KR20160145956A - Wavelength multiplexing optical receiving module - Google Patents

Abstract

According to the present invention, various forms of wavelength multiplexing optical receiving modules are disclosed. The present invention relates to the wavelength multiplexing optical receiving module to perform optical communication of a wavelength division multiplexing (WDM) method. The wavelength multiplexing optical receiving module comprises: a parallel light receptacle unit; a zigzag filter unit; an optical package unit; and a pre-amplification element unit.

Description

[0001] Wavelength multiplexing optical receiving module [

The present invention relates to a wavelength multiplexed light receiving module, and more particularly, to a wavelength multiplexed light receiving module using a thin film filter.

As the demand for data increases, the speed and capacity of optical communication have also been increasing rapidly. Optical communication systems having a transmission capacity of 10 Gbps or more have already been commercialized by using optical signals of a single wavelength. However, in recent metro and periodic transmission networks, a transmission capacity of 40 Gbps or 100 Gbps is required for one optical fiber, so that optical signals of four different wavelengths having a transmission rate of 10 Gbps or 25 Gbps are multiplexed on one optical fiber to transmit 40 Gbps or 100 Gbps (WDM) type optical communication for transmitting data is used.

In this wavelength division multiplexing optical communication, an optical transmission module for wavelength division multiplexing laser light of four wavelengths and an optical signal transmitted through an optical line are demultiplexed into respective wavelengths, "Wavelength Division Multiplexed Optical Receiving Module" which amplifies the detected electric signal is constituted as a core component of the optical communication system. The wavelength multiplexing light receiving module includes a receptacle for coupling an optical fiber connector and an optical receiving module located at the end of an optical line, an optical coupling lens, a demultiplexing device for demultiplexing received optical signals of different wavelengths into respective wavelengths, A photodetecting device for converting the lights separated into respective wavelengths into an electric signal (photocurrent), and a transfer-impedance-type amplifying device for amplifying these electric signals.

Such a wavelength multiplexed light receiving module is divided into two types according to the types of demultiplexing elements as follows. As shown in FIG. 1, the first type wavelength division multiplexing light receiving module uses an arrayed waveguide grating (AWG) element 14 as a demultiplexing element to separate multiplexed light into respective wavelengths The optical signals corresponding to the separated wavelengths are converted into electric signals by using the photodetector element 16 and the preamplifier element 18, and then amplified and outputted.

More specifically, the wavelength multiplexed light receiving module (abbreviated as 'light receiving module' hereinafter) using the arrayed waveguide grating device 14 has a structure in which the portion of the receptacle 11 into which the ferrule 12 is inserted is fastened to an optical fiber connector When the multiplexed optical signal enters the inside of the light receiving module, the aspherical lens 13 is used to couple the light into the optical waveguide of the arrayed waveguide grating device 14, and the optical signal is received in the arrayed waveguide grating device 14 Separated by respective wavelengths, and emitted through each of the other output ports.

The respective wavelengths output from the optical waveguide of the arrayed waveguide grating element 14 and diverged are converged by the lens 15 into the light receiving area of the photodetector element 16 responsible for detecting each optical signal, 16 amplify and output the respective signals in a plurality of transmission impedance type preamplifiers 18 connected to each other by wire bonding (not shown) located at the rear end of the electric signal detected according to the converged wavelength.

In this first type of conventional light receiving module, the greatest disadvantage is that a large amount of light loss occurs in the optical path until the optical signal input to the receptacle 11 is finally input to the photodetector element 16. Optical loss occurs not only when the input light is put into the optical waveguide of the arrayed waveguide grating element 14 but also inside the arrayed waveguide grating element 14 by using the aspherical lens 13. [

In order to reduce the optical loss generated in the arrayed waveguide grating device 14, the optical waveguide should be designed so that the deflection of the optical waveguide from the common port of the input end of the arrayed waveguide grating device 14 to the port of each wavelength of the output end is minimized The size of the arrayed waveguide grating device 14 becomes large, which increases the size of the entire optical receiving module. Generally, in the case of a light receiving module using such an arrayed waveguide grating device 14, the total optical insertion loss is usually as large as 2 dB or more.

 As shown in FIG. 2, the other type light receiving modules include thin film filters 25-1 to 25-4 (see FIG. 2) for passing only the respective wavelengths through a demultiplexing device for dividing the wavelength of the multiplexed light into four wavelengths. ). ≪ / RTI >

At this time, the demultiplexing device including the thin film filters 25-1 to 25-4 is generally referred to as a 'zigzag filter' in the industry, and the zigzag filter is a glass block processed to have a predetermined angle, Thin film filters 25-1 to 25-4 adhered to one side of the glass block 24 at predetermined intervals and glass blocks 24 corresponding to the thin film filters 25-1 to 25-4, And a reflection block 24-1 coated with a reflective coating formed on the other side of the thin film filters 25-1 to 25- 4).

The operation principle of the conventional light receiving module 20 using the zigzag filter will be briefly described. The optical signal inputted through the ferrule 22 in the receptacle 21 is spread by the difference in refractive index with air, The optical signal is made into parallel light (L) by the aspherical lens (23).

When the parallel light L passes through the zigzag filter, it is separated into optical signals of respective wavelengths. The optical signals of the respective wavelengths are converted into focal light while passing through the array lens 26, The optical signal is input to a photodetector element 28 that is reflected by a reflective mirror 27 attached at an inclination of 45 degrees and horizontally attached to the metal optical bench 32.

The photodetecting device 28 receives the electric signals detected in accordance with the inputted optical signals of the respective wavelengths and transmits the respective signals in a plurality of transfer impedance type preamplifiers 29 connected in wire bonding (not shown) Amplified and output.

The conventional light receiving module 20 using such a zigzag filter has an advantage that the insertion loss of the optical signal can be significantly reduced as compared with the light receiving module 10 using the arrayed waveguide grating device 14, It also has the advantage of smaller size.

However, in the optical receiving module 20 using the thin film filters 25-1 to 25-4, the characteristics of the insertion loss and the band-pass wavelength of the zigzag filter are different from the incident angle of the optical signal incident on the thin film filter (Refer to FIG. 3, insertion loss of about 2dB occurs when a change in the incident angle of +/- 0.1 degree is caused in a thin film filter designed to have an angle of incidence (AOI) of 10 degrees) There is a disadvantage in that the deviation of the electric signal measured by the photodetector 28 according to the input accuracy of the focal light is significant.

In order to minimize the insertion loss due to the incident angle change of the thin film filter and the deviation of the electric signal measured from the photodetecting device, a convex lens type which allows the divergent light to enter into the zigzag filter as parallel light so that the incident angle change is minimized Of the aspheric lens 23 and the position and angle alignment of the array lens 26 for making the parallel light beams passing through the zigzag filter and separated into the respective wavelengths correctly enter the light receiving area of the photodetector element 28 are very important .

However, the alignment of the positions and angles of the aspheric lens 23 and the array lens 26 so far with each other is performed by manually aligning (active alignment) the electrical signals detected from the photodetector element 28 while measuring them, Time and input manpower, resulting in an increase in manufacturing cost and a significant decrease in productivity.

Therefore, there is a need for a new structure of a light receiving module capable of solving the above problems, improving performance and productivity, and minimizing the manufacturing cost and size.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a wavelength multiplexed light receiving module using a thin film filter, in which an aspherical lens and an array lens can be easily aligned on a metal optical bench, A wavelength multiplexing light receiving module capable of reducing the number of components, size, manufacturing process, and manufacturing cost of the module.

According to an aspect of the present invention, there is provided a wavelength multiplexed light receiving module for optical communication using a wavelength division multiplexing (WDM) method, the module including: a receptacle coupled to an optical fiber connector formed at a terminal end of a light path; A parallel light receptacle part constituting a hill type refractive index lens (GRIN LENS) for converting input light into parallel light; A glass block having a parallelogram shape, a coating part formed on one side of the glass block, and a thin film filter formed on the other side of the glass block on which the coating part is formed, part; An array lens disposed at a rear end of the zigzag filter unit to convert an optical signal of a parallel optical type separated from the zigzag filter unit into an optical signal of a focal optical type; An array optical detecting element disposed horizontally with the optical signal and detecting an electrical signal according to an optical signal for each wavelength emitted from the array lens, a reflecting mirror for converting the direction of the focal light emitted from the array lens to the array optical detecting element side And a metal optical bench for aligning and aligning the zigzag filter unit, the array lens, the reflecting mirror, and the array photodetecting device on an upper surface thereof; A preamplifier unit comprising a transfer preamplifier array preamplifier for amplifying and outputting an electric signal detected by the photodetector, an array preamplifier submount on which the array preamplifier is mounted, and a module housing; A wavelength multiplexing light receiving module including the wavelength multiplexing light receiving module may be provided.

According to another aspect of the present invention, there is provided a wavelength multiplexed light receiving module for optical communication using a wavelength division multiplexing (WDM) method, the module including: a receptacle coupled to an optical fiber connector formed at the end of a light path; A parallel light receptacle part which is positioned and constitutes a hill type refractive index lens (GRIN LENS) for converting input light into parallel light; A glass block having a parallelogram shape, a coating part formed on a side surface of the glass block, and a thin film filter formed on the other side of the glass block on which the coating part is formed, so that a zigzag filter part; An array lens disposed at a rear end of the zigzag filter unit to convert an optical signal of a parallel optical type separated from the zigzag filter unit into an optical signal of a focal optical type; An array photodetecting element arranged vertically with respect to the optical signal for detecting an electric signal in accordance with the focal light emitted from the array lens; an array photodetecting element submount for vertically mounting the array photodetecting element; An optical package unit comprising a filter unit, a metal optical bench for aligning and aligning the array lens, the array photodetecting device and the array photodetecting device submount; And an array pre-amplification sub-mount on which the array pre-amplification device is mounted, and a pre-amplification unit sub-module including a module housing, A wavelength multiplexed light receiving module may be provided.

According to another embodiment of the present invention, there is provided a wavelength multiplexed light receiving module for optical communication using a wavelength division multiplexing (WDM) method, the module including: a receptacle coupled to an optical fiber connector formed at the end of a light path; A parallel light receptacle portion which is located in the space and constitutes a hill type refractive index lens (GRIN LENS) for converting input light into parallel light; A glass block having a parallelogram shape, a coating part formed on a side surface of the glass block, and a thin film filter formed on the other side of the glass block on which the coating part is formed, so that a zigzag filter part; A reflecting mirror for vertically refracting an optical signal of a parallel light type separated and emitted from the zig-zag filter unit in a downward direction, and a collimator lens disposed parallel to the reflecting mirror at a lower side of the reflecting mirror, Type optical signal into an optical signal of a focal-light type, and an optical signal according to an optical signal of a focal-light type, which is arranged in parallel with the array lens at a lower side of the array lens and is emitted from the array lens, And a metal optical bench for aligning and aligning the reflection mirror, the array lens, and the array photodetecting elements at a predetermined interval in parallel with each other, An optical package unit configured; A preamplifier unit comprising a transfer preamplifier array preamplifier for amplifying and outputting an electric signal detected by the photodetector, an array preamplifier submount on which the array preamplifier is mounted, and a module housing; A wavelength multiplexing light receiving module including the wavelength multiplexing light receiving module may be provided.

The wavelength multiplexing light receiving module according to various embodiments of the present invention can minimize the active alignment process by manufacturing the optical receiving module and the optical receiving module is formed by individually manufacturing and assembling a plurality of individual assembly- The productivity (manufacturing yield) of the overall module can be improved.

In addition, it is possible to mass-produce the optical receiving module having excellent characteristics at a low price while improving the manufacturing yield, and also to reduce the price of the optical transceiver that uses the optical receiving module as an important component, ultimately to activate the optical receiving module market, Technology to greatly increase the data transmission capacity of the optical communication.

1 is a plan view showing a wavelength division multiplexing light receiving module using a conventional arrayed waveguide grating (AWG) device.
2 is a plan view and a cross-sectional view illustrating a wavelength division multiplexed light receiving module using a conventional thin film filter.
FIG. 3 is a graph showing an insertion loss curve according to an angle of incidence of a band pass filter of a wavelength division multiplexing light receiving module using the thin film filter of FIG. 2. FIG.
4 is a plan view and a cross-sectional view illustrating a wavelength division multiplexing light receiving module according to an embodiment of the present invention
5 is a cross-sectional view showing a state in which a silicon V-groove reflective mirror is applied to the optical package unit of FIG.
6 is an assembly explanatory view for explaining an assembling process of the wavelength division multiplexing light receiving module of FIG.
7 is a cross-sectional view illustrating a wavelength division multiplexing light receiving module according to another embodiment of the present invention.
8 is a cross-sectional view showing a state in which a lens-integrated photodetecting device is applied to the optical packaged portion of FIG.
9 is a plan view and a cross-sectional view illustrating a parallel optical receptacle portion and an optical package portion of a wavelength division multiplexing light receiving module according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided by way of example so that those skilled in the art can fully understand the spirit of the present invention. Therefore, the present invention is not limited to the embodiments described below, but may be embodied in other forms. In the drawings, the width, length, thickness, etc. of components may be exaggerated for convenience. In addition, like reference numerals throughout the specification may refer to like elements.

4 is a plan view and a cross-sectional view illustrating a wavelength division multiplexing light receiving module according to an embodiment of the present invention. 5 is a cross-sectional view showing a state in which a silicon V-groove reflective mirror is applied to the optical package unit of FIG.

Referring to FIG. 4, a wavelength multiplexed light receiving module (hereinafter, abbreviated as 'light receiving module') according to an embodiment of the present invention includes a parallel light receptacle 110, a zigzag filter 120, An optical package unit 130 and a preamplifier unit 140.

The parallel optical receptacle unit 110 has a cylindrical receptacle 111, a ferrule 112 located inside the receptacle, a receptacle (not shown) 111 and a ferrule 112 and a hill type refractive index lens 114 located inside the receptacle 111 at the rear end of the ferrule 112. At this time, the ferrule 112, the sleeve 113, and the hill-shaped refractive index lens 114 have the same central axis in the inside of the receptacle 111.

The parallel light receptacle part 110 is further characterized by inserting a hill-shaped refractive index lens 114 in comparison with a conventional receptacle part composed of only a ferrule and a sleeve. At this time, the ferrule 112 and the hill- 114) can be machined on mutually facing surfaces. The hill type refractive index lens 114 functions to convert the dispersed light emitted through the ferrule 112 into parallel light. Since the position of the focal distance for making perfect parallel light is determined by the length of the hill type refractive index lens 114, the hill type refractive index lens 114 of the desired standard can be used, And ease of fabrication can be increased. The hill-shaped refractive index lens 114 has a structure in which the ferrule 122 of the same cylindrical structure is inserted and mounted in the receptacle 111 without a separate alignment process inside the receptacle 111 having a cylindrical structure, Since only a process of fixing to an accurate position is required, relatively complete parallel light can be produced without a separate active alignment.

The parallel light receptacle unit 110 includes an aspherical convex lens configured to produce parallel light in a conventional light receiving module and an aspherical convex lens configured to measure the photocurrent of the photodetector in order to position the aspherical convex lens at an accurate focal distance. It is possible to solve the problems of increasing the complexity of the assembling process and lowering the production yield due to the use of the active alignment method for locating and fixing the convex lens.

The zigzag filter unit 120 is a demultiplexing device for demultiplexing optical signals for respective wavelengths. The zigzag filter unit 120 includes a glass block 123 having a parallelogram shape, And a thin-film filter 124-x (124-1 to 124-4) for passing an optical signal. At this time, the coating portions 121 and 122 may be formed on the other side of the glass block 123 on which the thin film filters 124-x: 124-1 to 124-4 are formed.

The coating portions 121 and 122 are formed in the remaining regions except the region where the anti-reflection film coating is formed and the anti-reflection film coating 121 formed in a certain region corresponding to the region where the optical signal is incident through the hill type refractive index lens 114 A reflective coating 122 may be formed.

At this time, the anti-reflection coating 121 formed on one side of the glass block 123 minimizes the loss due to reflection of the optical signal entering through the hill-shaped refractive index lens 114 on the glass block 123, The reflection film coating 122 reflects the optical signal reflected from the thin film filter 124-1 formed on the opposite side and then reflects back to the thin film filters 124-2 to 124-4.

The zigzag filter unit 120 is formed by first coating a whitewash coating 121 on a part of one side of a glass plate having a predetermined refractive index and thickness and then coating a reflection coating 122 on another area on the same side, The next cut glass block is polished at a precise angle so that its cross section is in the form of a parallelogram, and then pre-fabricated thin film filters 124-x: 124-1 to 124-4 are formed on the glass block 123 And then sequentially attaching them to predetermined positions on the other side surface corresponding to the side surfaces.

The zigzag filter unit 120 according to this type of structure and fabrication process can reduce the number of components required and simplify the assembly process compared to the conventional structure in which a separate reflective film is attached to the side of the glass block, The manufacturing cost can be lowered.

The optical packaged section 130 may include an array lens 131, a reflective mirror 132, an array photodetector element 133, and a metal optical bench 134.

At this time, the array lens 131 integrates the lens for converting the divergent light into the focal light into one component, and the array photodetector element 133 integrates the photodetector element into one component, And the like.

The reflecting mirror 132 is disposed on the upper side of the array photodetecting device 133 and is configured to refract the focal light emitted by the array lens 131 to the array photodetecting device 133. A reflecting film And can be positioned at an angle (about 45 degrees) to be inclined.

The metal optical bench 134 is a component in which the zigzag filter portion 120, the array lens 131, the reflecting mirror 132 and the array photodetecting element 133 are seated and fixed, The alignment trench 135 and the seating portion 135a can be formed to be fixed. An alignment groove corresponding to the glass block 123 of the zigzag filter unit 120, the array lens 131 and the array photodetecting device 133 can be formed on the upper side of the metal optical bench 134 have. In addition, a seating part 135a may be formed on the upper side of the array photodetector 133 so that the reflecting mirror 132 is inclined at a predetermined angle to be seated.

The metal optical bench 134, in which the alignment troughs 135 and seating portions 135a for alignment and seating of the respective components are machined, provides a conventional active alignment for each of the components, particularly the array lens 131 It is possible to arrange the positions of the respective components only by mechanical precision without performing the operation, and in the case of the reflection mirror 132, there is no need to provide separate components for angle adjustment and seating, And the production efficiency can be improved. Further, as each component is aligned and seated on the alignment trench 135 and the seating portion 135a of the metal optical bench 134, damage to the components due to external force and deformation of the alignment state are prevented, thereby improving the mechanical durability of the optical package portion .

The preamplifier unit 140 includes a light receiving module housing 141 and an array preamplifier 141 and an array preamplifier 141 in which transfer amplification type preamplification (TIA) And an array preamplifier submount 143 that is seated.

FIG. 5 is a cross-sectional view showing a state in which a V-groove etched silicon semiconductor is applied to the optical package unit of FIG.

On the other hand, as shown in Fig. 5, instead of the plate-shaped reflection mirror 136 for refracting the focal light emitted by the array lens 131 to the optical packaged portion to the downside where the array photodetecting element 133 is located, A home reflective mirror 136 may be constructed. The silicon V-groove reflective mirror 136 is formed by etching a V-groove on the silicon semiconductor and coating the etched inclined surface with a reflection film. The silicon V-groove reflective mirror 136 is formed by a conventional planar reflective mirror 132 It can be operated more efficiently in terms of reducing the cost of the optical package unit 130 as compared with the case of using the reflective mirror 136. In addition,

However, when the light is deflected toward the array photodetecting device 133 using the silicon V-groove reflecting mirror 136, the reflection angle is about 45 degrees, which is about 54.7 degrees, which is the angle of the inclined surface when the silicon is wet-etched . In this case, the light incident on the array photodetector element 133 is incident at about 80.3 degrees instead of 90 degrees. However, since the adjustment can be made according to the position of the reflection mirror, a large influence (or change) A) Not available.

The parallel optical receptacle 110, the zigzag filter unit 120, the optical package unit 130, and the preamplifier unit 140 constituting the light receiving module according to the embodiment of the present invention may be manufactured as separate assemblies And the assembling process can be performed, and the assembly process thereof will be described with reference to FIG.

6 is an assembly explanatory view for explaining an assembling process of the wavelength division multiplexing light receiving module of FIG.

First, an assembling step-1 process of attaching the zigzag filter unit 120 to a predetermined position of the optical package unit 130 is performed. At this time, the distance between the zigzag filter unit 120 and the array lens 131 does not affect the characteristics of the module during the assembly step-1 process, but the degree of distortion of the zigzag filter unit 120 is large . Since the alignment groove 315 is formed in the metal optical bench 134 according to the present invention, the zigzag filter unit 120 can be mounted on the alignment groove 315, The assembly can be performed with minimized distortion of the body.

An assembling step-2 process of attaching the optical package part 130 in which the zigzag filter part 120 is assembled to a predetermined position in the preamplifier part 140 is carried out in the assembling step -1. The accuracy of this assembly process does not affect the optical characteristics of the light receiving module, so accurate positional accuracy is not required. The array photodetector elements of the optical package unit 130 assembled inside the preamplifier unit 140 are connected to the array preamplifier elements 142 of the preamplifier unit 140 by wire bonding Omission).

Finally, in the assembly step of assembling the parallel optical receptacle part 110 to the assembled assembly of the zigzag filter part 120, the optical package part 130 and the preamplifier part 140 completed in the assembling step-2, -3 process is carried out. In this assembling process, light is inputted through the receptacle of the parallel light receptacle part 110 while reading the output electric signal (photocurrent) value of the corresponding array photodetecting device, and at the position where the maximum electric signal value can be obtained, Assembled by an active alignment method for fixing the part 110. In this case, it is necessary to arrange active array elements such that the electric signal values of the minimum two or more array photodetector elements are equal to or more than a predetermined reference value, and the optical detector element having the shortest optical path of the parallel light L and the longest photodetector element 1, 124-4) may be effective.

Hereinafter, a wavelength division multiplexed light receiving module according to another embodiment of the present invention will be described.

7 is a cross-sectional view illustrating a wavelength division multiplexing light receiving module according to another embodiment of the present invention. 8 is a cross-sectional view showing a state in which a lens-integrated photodetecting device is applied to the optical packaged portion of FIG.

7, a light receiving module according to another embodiment of the present invention includes an array photodetector 133, which is one of the components of the optical packaged unit 130, And is vertically attached to the array photodetecting device submount 237 which is not attached to the upper surface of the bench 234. According to this structure, since it is not necessary to refract the direction of the light incident on the array photodetecting device 233, the reflection mirror 132 or the silicon V-groove reflecting mirror 136, which is configured in the optical package unit of the embodiment, It is possible to manufacture a more compact optical receiving module.

In addition, an array photodetecting device 233 of the light receiving module according to another embodiment of the present invention shown in FIG. 8 is used. The lens integrated photodetecting device 238 is a module in which a lens is integrally formed on the back surface of the light receiving area of the photodetecting device. If light is input to the light receiving area through the front surface of the existing photodetecting device, And the light input through the lens is input to the light receiving area through the rear surface of the photodetecting device.

 Since the optical packaged unit 230 using the lens integrated photodetector 238 does not require an array lens for converting the parallel light L having passed through the zigzag filter unit 220 into the focal light, Simplifying the process and reducing the size of the fabrication module.

Hereinafter, a wavelength division multiplexed light receiving module according to another embodiment of the present invention will be described.

9 is a plan view and a cross-sectional view showing a parallel light receptacle part 320 and an optical package part 330 of a wavelength division multiplexing light receiving module according to another embodiment of the present invention.

9, the optical receiving module according to another embodiment of the present invention differs from the optical receiving module according to the above-described embodiment in terms of the optical package portion, .

The optical packaged part 330 according to another embodiment of the present invention includes an array lens 331 disposed between the zigzag filter part 320 and the reflective mirror 333 as the reflective mirror 332 and the array optical detection element 333). ≪ / RTI > At this time, the array lenses 331 are arranged in parallel with the array photodetecting elements 333 in the same vertical direction.

The distance between the array lens 331 and the array photodetector element 333 is set at a predetermined position on both edges of the metal optical bench 334 so that the array photodetector element 333 is positioned at the focal distance of the array lens 331 So that the array lens 331 can be aligned. This can be matched with the seat portion described in one embodiment.

As described above, the optical receiving module according to various embodiments of the present invention can minimize the active alignment process by manufacturing the optical receiving module, and the optical receiving module is formed by individually manufacturing and assembling a plurality of individual assembly- The productivity of the overall module (manufacturing yield) can be improved.

In addition, it is possible to downsize the module and reduce the manufacturing cost by reducing the number of components, thereby reducing the price of the optical transceiver that uses the optical receiving module as an important component. It can contribute greatly to increase the data transmission capacity of the optical communication by using the wavelength multiplexing technique.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. The present invention is not limited to the drawings, and all or some of the embodiments may be selectively combined so that various modifications may be made.

110, 210: parallel light receptacle portion
111, 211: Receptacle
112, 212, 212: Closed
113, 213: Sleeve
114, 214: a hill type refractive index lens (GRIN LENS)
120, 220, and 320: a zigzag filter unit
121, 221, 321: anti-reflection coating
122, 222, 322: reflection film coating
123, 223, 323: glass block
124-X, 224-X, 324-X: Thin film filter
130, 230, and 330:
131, 331, 331: Array lens
132, 332: reflection mirror
133, 233, 333: array photodetector element
134, 234, 334: Metal optical bench
135, 235, 335: alignment groove
135a and 335a:
136: Silicon V-groove reflective mirror
140, 240: Preamplifier section
141, 241: Module housings
142, 242: array preamplifier
143: Array preamplifier submount
237: Array photodetecting device submount
238: Lens integrated photodetector

Claims (11)

A wavelength multiplexed light receiving module for optical communication using a wavelength division multiplexing (WDM)
A parallel light receptacle part formed in the inner space of the receptacle and constituted by a hill type refractive index lens (GRIN LENS) for converting input light into parallel light;
A glass block having a parallelogram shape, a coating part formed on a side surface of the glass block, and a thin film filter formed on the other side of the glass block on which the coating part is formed, so that a zigzag filter part;
An array lens disposed at a rear end of the zigzag filter unit to convert an optical signal of a parallel optical type separated from the zigzag filter unit into an optical signal of a focal optical type; An array optical detecting element disposed horizontally with the optical signal and detecting an electrical signal according to an optical signal for each wavelength emitted from the array lens, a reflecting mirror for converting the direction of the focal light emitted from the array lens to the array optical detecting element side And a metal optical bench for aligning and aligning the zigzag filter unit, the array lens, the reflecting mirror, and the array photodetecting device on an upper surface thereof; And
A preamplifier unit comprising a transfer preamplifier array preamplifier for amplifying and outputting an electric signal detected by the photodetector, an array preamplifier submount on which the array preamplifier is mounted, and a module housing; A wavelength multiplexing light receiving module. A wavelength multiplexed light receiving module for optical communication using a wavelength division multiplexing (WDM)
A parallel light receptacle part formed in the inner space of the receptacle and constituted by a hill type refractive index lens (GRIN LENS) for converting input light into parallel light;
A glass block having a parallelogram shape, a coating part formed on a side surface of the glass block, and a thin film filter formed on the other side of the glass block on which the coating part is formed, so that a zigzag filter part;
An array lens disposed at a rear end of the zigzag filter unit to convert an optical signal of a parallel optical type separated from the zigzag filter unit into an optical signal of a focal optical type; An array photodetecting element arranged vertically with respect to the optical signal for detecting an electric signal in accordance with the focal light emitted from the array lens; an array photodetecting element submount for vertically mounting the array photodetecting element; An optical package unit comprising a filter unit, a metal optical bench for aligning and aligning the array lens, the array photodetecting device and the array photodetecting device submount; And
A preamplifier unit comprising a transfer preamplifier array preamplifier for amplifying and outputting an electric signal detected by the photodetector, an array preamplifier submount on which the array preamplifier is mounted, and a module housing; Multiplexed light receiving module. A wavelength multiplexed light receiving module for optical communication using a wavelength division multiplexing (WDM)
A parallel light receptacle part formed in the inner space of the receptacle and constituted by a hill type refractive index lens (GRIN LENS) for converting input light into parallel light;
A glass block having a parallelogram shape, a coating part formed on a side surface of the glass block, and a thin film filter formed on the other side of the glass block on which the coating part is formed, so that a zigzag filter part;
A reflecting mirror for vertically refracting an optical signal of a parallel light type separated and emitted from the zig-zag filter unit in a downward direction, and a collimator lens disposed parallel to the reflecting mirror at a lower side of the reflecting mirror, Type optical signal into an optical signal of a focal-light type, and an optical signal according to an optical signal of a focal-light type, which is arranged in parallel with the array lens at a lower side of the array lens and is emitted from the array lens, And a metal optical bench for aligning and aligning the reflection mirror, the array lens, and the array photodetecting elements at a predetermined interval in parallel with each other, An optical package unit configured; And
A preamplifier unit comprising a transfer preamplifier array preamplifier for amplifying and outputting an electric signal detected by the photodetector, an array preamplifier submount on which the array preamplifier is mounted, and a module housing; A wavelength multiplexing light receiving module. The method according to any one of claims 1 to 3,
Wherein the parallel light receptacle portion further includes a closed-loop located in the receptacle inner space on the front side of the hill-shaped refractive index lens, and a cylindrical sleeve disposed between the closed-loop and the receptacle, wherein the inner space of the receptacle, , The closed loop and the sleeve are all positioned so as to have the same central axis. The method according to any one of claims 1 to 3,
Wherein the coating portion is formed on one side of the glass block located at the rear end of the hill type refractive index lens and includes an anti-reflection film coating formed on a predetermined region where light is input from the hill type refractive index lens, And a reflection film coating formed on the remaining region except for the reflection film coating. The method according to claim 1,
The reflective mirror may include a planar reflection mirror coated with a reflective film on one surface thereof, or a silicon V-groove reflective mirror formed by etching a V-groove on a silicon semiconductor and a reflection film coated on the etched slope, . The method of claim 2,
Wherein the array photodetecting device is formed of a lens-integrated photodetecting device in which a lens for converting an optical signal of a parallel optical format into an optical signal of a focal optical format is formed integrally with the photodetecting device. The method according to any one of claims 1 to 3,
The metal optical bench is provided with an alignment groove for partially inserting and aligning the zigzag filter unit, the array lens, the array photodetecting device, and the reflection mirrors, respectively, or a seating portion formed of a protruding sloped surface or a multi- Wavelength multiplexed light receiving module. The method according to any one of claims 1 to 3,
Wherein the parallel light receptacle portion, the zigzag filter portion, the optical package portion, and the preamplifier portion are separately manufactured and are formed by mutually assembling them. The method of claim 9,
The parallel light receptacle unit includes a wavelength multiplexing light receiving module (not shown) assembled (formed) outwardly from the center of one surface of the module housing of the preamplifier unit, 12. The method of claim 10,
When the parallel light receptacle unit is assembled to one surface of the module housing of the preamplifier unit, the output electric signal value of the array photodetector element according to the light input through the parallel light receptacle unit is read and a maximum electric signal value is obtained And a wavelength multiplexing light receiving module assembled through an active alignment method for fixing the parallel optical receptacle portion.

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