KR100418204B1 - Wavelength division photodetector for multi channel - Google Patents

Abstract

Disclosed are a multi-channel wavelength division light receiving element. The disclosed multi-channel wavelength division light receiving device includes: a can type photodiode for detecting an optical signal; A filter assembly dual collimator installed to face the can-type photodiode and outputting an optical signal, pre-aligned with a dual collimator and a filter, and having an outer wall formed of a weldable metal material; A metal housing surrounding the can type photodiode and the filter assembly dual collimator and having a light passage formed therein so that the can type photodiode receives light; It is characterized in that it comprises a; and a boot to protect the fibers of the filter assembly dual collimator is installed surrounding the upper one side of the metal housing and the filter assembly dual collimator.

According to the present invention, since the functions of the filter CWDM and PD of the existing system can be directly integrated into one, the price competitiveness can be secured due to the reduction of material cost, etc. This has a possible advantage.

Description

Wavelength Division Light-Receiving Device for Multi-Channel {WAVELENGTH DIVISION PHOTODETECTOR FOR MULTI CHANNEL}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wavelength division light-receiving element for a multichannel, and more particularly, to filter coarse wavelength division multiplexing (hereinafter referred to as CWDM) and photodiode (hereinafter referred to as PD). The present invention relates to a multi-channel wavelength division light-receiving element for simultaneously functioning.

In general, PD fabrication technology belongs to automatic alignment and package technology using semiconductor fabrication technology and laser welding machine, and filter CWDM fabrication technology belongs to optical thin film coating technology and package technology.

The components are optical communication components, and the PD functions to convert an input optical signal into an electrical signal, and the filter CWDM separates a specific wavelength from all input wavelengths.

The PD belongs to the active component and is formed by aligning the can type PD with a metal ferrule. The filter CWDM is a passive component and consists of an array of dual collimators, filters, and single collimators.

1, a coaxial type PD is shown.

As shown, the PD receives the optical signal transmitted to the thin flexible optical fiber 11 to the PD cell or chip in the can type PD 12 to convert the optical signal into an electrical signal. In order to fix the optical fiber 11, the primary and secondary housings 13 and 14 and the metal ferrule 15 are manufactured by welding.

The can-type PD 12 is a photoelectric conversion element, the primary housing 13 fixes the can-type PD 12, and the secondary housing connects the primary housing 13 and the metal ferrule 15. Fix it.

In addition, the metal ferrule 15 fixes the secondary housing 14 and simultaneously holds and maintains the optical fiber 11 transmitting the optical signal. And boot (boot) 16 is installed to protect the appearance and the optical fiber.

2 shows a filter CWDM.

Referring to FIG. 2, the filter CWDM is a passive component that passes only a signal having a specific wavelength among various signals transmitted to the optical fiber 21, and reflects other signals. A single collimator 22, a dual collimator 23, and a filter are provided. Are manufactured by using epoxy and soldering.

The dual collimator 23 sends the input optical signal to the filter and receives and outputs the reflected optical signal, and the single collimator 22 outputs the specific optical signal passed through the filter.

The band pass filter (CWDM filter) 24 passes only a specific wavelength band and reflects all remaining wavelength bands. Typically, a band of ± 7 nm at 20 nm intervals of 1510 nm, 1530 nm, 1550 nm, and 1570 nm is typical. It is common to have a width.

In addition, the metal cap (25) is for protecting the appearance and the optical fiber 21, the two-piece holder (26) (26) secures the filter and the dual collimator (23), the primary housing ( 27 is installed to fix the single collimator 22 and the dual collimator 23, the secondary housing 28 is to reinforce the appearance and impact.

On the other hand, the WDM technology has made a lot of advances in order to simultaneously process a large amount of data at a low cost, and has seen many effects with the emergence of CWDM as described above.

3 illustrates an embodiment of a CWDM system to which CWDM is applied.

As shown, the PD and the filter CWDM are used in a dual manner, and this use requires the splicing of the optical fiber. As a result, the overall size of the system becomes larger, and workability and price competitiveness become inferior.

Recently, as demand for CWDM system increases, demand for filter CWDM and CWDM laser diode (LD) is increased. However, workability is relatively reduced.

The present invention was created in order to solve the above problems, the function of the filter CWDM and PD can be made at the same time to reduce the size of the applied system, improve the workability and price competitiveness for multi-channel It is an object to provide a wavelength division light receiving element.

1 is a view schematically showing a configuration of a general photodiode.

2 is a view schematically showing a configuration of a general filter CWDM.

Figure 3 is a schematic view showing the configuration of a CWDM system according to the prior art.

4 is a view schematically showing the configuration of a multi-channel wavelength division light-receiving element according to an embodiment of the present invention.

5 is a view schematically showing the configuration of a wavelength-dividing light receiving device for a multi-channel according to another embodiment of the present invention.

6 is a view schematically showing a configuration of a CWDM system to which the present invention is applied.

<Description of the symbols for the main parts of the drawings>

41,51. Canned PD 42. Filter Assembly Dual Collimator

43. Metal Housing 44,56. Boot

52. First Housing 53. Dual Collimator

54. Band Pass Filter 55. Second Housing

A multi-channel wavelength division light receiving device of the present invention for achieving the above object includes a can-type photodiode for detecting an optical signal; A filter assembly dual collimator installed to face the can-type photodiode and outputting an optical signal, pre-aligned with a dual collimator and a filter, and having an outer wall formed of a weldable metal material; A metal housing surrounding the can type photodiode and the filter assembly dual collimator and having a light passage formed therein so that the can type photodiode receives light; It is characterized in that it comprises a; and a boot to protect the fibers of the filter assembly dual collimator is installed surrounding the upper one side of the metal housing and the filter assembly dual collimator.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is a schematic diagram showing an embodiment of a multi-channel wavelength division light receiving device according to the present invention.

Referring to the drawings, the multi-channel wavelength division light-receiving element according to the present invention is provided so as to face a photodiode, for example, a can-type PD 41, which is an optical / electric conversion element for detecting an optical signal, and the can-type PD 41. A filter assembled dual collimator 42 having an outer wall made of a weldable metal material and outputting an optical signal, and pre-aligning the dual collimator and the filter. (41) and the filter assembly dual collimator (42) is installed, the metal housing (43) formed with a light port (43a) so that can-type PD (41) can receive light, and the upper portion of the metal housing (43) One side and the upper portion of the filter assembly dual collimator 42 is installed to include a boot 44 to protect the fibers (fiber) of the filter assembly dual collimator 42.

After aligning the filter assembly dual collimator 42 and the metal housing 43, the filter assembly dual collimator 42 and the metal housing 43 are laser welded, and the outer wall of the filter assembly dual collimator 42 is made of metal. Since it is to be welded with the housing 43 is made of stainless steel (SUS).

5 is a schematic view showing another embodiment of a multi-channel wavelength division light receiving device according to the present invention.

As shown, the can-type PD 51, which is an optical / electric conversion element for detecting an optical signal, is provided to surround the can-type PD 51, and an upper portion of the can-type PD 51 can receive an optical signal. A through-hole 52a is formed, and the can-shaped PD 51 and the first housing 52 for fixing the band pass filter 54 to be described later, and the can-hole of the first housing 52 toward the can-hole 52a. It is installed between the PD 51 and the dual collimator 53 which outputs an optical signal, and is installed between the dual collimator 53 and the can-type PD 51 to pass only a specific wavelength band, and the other wavelength band is reflected. A band pass filter 54 and the outer circumferential surface of the dual collimator 53 are installed on the upper portion of the first housing 52 to fix the first housing 52 and the dual collimator 53. The second housing 55 and the second housing 55 and the upper part of the dual collimator 53 are installed covering the dual collimator ( 53, a boot 56 for protecting the fibers.

The dual collimator 53 and the second housing 55, and the first housing 52 and the second housing 55 are fixed by laser welding.

In particular, the outer wall of the dual collimator 53 used for the input of the optical signal and the output of the optical signal reflected by the band pass filter 54 is made of stainless steel (SUS) because it is to be welded to the second housing (55).

FIG. 6 is a system diagram schematically showing the configuration of a CWDM system to which the multi-channel wavelength division light receiving device according to the present invention having the configuration as described above is applied.

As shown, when the optical signal is input at 1510nm, 1530nm, 1550nm, 1570nm LD, it is multiplexed into a 4-channel CWDM multiplex (Mux) and then transmitted through one optical fiber.

The optical signal thus transmitted is demultiplexed through the multi-channel wavelength division light receiving device according to the present invention and restored to the original signal.

The wavelength-division light-receiving element for a multi-channel according to the embodiment of the present invention configured as described above has the shape of a conventional PD as shown in FIG. 1, but the function of the conventional PD of FIG. It combines the functions of the filter CWDM as shown. Therefore, the present invention is simple in operation according to the structure and manufacturing. This will be described in more detail.

Referring to the operation of the multi-channel wavelength division light receiving device according to the present invention as described above are as follows.

In one embodiment of the present invention, a wavelength-dividing light-receiving element for a multi-channel device incorporates the performance of a filter CWDM into a PD and integrates the filter assembly dual collimator 42 and the can-type PD 41 as illustrated in FIG. 4. Is made of.

And the filter assembly dual collimator 42 is made of a material of stainless steel, for example, SUS 304, SUS316 or SUS430, the laser welding is performed.

In another exemplary embodiment of the present invention, the wavelength-dividing light receiving device for the multi-channel according to the present invention may be configured in the order of the can-type PD 51, the band pass filter 54, and the dual collimator 53 in the configuration of the PD package. It is aligned and applicable to all products so aligned.

The band pass filter 54 is also applicable to all of the maximum ranges that enter the CWDM system. Here, the maximum range refers to 19 kinds of filters from 1270 nm to 1630 nm at 20 nm intervals. In addition, it can be applied to the modified filter of the type found in the CWDM specification.

The PD assembly may be applicable to both the case of using the filter assembly dual collimator 42 and the case of using the band pass filter 54 and the dual collimator 53, respectively.

As described above, the multi-channel wavelength division light receiving device according to the present invention has the following effects.

The functions of the filter CWDM and PD of the existing system can be directly integrated to secure price competitiveness due to the reduction of material costs, and the overall workability can be improved by simplifying the work process in the overall system configuration.

In addition, the total system size can be significantly reduced compared to the case of using the conventional filters CWDM and PD, respectively, thereby minimizing the size of parts and equipment.

In addition, different types of PDs can be used depending on the type of filter, which enables multichannel expansion.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments are possible. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

Claims (6)

delete delete delete A can-type photodiode for detecting an optical signal; A first housing surrounding the can-type photodiode and having an optical port formed thereon to allow the can-type photodiode to receive an optical signal; A dual collimator facing the optical port and installed to face the can-type photodiode, the dual collimator including an optical fiber for an incident optical signal and an optical fiber for a reflected optical signal; A band pass filter installed between the dual collimator and the can-type photodiode and passing only a specific wavelength band of the optical signals passing through the dual collimator, and reflecting the other wavelength bands into an optical fiber for the reflected optical signal; A second housing installed around the outer circumferential surface of the dual collimator at an upper portion of the first housing to fix the first housing and the dual collimator; And a boot provided to surround the second housing and the upper part of the dual collimator to protect the fibers of the dual collimator. The method of claim 4, wherein And the dual collimator and the second housing, and the first housing and the second housing are fixed by laser welding. The method of claim 4, wherein The outer wall of the dual collimator is a multi-channel wavelength division light receiving device, characterized in that made of stainless steel.