optical cable; A plurality of optical filter parts coupled to the housing part and guiding an optical signal; A plurality of transceivers coupled to the housing and receiving optical signals through the optical filter and transmitting optical signals to the optical filter; And a substrate unit to which the transmitting and receiving unit is respectively coupled.

The housing portion includes a body portion; A plurality of filter mounting portions formed on the body portion and to which the optical filter unit is mounted; And a lens unit formed on the body unit and adapted to align optical signals transmitted and received through the optical cable.

And the filter mounting part is bonded to an edge of the optical filter part so as not to interfere with the optical signal.

Wherein the optical filter unit includes a transmission lens guiding unit disposed in a straight line with the lens unit and passing an optical signal of a predetermined wavelength or longer and guiding the optical signal of less than a predetermined wavelength to the lens unit; A transmission light reflection part disposed to face the transmission lens guiding part and reflecting the optical signal and guiding the optical signal to the transmission lens guiding part; A transmission long wavelength guiding unit disposed in a straight line with the transmission lens guiding unit and guiding the optical signal generated by the transmission and reception unit to the transmission lens guiding unit; A transmission reception guide unit disposed in a straight line with the transmission lens guide unit and guiding an optical signal having passed through the transmission long wavelength guide unit to the transmission / reception unit; And a transmission short wavelength guiding unit disposed in a straight line with the transmission light reflection unit and guiding the optical signal generated by the transmission and reception unit to the transmission light reflection unit.

Wherein the transmission short wavelength guiding part comprises three optical waveguides and reflects an optical signal having a shorter wavelength as it is farther from the transmission light reflection part, the transmission long waveguide guiding part is composed of two pieces, And reflects an optical signal having a longer wavelength.

Wherein the transceiver comprises: a plurality of transmission optical transmission units for generating optical signals and transmitting optical signals to the short wavelength guide for transmission and the long wavelength guide for transmission, respectively; And a transmission light reception unit for receiving the optical signal reflected by the transmission reception guide unit.

Wherein the optical filter unit comprises: a reception lens guiding unit disposed in a straight line with the lens unit, for passing an optical signal of a predetermined wavelength or longer and reflecting an optical signal having a wavelength shorter than a predetermined wavelength; A receiving light reflecting unit arranged to face the receiving lens guiding unit and guiding the optical signal reflected by the receiving lens guiding unit; A receiving long wavelength guide arranged in line with the receiving lens guiding unit and guiding an optical signal passed through the receiving lens guiding unit to the transmitting and receiving unit; A receiving and transmitting guide unit disposed in a straight line with the receiving lens guide unit and guiding the optical signal generated by the transmitting and receiving unit to the receiving lens guide unit; And a receiving short wavelength guiding unit disposed in a straight line with the receiving light reflecting unit and guiding the optical signal reflected by the receiving light reflecting unit to the transmitting and receiving unit.

Wherein the receiving short wavelength guiding part reflects an optical signal having a shorter wavelength as the farther from the receiving light reflecting part, and the receiving long waveguide guiding part is composed of two pieces and the distance from the receiving lens guiding part And reflects an optical signal having a longer wavelength.

Wherein the transmission / reception unit comprises: a reception optical transmitter for generating an optical signal and transmitting the optical signal to the reception / reception guide unit; And a plurality of reception light reception units for receiving the optical signals respectively reflected by the reception short wavelength guide unit and the reception long wavelength wave guide unit.

The multi-wavelength optical subassembly module according to one aspect of the present invention further includes a light aligner coupled to the housing and disposed between the optical filter and the transceiver to align optical signals.

Wherein the light aligning portion includes: a light aligning body coupled to the housing portion; An optical alignment lens formed on the optical alignment body and aligning optical signals passing between the optical filter unit and the transceiver unit; And a photo-alignment coupling band formed on the photo-alignment body and to which the transmission and reception unit is coupled.

Wherein the transceiver includes a rigid substrate coupled to the photo alignment coupler; A flexible substrate portion coupled to the rigid substrate portion and connected to the substrate portion; And an optical device mounted on the flexible substrate and transmitting and receiving an optical signal.

And the transceiver is fabricated from a plurality of integrated matrix type boards.

The multi-wavelength optical subassembly module according to an aspect of the present invention further includes a sorting filter unit disposed between the optical filter unit and the transceiver unit and transmitting only an optical signal having a selected wavelength.

The multi-wavelength optical subassembly module according to the present invention has an effect that a plurality of transmitting and receiving units transmit and receive optical signals of different wavelength ranges, thereby smoothly transmitting optical signals in a single cable.

The multi-wavelength optical subassembly module according to the present invention has the effect of replacing and using only defective parts when individual defects occur, since a plurality of transmission / reception parts are separately mounted.

The multi-wavelength optical subassembly module according to the present invention is capable of evaluating the reliability of the optical element, thereby improving the reliability of the product.

In the multi-wavelength optical sub-assembly module according to the present invention, since the plurality of transmitting and receiving sections are separately mounted, concentration of components between the components is mitigated to prevent overheating.

The multi-wavelength optical subassembly module according to the present invention has the effect of suppressing optical signal distortion by dual alignment of optical signals by the optical alignment unit and the lens unit.

The multi-wavelength optical subassembly module according to the present invention has an effect of preventing interference of optical signals having different wavelength regions by disposing a sorting filter unit between the transmitting and receiving unit and the optical filter unit.

The multi-wavelength optical sub-assembly module according to the present invention can be mass-produced in a production line in a transmission / reception section, thereby improving productivity.

1 is a perspective view schematically showing a multi-wavelength optical subassembly module according to an embodiment of the present invention.
2 is a plan view schematically illustrating a multi-wavelength optical subassembly module according to an embodiment of the present invention.
3 is a side view schematically illustrating a multi-wavelength optical subassembly module according to an embodiment of the present invention.
4 is a perspective view schematically showing a housing part in a multi-wavelength optical subassembly module according to an embodiment of the present invention.
5 is a schematic view of a light alignment unit in a multi-wavelength optical subassembly module according to an embodiment of the present invention.
6 is a view schematically showing an arrangement state of an optical filter unit for optical transmission in a multi-wavelength optical subassembly module according to an embodiment of the present invention.
7 is a view schematically showing an arrangement state of an optical filter unit for receiving light in a multi-wavelength optical subassembly module according to an embodiment of the present invention.
8 is an exploded perspective view schematically illustrating a state in which the transmitting and receiving unit is aligned in the multi-wavelength optical subassembly module according to an embodiment of the present invention.
9 is an assembled perspective view schematically showing a state in which a transmitting and receiving section is aligned in a multi-wavelength optical subassembly module according to an embodiment of the present invention.
10 is a view schematically showing a state in which an optical device is mounted on a transceiver in a multi-wavelength optical subassembly module according to an embodiment of the present invention.
11 is a view schematically showing a state where an optical element mounted on a transceiver unit is wire-bonded in a multi-wavelength optical subassembly module according to an embodiment of the present invention.
12 is a view schematically showing a state where an optical element mounted on a transceiver unit is covered by an epoxy in a multi-wavelength optical subassembly module according to an embodiment of the present invention.

Hereinafter, embodiments of a multi-wavelength optical sub-assembly module according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a perspective view schematically showing a multi-wavelength optical sub-assembly module according to an embodiment of the present invention, FIG. 2 is a plan view schematically showing a multi-wavelength optical sub-assembly module according to an embodiment of the present invention, Is a side view schematically illustrating a multi-wavelength optical subassembly module according to an embodiment of the present invention.

FIG. 4 is a perspective view schematically showing a housing part in a multi-wavelength optical subassembly module according to an embodiment of the present invention, FIG. 5 is a schematic view of a multi-wavelength optical subassembly module according to an embodiment of the present invention, 6 is a view schematically showing an arrangement state of an optical filter unit for optical transmission in a multi-wavelength optical subassembly module according to an embodiment of the present invention. FIG. 7 is a cross- And schematically showing the arrangement state of the optical filter unit for light reception in the optical subassembly module.

FIG. 8 is an exploded perspective view schematically illustrating a state in which a transmitting and receiving unit is aligned in a multi-wavelength optical subassembly module according to an embodiment of the present invention. FIG. 9 is a cross- Is schematically shown as a combined perspective view.

FIG. 10 is a schematic view of a multi-wavelength optical subassembly module according to an exemplary embodiment of the present invention, in which optical elements are mounted on a transmission / reception unit, FIG. 11 is a cross- FIG. 12 is a view schematically showing a state in which an optical element mounted on a transmission / reception section is wire-bonded to a transmission / reception section in a multi-wavelength optical subassembly module according to an embodiment of the present invention. Fig.

1 to 3, a multi-wavelength optical sub-assembly module 1 according to an embodiment of the present invention includes a housing unit 10, an optical filter unit 20, a transceiver unit 30, and a substrate unit 40 .

The housing part 10 is connected to the optical cable 100 and the optical filter part 20 is coupled to the housing part 10 to guide the optical signal.

The transceiver unit 30 is coupled to the housing unit 10 to transmit and receive optical signals. The transmission / reception unit 30 is composed of a plurality of units.

The transceiver 30 receives the optical signal reflected through the optical filter 20. The transceiver unit 30 transmits the optical signal to the optical filter unit 20, and the optical filter unit 20 reflects the optical signal in the set direction.

For example, when a multi-wavelength optical sub-assembly module 1 is connected to a computer, a video signal, a voice signal, and a control signal are transmitted and a status signal of the monitor is received.

When the multi-wavelength optical subassembly module 1 is connected to the monitor, the video signal, the audio signal, and the control signal are received, and the status signal of the monitor is transmitted to the computer.

The transmitting and receiving unit 30 is made up of a plurality of optical signals having different wavelength bands so that they can be transmitted and received individually.

A plurality of transmission / reception units 30 are coupled to the substrate unit 40, respectively. The substrate portion 40 includes a substrate having a hard material and a substrate having a soft material, and circuits and elements for controlling the respective transceiver portions 30 are formed.

Referring to FIGS. 1 to 4, a housing part 10 according to an embodiment of the present invention includes a body part 11, a filter mounting part 12, and a lens part 13. The housing part 10 includes a plastic material and is integrally molded.

For example, the body part 11 is provided with a side plate part 112 extending downward from one end of the upper plate part 111 and the upper plate part 111. The body portion 11 is provided with a side wall portion 113 extending downward from the side end portion of the upper plate portion 111.

The body part 11 forms a skeleton of the housing part 10 and the filter mounting part 12 is formed in the body part 11. [ The filter mounting portion 12 has a number corresponding to that of the optical filter portion 20 so that a plurality of optical filter portions 20 are mounted.

The filter mounting portion 12 supports the optical filter portion 20 and has a shape or material that does not cause interference with the optical signal.

For example, the filter mounting portion 12 is protruded from the bottom surface of the top plate 111, and the edge of one optical filter portion 20 is coupled to the filter mounting portion 12.

In addition, the filter mounting portion 12 protrudes from the bottom surface of the upper plate 111 and has an open center so that the optical signal is passed therethrough.

On the other hand, the optical filter unit 20 is disposed above the transmission / reception unit 30 and guides the optical signal of the set wavelength band. At this time, the filter mounting part 12 on which the optical filter part 20 is mounted may have a triangular cross-section for optical signal reflection.

The lens unit 13 is formed on the body part 11 and aligns the optical signals transmitted and received through the optical cable 100.

For example, the lens section 13 is formed inside the side plate section 112 and is formed outside the lens body 131 and the side plate section 112 for aligning the optical signals, and is connected to the optical cable 100 132 are provided.

At this time, the optical signal aligned by the lens body 131 or the optical signal guided through the optical cable 100 passes through the side plate hole 113 formed in the side plate portion 112.

2, 3 and 6, the optical filter unit 20 according to an embodiment of the present invention is provided with a transmitting lens guiding unit 51, a transmitting light reflecting unit 52, a transmitting long wavelength guiding unit 53, a transmission reception guide unit 54, and a transmission short wavelength guide unit 55 are provided. The multi-wavelength optical subassembly module 1 including the optical filter unit 20 may be connected to a computer that transmits optical signals.

The transmitting lens guiding portion 51 is disposed on a straight line with the lens portion 13. The transmitting lens guiding unit 51 passes an optical signal having a wavelength equal to or higher than a predetermined wavelength, and reflects an optical signal having a wavelength less than a predetermined wavelength to guide the lens unit 13.

The transmitting light reflecting portion 52 is arranged to face the transmitting lens guiding portion 51, and reflects the optical signal to guide it to the transmitting lens guiding portion 51. Since the transmitting light reflection part 52 does not require transmission of an optical signal for each wavelength, it can be replaced with a mirror for reflecting the optical signal itself.

The transmission long wavelength guiding section 53 is disposed on a straight line with the transmission lens guiding section 51. The transmission long wavelength guide 53 directs the optical signal generated by the transmission / reception unit 30 to the transmission lens guiding unit 51.

The transmission and reception guide unit 54 is disposed on a straight line with the transmission lens guide unit 51 and guides the optical signal that has passed through the transmission long wavelength guide unit 53 to the transmission and reception unit 30.

The short wavelength guide for transmission 55 directs the optical signal generated by the transmission / reception section 30 to the transmission light reflection section 52, which is disposed on a straight line with the transmission light reflection section 52.

The transmission short wavelength guiding section 55 is made up of three and reflects an optical signal having a shorter wavelength as the distance from the transmission light reflection section 52 increases.

For example, the farther from the transmission light reflection part 52, the shorter the first transmission end reflector 551, the second transmission end reflector 552, and the third transmission end 552, A reflector 553 is disposed.

The first transmission single reflector 551 reflects an optical signal having a wavelength of 870 nm and guides it to the transmission light reflection portion 52.

The second transmission single reflector 552 reflects an optical signal having a wavelength of 825 nm and guides it to the transmission light reflection portion 52. At this time, the optical signal having the wavelength of 825 nm passes through the first transmitting short reflector 551.

The third transmission single reflector 553 reflects an optical signal having a wavelength of 780 nm and guides it to the transmission light reflection portion 52. At this time, the optical signal having the wavelength of 780 nm sequentially passes through the second transmission single reflector 552 and the first transmission single reflector 551.

Since the third transmission single stage reflector 553 does not require transmission of an optical signal for each wavelength, it can be replaced with a mirror for reflecting the optical signal itself.

The transmission long wavelength guiding section 53 is made up of two and reflects an optical signal having a longer wavelength as the distance from the transmitting lens guiding section 51 increases.

For example, the first transmission line reflector 531 and the second transmission line reflector 532 are sequentially arranged in the transmission long wavelength guide 53 as the distance from the transmission lens guide 51 increases.

The first transmission reflector 531 reflects an optical signal having a wavelength of 915 nm and guides it to the transmission lens guiding portion 51.

The second transmission line reflector 532 reflects an optical signal having a wavelength of 960 nm and guides it to the transmission lens guiding portion 51. At this time, the optical signal having the wavelength of 960 nm passes through the first transmission line reflector 531.

On the other hand, a transmission long wavelength guiding section 53 is disposed between the transmission / reception guide section 54 and the transmission lens guiding section 51.

For example, the first transmission transmission reflector 531, the second transmission transmission reflector 532, and the transmission reception guide section 54 are sequentially arranged.

The transmission / reception section 54 reflects an optical signal having a wavelength of 1005 nm and guides it to the transmission / reception section 30. At this time, an optical signal having a wavelength of 1005 nm passes through the first transmission line reflector 531 and the second transmission line reflector 532.

Since the transmission and reception guide unit 54 does not need to transmit an optical signal for each wavelength, it can be replaced with a mirror that reflects the optical signal itself.

The transmission / reception unit 30 is provided with a transmission light transmission unit 31 and a transmission light reception unit 32.

The transmitting optical transmitter 31 is disposed below each of the short wavelength guide for transmission 55 and the long wavelength guide for transmission 53, and generates optical signals of different wavelength bands. The transmission light reception section 32 is disposed below the transmission reception guide section 54.

For example, the transmission light transmitting section 31 disposed below the first transmission single reflector 551 generates an optical signal having a wavelength of 870 nm, and transmits the light, which is disposed below the second transmission single reflector 552, The optical transmitting unit 31 generates an optical signal having a wavelength of 825 nm and the transmitting optical transmitting unit 31 disposed below the third transmitting single reflector 553 generates an optical signal having a wavelength of 780 nm.

The transmission light transmitter 31 disposed below the first transmission receiver reflector 531 generates an optical signal having a wavelength of 915 nm and a transmission light transmitter 31 ) Generates an optical signal having a wavelength of 960 nm.

On the other hand, the transmission light reception unit 32 disposed below the transmission reception guide unit 54 receives an optical signal having a wavelength of 1005 nm.

2, 3 and 7, the optical filter unit 20 according to an embodiment of the present invention includes a reception lens guide 61, a reception light reflection unit 62, a reception long wavelength guide 63, a reception transmission guide section 64, and a reception short wavelength guide section 65. The multi-wavelength optical subassembly module 1 including the optical filter unit 20 may be connected to a monitor for receiving an optical signal.

The receiving lens guide portion 61 is disposed on a straight line with the lens portion 13. The receiving lens guiding unit 61 passes an optical signal of a set wavelength or more, reflects an optical signal of a wavelength shorter than the set wavelength, and guides the optical signal to the receiving light reflecting unit 62.

The receiving light reflecting portion 62 is arranged to face the receiving lens guiding portion 61 and reflects the optical signal guided by the receiving lens guiding portion 61 and guides it to the receiving short wavelength guiding portion 65.

Since the light-receiving reflector 62 does not need to transmit an optical signal for each wavelength, it can be replaced with a mirror that reflects the optical signal itself.

The receiving long wavelength guiding portion 63 is disposed on a straight line with the receiving lens guiding portion 61. The receiving long wavelength guiding unit 63 guides the optical signal passing through the receiving lens guiding unit 61 to the transmitting and receiving unit 30.

The reception and transmission guide unit 64 is disposed on a straight line with the reception lens guide unit 61 and guides the optical signal generated by the transmission and reception unit 30 to the reception lens guide unit 61. At this time, the optical signal reflected by the reception and transmission guide unit 64 passes through the reception long wavelength guide unit 63 and reaches the reception lens guide unit 61.

The receiving short waveguide guiding portion 65 guides the optical signal reflected by the receiving light reflecting portion 62 to the transmitting / receiving portion 30, which is disposed on the straight line with the receiving light reflecting portion 62.

The receiving short waveguide guiding portion 65 is composed of three optical waveguides and reflects the optical signal having a shorter wavelength as the receiving optical waveguide 62 is farther from the receiving optical waveguide 62.

For example, the farther from the receiving light reflecting portion 62, the shorter the first receiving end reflector 651, the second receiving end reflector 652, and the third receiving end A reflector 653 is disposed.

The first reception end reflector 651 reflects an optical signal having a wavelength of 870 nm and guides it to the transmission / reception unit 30. The first receiving end reflector 651 passes an optical signal having a wavelength shorter than the wavelength of 870 nm.

The second reception end reflector 652 reflects the optical signal having the wavelength of 825 nm and guides it to the transmission / reception section 30. This second receiving end reflector 652 passes an optical signal having a wavelength shorter than the wavelength of 825 nm.

The third reception end reflector 653 reflects the optical signal having the wavelength of 780 nm and guides it to the transmission / reception section 30. Since the third reception end reflector 653 does not require transmission of an optical signal per wavelength, it can be replaced with a mirror that reflects the optical signal itself.

The receiving long wavelength guiding section 63 is composed of two lenses and reflects the optical signal having a longer wavelength as the distance from the receiving lens guiding section 61 increases.

For example, the first reception receiver reflector 631 and the second reception receiver reflector 632 are disposed in sequence in the receiving long wavelength guide 63 as the receiving lens guide 61 moves away from the receiver guide 61.

The first reception reflector 631 reflects an optical signal having a wavelength of 915 nm and guides it to the transmission / reception unit 30. The first reception reflector 631 passes an optical signal having a wavelength longer than 915 nm.

The second reception reflector 632 reflects the optical signal having the wavelength of 960 nm and guides it to the transmission / reception unit 30. The second reception reflector 632 passes an optical signal having a wavelength longer than the wavelength of 960 nm.

On the other hand, a receiving long wavelength guide portion 63 is disposed between the receiving and transmitting guide portion 64 and the receiving lens guiding portion 61.

For example, the first reception hall reflector 631, the second reception hall reflector 632, and the reception transmission guide section 64 are sequentially arranged.

The reception and transmission guide unit 64 reflects the optical signal having the wavelength of 1005 nm and guides it to the reception lens guide unit 61. At this time, the optical signal having a wavelength of 1005 nm passes through the first reception reflector 631 and the second reception reflector 632.

Since the transmission and reception guide unit 64 does not need to transmit the optical signal for each wavelength, it can be replaced with a mirror that reflects the optical signal itself.

The transmission / reception section 30 is provided with a reception light transmission section 33 and a reception light reception section 34.

The reception light reception section 34 is disposed below each of the reception short waveguide guide section 65 and the reception long waveguide guide section 63 and receives optical signals of different wavelength bands.

Then, the reception optical transmission unit 33 is disposed below the reception transmission guide unit 64 to generate an optical signal.

For example, the reception light reception section 34 disposed below the first reception reception end reflector 651 receives an optical signal having a wavelength of 870 nm, The light reception section 34 receives an optical signal having a wavelength of 825 nm and the reception light reception section 34 disposed below the third reception reception end reflector 653 receives an optical signal having a wavelength of 780 nm.

The reception light reception section 34 disposed below the first reception reflector 631 receives the optical signal having the wavelength of 915 nm and the reception reception section 34 ) Receives an optical signal having a wavelength of 960 nm. On the other hand, the reception light transmitting section 33 disposed under the reception transmission guide section 64 generates an optical signal having a wavelength of 1005 nm.

Referring to FIGS. 3 and 5, the multi-wavelength optical subassembly module 1 according to the embodiment of the present invention further includes a light alignment unit 70.

The optical alignment unit 70 is coupled to the housing unit 10 and disposed between the optical filter unit 20 and the transceiver unit 30 to align the optical signals.

The optical alignment unit 70 according to an embodiment of the present invention includes a light alignment body 71, a photo alignment lens 72, and a photo alignment alignment unit 73.

The light alignment unit 70 includes a plastic material, and is integrally formed. In addition, the light alignment unit 70 can use various materials capable of transmitting optical signals.

The optical alignment body 71 is coupled to the housing portion 10. For example, the optical alignment body 71 has a plate shape parallel to the top plate 111, is manually assembled with the side plate 112 through ultraviolet curing, and then fixed through a thermal curing process.

The optical alignment lens 72 is formed in the optical alignment body 71 and aligns the optical signal passing between the optical filter unit 20 and the transceiver unit 30. [ The light-aligning lens 72 is arranged on the vertical line of each transceiver 30.

The optical alignment coupling base 73 is formed on the optical alignment body 71 and protrudes downward. The optical alignment coupler 73 is disposed between the respective photo-alignment lenses 72 and is coupled to the transmission / reception unit 30.

After the photo-alignment inspection operation is completed, the transceiver 30 is temporarily fixed to the photo-alignment coupler 73 through ultraviolet curing, and is completely fixed by the thermosetting epoxy.

3 and 8 to 12, a transceiver 30 according to an embodiment of the present invention includes a hard substrate portion 35, a flexible substrate portion 36, and an optical device portion 37.

The hard substrate portion 35 includes a hard material and is bonded to the photo alignment bonding pad 73. The flexible substrate portion 36 is coupled to the rigid substrate portion 35 and to the substrate portion 40. The optical element portion 37 is mounted on the flexible substrate portion 36 and transmits and receives an optical signal.

On the other hand, the transceiver 30 is manufactured from a plurality of integrated matrix type boards.

That is, in order to manufacture the transceiver 30 according to the embodiment of the present invention, the circuit board portion 39 having the rigid substrate portion 35 and the flexible substrate portion 36 integrally formed thereon is aligned, (See Figs. 8 and 9).

First, the substrate bundling unit 200 in which the plurality of circuit board units 39 are partitioned is seated on the seating plate 210.

At this time, the circuit board portions 39 having the same shape are arranged in rows and columns of the substrate bundling portion 200. A space for receiving the substrate bundling unit 200 is formed on the seating plate 210, and a fixing protrusion 211 protrudes upward.

After the substrate bundling section 200 is seated on the seating plate 210, the holding plate 220 is stacked on the seating plate 1. [ When the fixing plate 220 presses the substrate bundling portion 200, the flow of the substrate bundling portion 200 is limited by the load.

An opening hole 225 is formed in the fixing plate 220 so that each circuit board portion 39 is exposed to the outside so that the optical element portion 37 can be mounted on the circuit board portion 39, A fixing hole 221 for inserting the fixing plate 220 is formed.

When the substrate bundling portion 200 is disposed between the seating plate 210 and the fixing plate 220, they are moved along the process line for mounting the optical element portion 37.

In the process line for mounting the optical element portion 37, the automation device mounts the optical element portion 37 on each circuit board portion 39 and then wire-bonds the optical element portion 37 (see FIG. 11) And covers the female portion 37 (see Fig. 12).

When the optical device section 37 is mounted on each circuit board section 39 by the automatic apparatus, the substrate bundling section 200 is cut and each circuit board section 39 is separated to acquire the individual transceiver section 30 .

The hard substrate portion 35 includes a hard material that does not bend well so as to be bonded to the photo alignment bonding pad 73, and the soft substrate portion 36 includes a flexible material which is well-brittle.

At this time, the hard substrate portion 35 is mounted on the bottom surface of the soft substrate portion 36 to form one single component, and the soft substrate portion 36 and the hard substrate portion 35 can be connected to each other have.

The optical element unit 37 is divided into a light emitting element and a light receiving element, and mounted on the transceiver unit 30. The optical element portion 37 can be evaluated for reliability with respect to the optical element portion 37 by checking whether the optical element portion 37 is defective at the limit value through a screen test.

For example, when the light emitting device is mounted on the transceiver unit 30, the transceiver unit 30 generates an optical signal. When the light receiving element is mounted on the transceiver 30, the transceiver 30 receives the optical signal.

If the light emitting element and the light receiving element are simultaneously mounted on the transmission / reception section 30, the multi-wavelength optical subassembly module 1 may be used in combination for transmission or reception.

Referring to FIG. 3, the multi-wavelength optical subassembly module 1 according to an embodiment of the present invention further includes a sorting filter unit 80. The sorting filter unit 80 can prevent an optical signal of a different wavelength band from being introduced into a light receiving element to receive an optical signal of a predetermined wavelength band.

The sorting filter unit 80 is disposed between the optical filter unit 20 and the transceiver unit 30 to transmit only the optical signal having the selected wavelength. The sorting filter unit 80 filters optical signals of undesired wavelength bands to prevent optical signal interference.

For example, the sorting filter unit 80 may be disposed between the light filter unit 20 and the light aligning unit 70. At this time, the sorting filter unit 80 is coupled to the upper side of the light aligning unit 70 and disposed on the vertical line with the photo aligning lens 72.

The sorting filter unit 80 may be disposed between the light arranging unit 70 and the transceiver unit 30. At this time, the sorting filter unit 80 is coupled to the lower side of the light aligning unit 70 and disposed on the vertical line with the photo aligning lens 72. In addition, the sorting filter portion 80 can be coupled to the housing portion 10.

The operation of the multi-wavelength optical subassembly module according to an embodiment of the present invention will now be described.

A multi-wavelength optical subassembly module 1 is mounted on both ends of a single optical fiber cable 100.

The multi-wavelength optical subassembly module 1 includes a plurality of transceiver units 30 and a plurality of optical filter units 20 for guiding optical signals at positions corresponding to the transceiver unit 30.

At this time, the reliability evaluation is performed on the optical device section 37 mounted on the transmission / reception section 30.

On the other hand, the operating relationship of the multi-wavelength optical subassembly module 1 connected to the image transmitting apparatus such as a computer is as follows.

The five optical transmission units 31 for transmission and the one reception optical reception unit 32 having different wavelength bands are coupled to the optical alignment coupler 73. At this time, defective portions are separately replaced through the optical alignment operation between the optical transmission unit 31 and the transmission optical reception unit 32 for each transmission, and then the optical alignment unit is coupled to the optical alignment coupler 73.

Two transmission light transmission sections 31 and one transmission light reception section 32 which are arranged on the same line as the transmission lens guiding section 51 are arranged in the same manner as the transmission light reflection section 52, The wavelength band of the optical signal guided by the credit optical transmission unit 31 is long.

In this state, the optical signal having the wavelength of 780 nm is reflected by the third transmitting short reflector 553, and passes through the second transmitting short reflector 552 and the first transmitting short reflector 551.

Then, the light is reflected by the transmission light reflecting portion 52, reflected by the transmission lens guiding portion 51, and is moved to the lens portion 13 (see FIG. 6).

An optical signal having a wavelength of 825 nm is reflected by the second transmission single reflector 552 and passes through the first transmission single reflector 551. [

Then, the light is reflected by the transmitting light reflecting portion 52, reflected by the transmitting lens guiding portion 51, and is moved to the lens portion 13.

An optical signal having a wavelength of 870 nm is reflected through the first transmission short reflector 551 and reflected by the transmission light reflection portion 52. Then, it is reflected by the transmitting lens guiding part 51 and is moved to the lens part 13.

The optical signal having a wavelength of 915 nm is reflected through the first transmission reflector 531 and is transmitted to the lens unit 13 through the transmission lens guiding unit 51.

The optical signal having the wavelength of 960 nm is reflected through the second transmission reflector 532 and passes through the first transmission reflector 531 and passes through the lens guiding portion 51 to the transmission lens portion 13 .

In addition, the optical signal having a wavelength of 1005 nm transmitted from the image receiving apparatus sequentially passes through the transmitting lens guide unit 51, the first transmission reflector 531, and the second transmission reflector 532, Is reflected by the credit reception guide unit (54) and is guided to the transmission light reception unit (32).

In this case, the optical signals generated by the transmitting optical transmitter 31 means a video signal, a voice signal, and a control signal for implementing red, green, and blue colors, respectively, and the optical signal received by the transmitting and receiving unit 32 The optical signal means a status signal of the image receiving apparatus.

The operation of the multi-wavelength optical subassembly module 1 connected to the image receiving apparatus such as a monitor is as follows.

The five reception light receiving sections 34 and the one reception light transmission section 33 having different wavelength bands are coupled to the optical alignment coupler 73. At this time, the defective portions are separately replaced through the optical alignment operation of the reception light receiving portion 34 and the reception light transmission portion 33, and then the defective portions are coupled to the optical alignment coupling band 73.

The two reception light reception sections 34 and one reception light transmission section 33 which are arranged on the same line as the reception lens guide section 61 are connected to the reception light reflection section 62 by three The wavelength band of the optical signal guided by the credit light reception section 34 is long.

In the above state, the optical signal having the wavelength of 780 nm is reflected by the receiving lens guide portion 61, guided to the receiving light reflecting portion 52, and reflected by the receiving light reflecting portion 52.

After passing through the first reception end reflector 651 and the second reception end reflector 652, the light is reflected by the third reception end reflector 653 and is moved to the reception light reception portion 34 7).

The optical signal having a wavelength of 825 nm is reflected by the receiving lens guide portion 61, guided to the receiving light reflecting portion 62, and reflected by the receiving light reflecting portion 62.

After passing through the first reception end reflector 651, the light is reflected by the second reception end reflector 652 and is moved to the reception light reception portion 34

The optical signal having the wavelength of 870 nm is reflected by the reception lens guide portion 61 and guided to the reception light reflection portion 62 and reflected by the reception light reflection portion 62.

Then, the light is reflected by the first reception end reflector 651 and is moved to the reception light reception portion 34.

The optical signal having the wavelength of 915 nm passes through the reception lens guide portion 61 and is reflected by the first reception receiver reflector 631 and is moved to the reception light reception portion 34.

The optical signal having a wavelength of 960 nm is sequentially transmitted through the reception lens guide portion 61 and the first reception receiver reflector 631 and then reflected by the second reception receiver reflector 632 to be received by the reception receiver portion 34 .

In addition, the optical signal having a wavelength of 1005 nm to be transmitted to the image transmitting apparatus is reflected by the reception and transmission guide unit 64, and the second reception receiver 632, the first reception receiver 631, And passes through the reception lens guide portion 61 in order to be moved to the lens portion 13. [

In this case, the optical signals received by the reception light receiving section 34 means an image signal, a voice signal, and a control signal for implementing red, green and blue colors, respectively, The optical signal means a status signal of the image receiving apparatus.

On the other hand, a plurality of optical signals having different wavelengths are not interfered with each other even if they are moved through a single cable 100. A light sorting unit 70 is disposed between the optical filter unit 20 and the transceiving unit 30 to perform optical alignment and a sorting filter unit 80 is disposed between the optical filter unit and the transceiver unit 30 So that the optical signal that is not selected is filtered.

Accordingly, the present invention can smoothly transmit optical signals from a single cable 100 by transmitting / receiving optical signals of different wavelength ranges from / to a plurality of transmitting / receiving units 30.

In the present invention, since a plurality of transmission / reception units 30 are separately mounted, only defective portions can be replaced and used when individual defects are generated.

According to the present invention, since the plurality of transceivers 30 are separately mounted, concentration of the components between the components can be mitigated to prevent overheating.

The present invention enables reliable evaluation of the optical element (37), thereby improving product reliability.

The present invention is capable of suppressing optical signal distortion since the optical signal is dual-optically aligned by the light aligning section (70) and the lens section (13).

The present invention can prevent the interference of optical signals having different wavelength regions by arranging the selective filter unit 80 between the transceiver unit 30 and the optical filter unit 20. [

Since the transceiver 30 can be mass-produced in a production line, the present invention can improve the productivity and reduce the manufacturing cost.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the following claims.

10: housing part 11: body part
12: filter mounting part 13: lens part
20: Optical filter unit 30: Transmitting /
31: transmitting optical transmitter 32: transmitting optical receiver
33: receiving optical transmitter 34: receiving optical receiver
40: substrate portion 51: transmitting lens guide portion
52: light-transmitting reflecting portion 53: transmitting long-wavelength guiding portion
54: transmission and reception guide unit 55: short wavelength transmission guide unit
61: receiving lens guide part 62: receiving light reflecting part
63: Long-wavelength reception section for reception 64:
65: receiving short wavelength guide 70:
71: optical alignment body 72: photo alignment lens
73: optical alignment coupling base 80: sorting filter unit

Claims (14)

delete delete delete A housing part connected to the optical cable;
A plurality of optical filter parts coupled to the housing part and guiding an optical signal;
A plurality of transceivers coupled to the housing and receiving optical signals through the optical filter and transmitting optical signals to the optical filter; And
And a substrate portion to which the transmitting and receiving portions are respectively coupled,
The housing part
A body portion;
A plurality of filter mounting portions formed on the body portion and to which the optical filter unit is mounted; And
And a lens unit formed on the body and arranged to align optical signals transmitted and received through the optical cable,
Wherein the filter mounting portion is bonded to an edge of the optical filter portion so as not to interfere with an optical signal,
The optical filter unit
A transmission lens guiding unit which is disposed in a straight line with the lens unit, passes a light signal of a predetermined wavelength or more, reflects an optical signal of less than a predetermined wavelength and guides the light signal to the lens unit;
A transmission light reflection part disposed to face the transmission lens guiding part and reflecting the optical signal and guiding the optical signal to the transmission lens guiding part;
A transmission long wavelength guiding unit disposed in a straight line with the transmission lens guiding unit and guiding the optical signal generated by the transmission and reception unit to the transmission lens guiding unit;
A transmission reception guide unit disposed in a straight line with the transmission lens guide unit and guiding an optical signal having passed through the transmission long wavelength guide unit to the transmission / reception unit; And
And a transmission short wavelength guiding unit disposed in a straight line with the transmission light reflection unit and guiding the optical signal generated by the transmission and reception unit to the transmission light reflection unit. 5. The method of claim 4,
The transmission short wavelength guiding portion is composed of three optical waveguides, and reflects an optical signal having a shorter wavelength as it is farther from the transmission light reflection portion,
Wherein the transmission long wavelength guiding portion comprises two optical guiding portions and reflects an optical signal having a longer wavelength as it is farther from the transmission lens guiding portion. 6. The apparatus of claim 5, wherein the transceiver
A plurality of transmission optical transmission units for generating optical signals and transmitting the optical signals to the short wavelength guide for transmission and the long wavelength guide for transmission, respectively; And
And a transmission light reception unit for receiving the optical signal reflected by the transmission reception guide unit. A housing part connected to the optical cable;
A plurality of optical filter parts coupled to the housing part and guiding an optical signal;
A plurality of transceivers coupled to the housing and receiving optical signals through the optical filter and transmitting optical signals to the optical filter; And
And a substrate portion to which the transmitting and receiving portions are respectively coupled,
The housing part
A body portion;
A plurality of filter mounting portions formed on the body portion and to which the optical filter unit is mounted; And
And a lens unit formed on the body and arranged to align optical signals transmitted and received through the optical cable,
Wherein the filter mounting portion is bonded to an edge of the optical filter portion so as not to interfere with an optical signal,
The optical filter unit
A receiving lens guiding unit disposed in a straight line with the lens unit and passing an optical signal of a predetermined wavelength or more and reflecting an optical signal of less than a predetermined wavelength;
A receiving light reflecting unit arranged to face the receiving lens guiding unit and guiding the optical signal reflected by the receiving lens guiding unit;
A receiving long wavelength guide arranged in line with the receiving lens guiding unit and guiding an optical signal passed through the receiving lens guiding unit to the transmitting and receiving unit;
A receiving and transmitting guide unit disposed in a straight line with the receiving lens guide unit and guiding the optical signal generated by the transmitting and receiving unit to the receiving lens guide unit; And
And a reception short wavelength guiding unit disposed in a straight line with the reception light reflection unit and guiding the optical signal reflected by the reception light reflection unit to the transmission / reception unit. 8. The method of claim 7,
Wherein the receiving short waveguide guiding unit comprises three optical waveguides and reflects an optical signal having a shorter wavelength as the receiving optical waveguide is farther from the receiving optical waveguide,
Wherein the receiving long wavelength guiding unit comprises two optical guiding units and reflects an optical signal having a longer wavelength as the distance from the receiving lens guiding unit increases. The apparatus of claim 8, wherein the transceiver
A reception optical transmitter for generating an optical signal and transmitting the optical signal to the reception and transmission guide unit; And
And a plurality of reception light reception units receiving the optical signals reflected by the reception short wavelength guide unit and the reception long wavelength guide unit, respectively. 8. The method according to claim 4 or 7,
Further comprising a light alignment unit coupled to the housing unit and disposed between the optical filter unit and the transceiver unit to align optical signals. 11. The apparatus of claim 10, wherein the light aligning portion
A photo-alignment body coupled to the housing portion;
An optical alignment lens formed on the optical alignment body and aligning optical signals passing between the optical filter unit and the transceiver unit; And
And a photo-alignment coupling band formed on the photo-alignment body and coupled to the transmission and reception unit. 12. The apparatus of claim 11, wherein the transceiver
A hard substrate portion coupled to the photo alignment bonding pad;
A flexible substrate portion coupled to the rigid substrate portion and connected to the substrate portion; And
And an optical device part mounted on the flexible substrate part and transmitting and receiving an optical signal. 13. The method of claim 12,
Wherein the transceiver is fabricated from a plurality of integrated matrix type boards. 8. The method according to claim 4 or 7,
Further comprising a sorting filter unit disposed between the optical filter unit and the transmitting and receiving unit and transmitting only an optical signal having a selected wavelength.

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