KR101001277B1 - Wavelength division multiplexing optical module - Google Patents

Abstract

PURPOSE: A wavelength division multiplexing light module is provided to prevent the degradation of light combining efficiency, thereby realizing the miniaturization. CONSTITUTION: An optical signals of many wavelength is transmitted to an optical coupling block(110) through an optical fiber. Combination with an optical filter(200) for wavelength division of the optical block and light fiber is performed through a receptacle(114) of the light combining block. The light signal of an optical fiber core of optical cable passes through an input collimate lens surface(111') of the light combining block. The light signal is converted into a parallel light. Therefore, the light signal is transmitted without light loss in relatively far distance.

Description

Wavelength Division Multiplexing Optical Module

The present invention separates the optical signals of different wavelengths output from a single optical fiber and transmits them to the light receiving elements for each channel, and the wavelength division for integrating a plurality of optical signals from the light emitting elements of different wavelengths into one and transmitting them to the optical fiber. The present invention relates to a multiplexing optical module.

As the necessity of high-speed and high-capacity data transmission through optical communication increases, wavelength division multiplexing technology that uses independent characteristics of light without mutual interference between wavelengths, collects independent information on different wavelengths and sends them to one optical fiber. I am in the limelight.

Typical use of wavelength division multiplexing technology is to separate the optical signals of different wavelengths transmitted from the optical cable into individual wavelengths and input them to the optical cables for each channel or to receive different wavelengths of optical signals from the multiple channels of optical cables. It combines the signals into a single optical cable.

However, the technology of combining optical signals from light emitting devices having different wavelengths into one and combining them into a single optical cable and transmitting them or dividing the optical signals of different wavelengths transmitted from the optical cables into optical receivers for each wavelength is very difficult. Not much

The bidirectional optical transceiver module 10 shown in FIG. 1 is the simplest form of wavelength division multiplexing technology. As shown in FIG. 1, the conventional bidirectional optical transmission / reception module 10 positions the transmitter 11 and the receiver 12 at a right angle, and positions the optical filter 13 at 45 ° therebetween to selectively select a wavelength. It is a structure that transmits or reflects, separates and integrates optical signals of different wavelengths and transmits them to a single optical cable 14.

In addition, as shown in FIG. 2, when the light emitted from the light source 22 is made parallel using the collimated lens 21, parallel light is transmitted between the transmitter 22 and the optical cable 24 or the optical cable and the receiver 23. Even if the distance is far away, the light is hardly spread and the light coupling strength is not weakened, so the channel can be expanded.

In order to effectively transmit a larger amount of data, more wavelengths must be used, and thus, a wavelength gap between channels must be small. However, in the bidirectional transmission / reception module, since the angle of incidence of the filter 25 is 45 ° and the angle is relatively large, the difference in the transmission characteristics of the S and P polarization components of the light increases according to the wavelength, thereby increasing the wavelength gap between the transmission band and the reflection band. This has a wide disadvantage. Therefore, the conventional structure shown in FIGS. 1 to 2 has a limitation in the wavelength division multiplexing optical transmission / reception module including a plurality of channels such as a coarse wavelength division multiplexer (CWDM) having a narrow channel spacing between channels.

As a technique for transmitting multiple channels having narrow channel spacing between channels, a wavelength division multiplexing technique using a zigzag optical path has been proposed.

As shown in FIG. 3, the light output from the optical cable 31 is transferred using the collimating lens 32 and the reflector 33 to the reflecting surface 35 and a plurality of band pass filters 36. When incident on the optical block (34) consisting of the optical block (34), the light in the transmission wavelength band of the filter when entering the optical band pass filter 35 is transmitted through the filter and the light outside the band is reflected again to zigzag It is a technology in which an optical path is formed. Along the zigzag optical path, wavelengths are divided or combined. At this time, since the filter incidence angle of the optical signal traveling in the zigzag optical path is small, the wavelength interval is narrow and thus many channels can be accommodated.

However, such a structure has a problem in that the optical path is sensitively changed in the reference path due to the change in the thickness dimension of the optical block that creates the zigzag optical path as shown in FIG. In particular, if there is an error ΔT in the thickness dimension of the optical block, the farther the zigzag path, the more the error accumulates and deviates as much as ΔL from the reference light path, making it difficult to properly align the light.

In addition, if the actual light incidence path is distorted from the reference incidence path due to the assembly error occurring when assembling the zigzag block and the optical coupling block, the error accumulates as the light travels farther away, and thus the optical coupling efficiency falls off the reference optical path. There is this.

An object of the present invention for solving the above problems has a high optical coupling efficiency to minimize the optical loss in the wavelength division, significantly reduce the error caused by the assembly of the optical components constituting the optical transmission module, and very precise and It is to provide an optical module including an optical receiving module, an optical transmitting module and an optical transmitting and receiving module which are easily optically aligned, the structure thereof is simple, the manufacturing process is simple, the mass production is possible, and the manufacturing cost is low. It is to provide a bidirectional transmission optical transmission / reception module that can effectively divide the transmission wavelength and the reception wavelength even in the narrow band of 20nm wavelength interval.

The present invention provides an optical module using a single optical fiber, and the optical module according to the present invention means a wavelength division optical reception module, a wavelength division optical transmission module, or a bidirectional transmission wavelength division optical transmission and reception module.

In detail, the optical module according to the present invention is a wavelength-division light receiving module using a single optical fiber, and includes an optical fiber, an optical collimating lens, an optical filter, a refraction unit, an optical collimating lens, and an optical element as a light receiving element. do.

More specifically, the optical module according to the present invention comprises an input collimator lens (collimate len) for making the multi-wavelength light output from the optical fiber to parallel light; Two or more optically tilted at a predetermined angle with respect to the traveling direction of the parallel light by the input collimating lens, spaced apart from each other at a predetermined distance in the traveling direction of the parallel light, and reflecting and transmitting light for each wavelength. filter; A refraction unit provided corresponding to each of the optical filters and refracting the traveling direction of the reflected light reflected by the optical filter to be perpendicular to the traveling direction of the parallel light; An output collimator lens provided corresponding to each of the refracting portions and condensing the reflected light refracted by the refracting portion; And a light receiving element provided corresponding to each of the output collimating lenses and receiving the light condensed by the output collimating lens.

In detail, the optical module according to the present invention is a wavelength division optical transmission module using a single optical fiber, and includes an optical fiber, an optical collimating lens, an optical filter, a refraction unit, an optical collimating lens, and an optical element as a light emitting element. do.

More specifically, the optical module according to the present invention comprises at least two light emitting elements for generating transmission light of different wavelengths; An output collimator lens provided on an upper portion of the light emitting element corresponding to each of the light emitting elements and configured to convert light output from the light emitting element into parallel light; A refractive unit provided corresponding to each of the output collimating lenses and receiving the parallel light and outputting the parallel light to an optical filter at a predetermined angle; An optical filter provided corresponding to each of the refraction parts and configured to receive light refracted by the refraction part to reflect light refracted by the corresponding refraction part and transmit wavelengths in other regions; An input collimator lens for condensing the light reflected by the optical filter; And an optical fiber receiving the light collected by the input collimating lens, wherein the optical filter is disposed to be spaced apart from each other by a predetermined distance in a horizontal direction extending between the optical fiber and the input collimating lens, and the refraction unit emits light. The parallel light traveling in the vertical direction, which is an extension direction between the device and the output collimating lens, is input to the optical filter to be reflected in the horizontal direction by the optical filter, and is reflected and transmitted in the horizontal direction by the optical filter. And the integrated light is input to the single optical fiber by the single input collimating lens.

Specifically, the optical module according to the present invention is a wavelength division optical transmission and reception module using a single optical fiber, an optical element that is an optical fiber, an input collimating lens, an optical filter, a refraction unit, an output collimating lens and a light receiving element or a light emitting element; It is configured to include.

More specifically, the optical module according to the present invention comprises an input collimator lens (collimate len) for making the multi-wavelength light output from the optical fiber to parallel light; Two or more optically tilted at a predetermined angle with respect to the traveling direction of the parallel light by the input collimating lens, spaced apart from each other at a predetermined distance in the traveling direction of the parallel light, and reflecting and transmitting light for each wavelength. filter; A refraction unit provided corresponding to each of the optical filters and refracting the traveling direction of the reflected light reflected by the optical filter to be perpendicular to the traveling direction of the parallel light; An output collimator lens provided corresponding to each of the refracting portions and condensing the reflected light refracted by the refracting portion; And light-receiving elements for receiving the light focused by the output collimating lens, the output collimating lens, the refraction unit, the optical filter, and the input collimating lens. And two or more optical elements including a light emitting element for generating transmission light input to the optical fiber through a furnace.

In this case, when the optical module according to the present invention is a receiving module, the single optical device means a single light receiving device, and when the optical module according to the present invention is a transmitting module, the single optical device means a single light emitting device. In addition, when the optical module according to the present invention is an optical transmitting and receiving module, the two or more optical elements means at least one light receiving element and at least one light emitting element.

Among the optical modules according to the present invention, the refraction portion has a polygonal shape having at least a first refractive surface and a second refractive surface, based on an optical receiving module or an optical transmitting / receiving module, wherein the first refractive surface is between the optical fiber and the input collimating lens. The reflected light is a plane parallel to the horizontal direction in the extending direction, and the reflected light is incident on the first refractive surface and refracted according to Snell's law between air and the refracting portion, and the reflected light refracted by the first refractive surface is refracted and air at the second refractive surface. According to Snell's law of the liver, it is characterized in that it is output from the refracting portion so as to be perpendicular to the traveling direction of the parallel light.

Among the optical modules according to the present invention, the refracting portion has a polygonal shape having at least a first refractive surface and a second refractive surface, based on an optical transmission module, wherein the first refractive surface is a horizontal direction extending between the optical fiber and the input collimating lens. The parallel light (transmission parallel light) output from the output collimating lens is incident on the second refractive surface and refracted according to Snell's law between air and the refracting portion, and is refracted by the second refractive surface. The light (transmission parallel light) is refracted in accordance with Snell's law between the refracting portion and the air at the first refractive surface and reflected by the optical filter in the horizontal direction in the extension direction between the optical fiber and the input collimating lens. There is a characteristic to input into a filter.

The optical filter is characterized in that the optical filter is tilted so that the angle between the vertical axis of the optical filter and the traveling direction of the parallel light is 10 to 25 degrees.

The optical element is embedded in an optical element block which is a single transparent optical plastic injection molding, and the lens surface of the output collimating lens is a curved protruding surface of the optical element block.

The optical filter is characterized in that it is attached to the filter holder formed on the optical coupling block which is a single transparent optical plastic injection molding with an optical adhesive, the tilt angle of the optical filter is controlled by the inclination of the filter holder. In detail, the filter holder has an inclined surface that is inclined at 10 to 25 degrees with respect to the traveling direction of the parallel light.

The refraction unit is integral with the optical coupling block, and the optical coupling block includes a receptacle for fixing a ferrule coupled to the optical fiber, and the lens surface of the input collimating lens is spaced apart from the receptacle by a predetermined distance. And a protruding surface of the optical coupling block curvature perpendicular to the horizontal direction, the extension direction between the optical fiber and the input collimating lens.

The optical device block includes a guide hole, the optical coupling block comprises a guide pin, the optical device block and the optical coupling block is assembled by the coupling of the guide hole and the guide pin is characterized in that the optical alignment have. In addition, a lower portion of the optical coupling block is sealed by the optical device block by coupling the guide hole and the guide pin.

The optical module includes a cover block that is a single transparent optical plastic injection molding, the cover block includes a guide pin, the optical coupling block includes a guide hole, and the guide pin of the cover block and the optical coupling block The guide hole is coupled to the cover block and the optical coupling block is assembled, the cover block is characterized in that the top of the optical coupling block is sealed.

In the optical module according to the present invention, after the light output from the optical fiber is changed into parallel light, the light is sequentially input to the plurality of optical filters to sequentially divide the wavelength, and the parallel light is input to the optical filter by the refraction unit. The optical fiber has a stable optical path of horizontal (optical fiber) to vertical (receiving device) that is refracted in a direction perpendicular to the light receiving element, and the transmitted light output from the light emitting element formed at a position corresponding to the light receiving element The optical filter has a stable optical path of vertical (light emitting device) -horizontal (optical fiber) input to the optical filter and reflected from the optical filter to the optical fiber, thereby preventing deterioration of optical coupling efficiency due to manufacturing error and preventing optical module. Miniaturization and high integration are possible.

The optical module according to the present invention can easily manufacture an optical transmission module, an optical reception module or an optical transmission module easily by varying the configuration of the optical device.

The optical module according to the present invention has a structure in which the optical device is sealed in the optical plastic without being exposed to external air by the optical device block structure of the transparent optical plastic material in which the optical device is embedded therein, resulting in degradation due to contamination and oxidation of the optical device. To prevent.

In addition, since the lens surface of the output collimating lens is formed on the surface of the optical element block and the optical element is integrated inside the optical element block, the output collimating lens and the optical element have an integrated structure, so that the collimating lens can be attached and the optical element It is possible to prevent assembly errors that occur during assembly of attachments.

In addition, the optical device block can minimize the manufacturing tolerance by the configuration of the injection molded body, and by the stable light path configuration according to the characteristics of the present invention described above can also minimize the decrease in the optical coupling efficiency according to the manufacturing tolerances. It also has a very strong advantage in physical impact.

The optical module according to the present invention has a receptacle for fixing the optical fiber at a physically accurate position, a filter cradle in which each of the plurality of optical filters is located, and a refraction unit having an integrated structure formed in an optical coupling block made of a transparent optical plastic material. By fixing the optical fiber (ferrole) and attaching the optical filter to the filter holder using the optical adhesive, the splitting of the received light and the coupling of the transmitted light are performed, thereby assembling and attaching the optical elements. Errors can be prevented, and the position of the optical fiber (core) is strictly controlled by the receptacle, and the position and tilt angle of the optical filter are strictly controlled by the filter holder. have.

In addition, the optical coupling block can minimize the manufacturing tolerance by the injection molded configuration, and the reduction in the optical coupling efficiency due to the manufacturing tolerance by the stable optical path configuration according to the above-described features of the present invention can also be minimized. It also has a very strong advantage in physical impact.

The optical module according to the present invention comprises a transparent optical plastic injection molded to bond with each other, in detail, the cover block for sealing the upper portion of the optical coupling block, the optical coupling block and the lower portion of the optical coupling block Optical fiber, input collimating lens, optical filter, refraction, output collimating lens and optical element are precisely optically aligned by simple mechanical coupling between blocks of the optical element block, and have high optical coupling efficiency and very precise optical alignment. It is possible to mass-produce the aligned optical transmission / reception module in a short time and improve productivity.

Hereinafter, an optical module according to the present invention will be described in detail with reference to the accompanying drawings. The drawings introduced below are provided by way of example so that the spirit of the invention to those skilled in the art can fully convey. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. Also, throughout the specification, like reference numerals designate like elements.

At this time, if there is no other definition in the technical terms and scientific terms used, it has a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs, the gist of the present invention in the following description and the accompanying drawings Descriptions of well-known functions and configurations that may be unnecessarily blurred are omitted.

Figure 5 is a configuration diagram of an optical module according to the present invention, in detail Figure 5 (a) is an optical receiving module according to the present invention, Figure 5 (b) is an optical transmission module according to the present invention, Figure 5 (c) is 1 is a block diagram of an optical transmission module according to the present invention.

As shown in FIG. 5 (a), the light receiving module of the present invention uses a multi-wavelength diverging light (received light) output from a single optical fiber 1 by using an input collimating lens 111 to provide parallel light ( Reception parallel light), and the plurality of optical filters 200 sequentially receive the parallel light by the input collimating lens 111 to reflect and transmit light for each wavelength, and in the optical filter 200 The reflected reflected light is refracted by the refraction unit 113 to be perpendicular to the traveling direction of the parallel light, and is collected by the output collimating lens 121 and input to the light receiving element 122.

FIG. 5 (a) is a diagram illustrating a case of splitting light having multiple wavelengths output from the optical fiber 1, but as shown in FIG. 5 (b), the optical module according to the present invention is an optical transmission module. In this case, the light output from the one or more light emitting devices 123 that generate transmission light having different wavelengths may include the output collimating lens 121, the refraction unit 113, the optical filter 200, and the input collimating lens. It is integrated through the path of 111 and is input to the optical fiber 1.

In detail, as shown in FIG. 5B, the transmission divergence light (transmission light) generated by the light emitting element 123 is made into parallel light (transmission parallel light) by the output collimating lens 121, and the refraction portion is generated. And input to the optical filter 200 by the refraction unit 113 in the reverse direction of the reflection path of the optical filter 200.

The parallel light incident on the optical filter 200 is reflected in a direction perpendicular to the advancing direction of the parallel light (transmission parallel light), and the parallel light reflected by the optical filter 200 receives the input collimating lens 111. Is focused by the light source and input into the single optical fiber 1.

FIG. 5 (c) illustrates a case in which the optical module according to the present invention is an optical transmitting / receiving module including a light receiving element and a light emitting element. The light splitting and light emitting element of FIG. Based on the above, the integration of the light of FIG. 5 (b) is simultaneously performed.

Specifically, the optical transmission module according to the present invention is composed of at least one light receiving element 122 and at least one light emitting element 123, the input collimating lens 111, optical filter 200, refraction unit 113 ), The light having different wavelengths is split and integrated by the output collimating lens 121 and input / output through a single optical fiber.

Since the present invention performs input, output or input / output of light through a single optical fiber, it includes the single input collimating lens, and corresponds to the number (N> 1 natural number) of optical elements that are light receiving elements or light emitting elements. N output collimating lenses and N optical filters corresponding to the number of output collimating lenses.

Transmitted light having different wavelengths generated by one or more light emitting devices includes the output collimating lens 121, the refraction unit 113, the optical filter 200, and the single input collimating lens 111 corresponding to each of the light emitting devices. ), Which are integrated into a single optical fiber and input into a single optical fiber, and the received light having different wavelengths output from the single optical fiber 1 is an optical filter 200 corresponding to each of the single input collimating lens 111 and the light receiving element. ), Divided by the light receiving elements 122 by the refraction unit 113 and the output collimating lens 121, and input to each light receiving element 122.

As described above, in the optical module according to the present invention, after the light outputted from the optical fiber is changed into parallel light, the optical module is sequentially input to a plurality of optical filters to perform wavelength division, and the divided wavelength is transmitted to the optical filter by the refraction unit. A horizontal (optical fiber) -vertical (light receiving element) stable optical path refracted in a direction perpendicular to the parallel light input to the light receiving element, and the transmitted light output from the light emitting element formed at a position corresponding to the light receiving element The optical filter is input by the refraction unit to the optical filter and has a stable optical path of vertical (light emitting device) and horizontal (optical fiber) reflected from the optical filter and input to the optical fiber. It is prevented and has the advantage of miniaturization and high integration of the optical module.

Hereinafter, the optical module according to the present invention will be described with reference to the optical transmission / reception module according to the present invention, and the present invention will be described with reference to the optical division of the received light output from the optical fiber.

In the above-described optical transmitting and receiving module, if the optical elements are all light receiving elements, it is an example of the optical receiving module according to the present invention, and if the optical elements are all light emitting elements, it is obvious that the optical transmitting module according to the present invention is an example, and the division of light And it is obvious that the technical spirit of the present invention described on the basis of the optical transmission and reception module in which all of the light integration occurs in the optical reception module and the optical transmission module.

In addition, although the light receiving element and the light emitting element in the optical transmitting and receiving module are collectively referred to as an optical element, the technical spirit of the present invention is described in detail based on the light splitting of the received light, but the optical constitution of the present invention (input / output collimating lens, refractive unit It is apparent that light is processed in the reverse direction with respect to the light splitting in the optical filter), so that light integration of the transmitted light is performed. In the following drawings, the dotted line means the progress of light.

6 illustrates an example of an optical module according to the present invention, in which a path of an optical signal is precisely controlled, light loss is prevented, light coupling efficiency is increased, and manufacturing error and assembly error can be minimized.

As shown in FIG. 6, the optical module according to the present invention includes the optical device block 120, the optical coupling block 110, and the cover block 130. The optical device block 120, the optical coupling block 110, and the cover block 130 are integrally molded bodies injection molded from a transparent optical plastic material, respectively.

Except for intentional optical configurations, complex shapes including cavities, lens surfaces of input / output collimated lenses, and filter holders formed to propagate light into the air must be precisely embodied, and the light must This is because there should be no light loss when traveling through the refractive portion.

Examples of optical plastic materials of the optical coupling block 110, the optical element block 120, and the cover block 130 are poly-methylmethacrylate (PMMA), polycarbonate (PCMA) having a refractive index of 1.49 to 1.58, or COC Cyclic olefin copolymer) and the like, but the present invention is not limited by the optical plastic material.

The photonic device block 120 includes two or more photonic elements 124 embedded in the photonic device block 120, and the lens surface 121 ′ of the output collimating lens is formed on the photonic device block 120. It is a structure formed integrally on the surface.

In this case, as described above, when the two or more optical elements 124 are all light receiving elements, one example of the optical receiving module according to the present invention is provided. In the case of all of the light emitting elements, one example of the optical transmitting module according to the present invention is provided. In the case of the light receiving element and the light emitting element, an example of an optical transmitting and receiving module according to the present invention is provided.

The optical device 124 is positioned below the lens surface 121 ′ of the output collimating lens formed as a curved curved surface on the surface of the optical device block 120. The optical device 124 is positioned to correspond to each of the two or more lens surfaces 121 'formed to be spaced apart from each other by the predetermined distance, and the optical device 124 is positioned at a focal plane of the lens surface 121'. desirable.

As described above, by the horizontal (optical fiber) -vertical (light receiving element) stable optical path, the output collimating lens and the optical element 124 have a high optical coupling efficiency without being tilted at a specific angle.

As illustrated in FIG. 6, the lens surfaces 121 ′ of two or more output collimating lenses formed to be spaced apart from each other by a predetermined distance are integrally formed in the optical element block 120.

As a modified example of the optical device block 120, as shown in FIG. 7, a step difference between the lens surface (lens surface of the output collimating lens) and the edge region of the optical device block formed on the surface of the optical device block 120 may be obtained. It is preferable to form H) to form the step to protect the lens surface from handling including inter-block coupling and the like.

Preferably, recessed grooves are formed in one region of the surface of the optical device block 120 in a direction in which light is received, and output collimated lens surfaces 121 ′ spaced apart from each other by a predetermined distance are formed in the recessed grooves.

6 to 7, the optical coupling block 110 is a receptacle 114 for fixing the optical fiber in a physically accurate position, in detail, by physically fixing the ferrule of the optical fiber cable to adjust the output position of the received light In the receptacle 114 for precise control, the input collimating lens 111 to make the divergent light output from the optical fiber into parallel light, the filter holder 112 to which the optical filter 200 is attached, and the optical filter 200 The refraction unit 113 is formed to integrally receive light (reflected light) having a reflected wavelength and refract light in a vertical direction based on the traveling direction of the parallel light by the input collimating lens 111.

The receptacle 114 is preferably in the shape of an attachment groove physically coupled to the ferrule of the optical fiber cable to fix the ferrule, and the lens surface 111 ′ of the input collimating lens 111 is predetermined with the receptacle 114. A protruding surface 111 ′ of the optical coupling block that is curved at a distance and perpendicular to the traveling direction of the multi-wavelength light output from the optical fiber fixed by the receptacle 114.

As shown in FIG. 6, the input collimating lens 111 is made of a material forming the optical coupling block 110, and a lens surface spaced apart from the receptacle 114 at a rear end of the receptacle 114 by a predetermined distance ( One area of the optical coupling block 110 having 111 ') becomes an input collimating lens.

The received light output from the optical fiber fixed at the correct position by the receptacle 114 becomes parallel light by the input collimating lens. The optical coupling block 110 has a cavity in a horizontal direction formed in a rearward direction of the input collimating lens, that is, a stable optical path of the horizontal (optical fiber) -vertical (light receiving element) of the present invention. Thus, the parallel light propagates in the air other than the intentional optical element, and the filter holder 112 is formed so that the optical filters may be spaced apart from each other by a predetermined distance in the traveling direction of the parallel light.

6 to 7 illustrate an example of a saw-type filter holder 112 having two surfaces inclined at a predetermined angle, but the optical filter 200 can be easily attached without an error in an attachment position. It can be any shape if it is mounted.

An optical filter 200 for transmitting and reflecting light for each wavelength is attached to each of the filter holders using an optical adhesive, so that parallel light generated by the input collimating lens travels in the air in a horizontal direction, and a plurality of optical filters 200 are provided. Are sequentially entered.

The refraction unit 113 receives the light reflected by the optical filter 200 (reflected light) and refracts the reflected light to be perpendicular to the traveling direction of the parallel light, thereby providing the optical filter 200 with each other. It is formed on the lower portion of the optical filter 200 to correspond.

The refracting portion 113 has a polygonal shape having at least a first refractive surface and a second refractive surface, and the first refractive surface is a surface parallel to the traveling direction of the parallel light by the input collimating lens, and the reflected light is the first refractive surface. And reflected light refracted according to Snell's law between the air and the refracting portion and refracted at the first refractive surface are re-reflected according to Snell's law between the refracting portion and the air at the second refractive surface to be perpendicular to the direction of travel of the parallel light. It is output from the refraction unit 113.

As described above, the optical coupling block 110 has the refraction in which the receptacle 114, the input collimating lens 111, the cavity, the filter holder 112, and the first refractive surface and the second refractive surface are formed. The part 113 is integrally formed.

The cover block 130 is positioned above the optical coupling block 110 to seal the upper portion of the optical coupling block 110.

The optical module according to the present invention includes an optical coupling block 110 to which the optical filter 200 is attached, and an optical element block 120 positioned below the optical coupling block 110 and sealing the lower portion of the optical coupling block 110. And a cover block 130 positioned above the optical coupling block 110 and sealing an upper portion of the optical coupling block 110, wherein the optical element block 120, the optical coupling block 110, and As the cover block 130 is physically coupled, optical alignment and optical coupling of the entire module are performed.

The optical transmission / reception module of the present invention will be described in more detail with reference to FIG. 6 in terms of division of received light.

Optical signals of various wavelengths are transmitted to the optical coupling block 110 to which the optical filter 200 is attached through the optical fiber. At this time, the coupling between the optical fiber and the optical filter 200 for wavelength division of the optical coupling block 110 is made through the receptacle 114 of the optical coupling block. More specifically, the receptacle 114 holds the position of the outer diameter of the precise optical connector ferrule to match the position of the optical fiber to which the optical signal is transmitted (actually the optical fiber core of the optical cable) to suppress optical loss. To be correctly coupled through the receptacle 114.

The optical signal from the optical fiber core end of the optical cable fixed by the receptacle 114 diverges with a constant angle in the optical path indicated by dotted lines in FIG. 6. The diverging light passes through the input collimating lens surface 111 ′ of the optical coupling block 110 and changes into parallel light. Parallel light can transmit a relatively long distance with little light loss since little light is dispersed with respect to the traveling distance.

The optical signal of various wavelengths passing through the input collimating lens 111 and traveling in parallel light passes through the optical filter 200 in which transmission and reflection occur for each wavelength.

Typically, optical filters are made by coating a multilayer thin film on a glass substrate of constant thickness. By controlling the thickness of the material or the thin film of the thin film to control the amount of reflection and transmission according to the wavelength.

In order to transmit a large amount of data, the distance between the wavelengths of transmission and reflection must be narrowed so that light of many wavelengths can be used. Typically, the wavelength spacing used in low density wavelength division multiplexing (CWDM) systems is 20 nm. Therefore, the optical filter of the present invention should also be designed and manufactured in accordance with these characteristics.

FIG. 8 is a diagram showing transmittances of S-polarized light and P-polarized light components of a filter having an incident angle of 20 degrees (FIG. 8 (b)) and 45 degrees (FIG. 8 (a)).

As the angle of incidence of the optical filter increases, the difference in the transmission characteristics according to the wavelengths of the S-polarized component and the P-polarized component included in the light increases, making it difficult to coat the optical filter with a narrow wavelength interval between the transmission band and the reflection band.

In the case of the optical filter having an angle of incidence of 45 °, which is generally used in the bidirectional transmission / reception module, it is impossible to filter the wavelength interval to about 20 nm as in CWDM. Therefore, in order to fabricate an optical filter with a wavelength gap as small as 20 nm, such as CWDM, the incident angle should be as small as 20 degrees or less.

In order to easily attach the optical filter to the optical coupling block without errors, a filter holder is implemented on the optical coupling block. The tilt angle of the optical filter 200 is controlled by the inclination of the filter holder 112 of the optical coupling block 110, so that the position and the incident angle of the optical filter can be precisely and accurately controlled.

FIG. 9 is a diagram illustrating optical path control according to wavelengths performed by the optical filter 200 and the refraction unit 113 of the optical coupling block 110.

The light reflected by the optical filter 200 is incident on the primary refractive surface 113A of the refracting portion 113 of the optical coupling block 110 and then passes through the secondary refractive surface 113B through the optical coupling block material. To proceed. At this time, the light passing through the primary refraction surface 113A and the secondary refraction surface 113B is changed by the refraction phenomenon to change the direction of the light propagation path.

The refraction of the optical path follows Snell's law as we know it. The refraction (progression) path of light is determined by Fermat's principle that light passing through two media having different refractive indices n ₁ and n ₂ takes a path that can travel in the shortest time. Snell's law regarding the refractive indices n ₁ and n ₂ , the incident angle θ ₁ and the refractive angle θ ₂ is as follows.

n ₁ sinθ ₁ = n ₂ sinθ ₂

As shown in FIG. 9, the light reflected by the optical filter 200 is incident at an angle β into the primary refractive surface 113A of the optical coupling block 110 having the refractive index n in air. At this time, the optical path is refracted at an angle γ by Snell's law.

γ = sin ^-1 (1 / n sin β)

In addition, as shown in FIG. 9, the light traveling in the optical coupling block 110 having the refractive index n is emitted from the secondary refractive surface 113B at an angle of δ into the air in the optical path at an angle ε by Snell's law. Is refracted.

ε = sin ^-1 (n sin δ)

Based on Snell's law described above, the angle between the primary refracting surface 113A and the secondary refracting surface 113B of the optical coupling block 110 is the direction of the optical coupling block and the direction of diverging from the optical fiber to parallel light ( The angle between the optical paths passing through the secondary refractive surface 113B of 110 is 90 degrees.

This allows the direction of the N optical paths divided through the optical coupling block 110 to be in the same vertical direction as the connection direction of the optical fiber, so that the light receiving element 122 and the surface emitting laser diode such as the photodiode (Vertical Cavity Surface) The light emitting device 123, such as an Emitting Laser, can be positioned on the same horizontal plane to have a stable structure.

The specific wavelength suitable for the characteristics of the optical filter 200 is reflected and the path is changed to pass through the primary refractive surface 113A and the secondary refractive surface 113B to enter the optical device 124, and the optical signal of the remaining wavelength band is optical It passes through the filter 200.

The optical signal transmitted through the optical filter 200 without being reflected is transmitted through the optical filter 200 to the air.

The optical transmission module according to the present invention has a structure in which an optical path control unit including the optical filter 200 and the refraction unit 113 shown in FIG. 9 is sequentially formed in the direction of diverging from the optical fiber and traveling in parallel light. .

When the optical path controller is formed again behind the optical path controller according to the wavelength and reflects a part of the transmitted wavelength bands without being reflected by the previous optical filter, the optical path controller of the same wavelength selected by the aforementioned method of reflection refraction and transmission is formed. Only the optical signal is separated and the rest is transmitted. In this way, the optical path control unit according to the wavelength can be extended up to N, thereby separating the N wavelengths input through the optical fiber.

The light transmitted through the secondary refracting surface 113B of the optical coupling block 110 travels in the air and passes through the output collimating lens surface 121 'of the optical element block 120 and changes from parallel light to focus light. Will come into focus.

By placing a light-receiving element including a photodiode in a focus region where light is collected at one point, the optical signal starting from the optical fiber is converted into an electrical signal by photoelectric conversion.

As described above, when the light emitting device including the laser diode is formed at the position of the light receiving device, the light path is exactly reversed to the above-described light path.

In detail, an optical signal emitted from a light emitting device including a vertical cavity surface emitting laser (LED) operated by a predetermined electrical signal may cause the output collimating lens surface 121 'of the optical device block 120 to face. As it passes through, it turns into parallel light.

The light converted into parallel light 502 while passing through the output collimating lens surface 121 ′ of the optical element block 120 may be configured to convert the secondary refractive surface 113B and the primary refractive surface 113A of the optical coupling block 110. As it passes, the path is changed by the above-described refraction principle to enter the optical filter 200 of the optical coupling block 110, and is reflected back from the optical filter 200 to travel in the optical fiber direction. A plurality of optical signals having different wavelengths reflected from the optical filter 200 of the optical coupling block 110 including the plurality of optical path controllers are combined into one to travel toward the optical fiber.

The multi-wavelength optical signal traveling in the optical fiber direction changes from parallel light to focus light passing through the input collimating lens surface 111 'in the optical coupling block 110, and the multiple optical signals collected at one point are the core of the optical fiber. Is inputted and transmitted.

As described above, since the path of the optical signal input from the optical fiber to the light receiving element is the same as the path of the optical signal input from the light emitting element to the optical fiber, the present invention is implemented as an optical transmission module when the optical element is composed of only the light emitting element. If the device is composed of only a light receiving element is implemented as an optical transmission module, if the optical element is at least one light receiving element and at least one light emitting element is implemented as an optical transmission module.

10 is a partial cross-sectional perspective view of the optical coupling block 110. As shown in FIG. 10, the optical coupling block 110 is positioned in the filter holder 112 of the optical coupling block which is integrally ejected. And attach using a heat or ultraviolet curing adhesive.

The heat or ultraviolet curing adhesive may be an epoxy-based having a heat or ultraviolet curing functional group.

As described above, the receptacle 114, the input collimating lens 111, the filter holder 112, and the refraction unit 113 other than the optical filter 200 attached to the filter holder 112 in FIG. It is an integral part.

11 is a perspective view of an optical device block 120, and FIG. 12 is a cross-sectional view of the optical device block 120.

As shown in FIG. 11, the optical device block 120 according to the present invention includes two or more optical devices including one or more light receiving devices and one or more light emitting devices in the optical device block 120. Preferably, recessed grooves 125 are formed in one region of the surface of the device block 120 in the direction in which light is received, and curved recessed surfaces spaced apart from each other by a predetermined distance are formed in the recessed grooves 125 to output collimation. A lens surface 121 'is formed.

The light reflected by the optical filter 200 and refracted by the refraction unit 113 passes through the output collimating lens surface 121 ′ and turns into focus light, and is generated in an optical device (light emitting device) 124. The divergent light passes through the output collimating lens surface 121 'and changes parallel light. The output collimating lens surface 121 ′ is formed on a surface of the optical device block 120, so that the output collimating lens is integrally provided with the optical device block 120. The output collimating lens is made of a material forming the optical element block 120, and an area of the optical element block 110 between the optical element 124 and the output collimating lens surface 121 ′ is output. It becomes a collimated lens.

In this case, since the light is changed into focus light or parallel light by the curvature interface between two materials having different refractive indices (air and optical plastic material), the input collimating lens and the output collimating lens will be described in detail. As the lens surface 111 'of the input collimating lens and the lens surface 121' of the output collimating are defined, it is obvious that the input collimating lens and the output collimating lens are predefined.

12 is a cross-sectional view of the optical device block 120 in a state in which the light emitting device 124 or the light receiving device 124 is electrically connected to a pad of the lead frame 126 patterned as shown in FIG. 12. It may be embedded in the optical device block, and an amplifier for amplifying an electrical signal generated from the optical device may be included together.

For example, the electronic devices including the optical device may be die attached and connected by wire bonding between the optical device and the lead frame lead or between the optical device and the electronic device, and then surround the device by using an optical transparent plastic injection molding. It can be manufactured by injection molding. In this case, as shown in FIG. 11, the lead frame 126 is preferably connected to an external connection terminal 127 electrically connected to an external circuit.

FIG. 13 is a view illustrating optical alignment and coupling by physical assembly of the optical device block 120, the optical coupling block 110, and the cover block 130. The optical device block 120, the optical coupling block ( It is a structure that is fastened and sealed between blocks by coupling between the guide hole and the guide pin between the 110 and the cover block 130.

As shown in the example of FIG. 13, the optical device block 120 includes a guide hole 128 integrally, and the optical coupling block 110 includes a guide pin 116 integrally. 120 and the optical coupling block 110 are assembled by the coupling of the guide hole 128 and the guide pin 116 to output the collimating lens surface of the optical element block 120 and the optical coupling block 110. The optical path control unit including the optical filter 200 and the refraction unit 113 of FIG. 1 is optically aligned, and the lower portion of the optical coupling block 110 is sealed.

In addition, the cover block 130 which is a single transparent optical plastic injection molded body includes a guide pin 131 integrally, the optical coupling block 110 includes a guide hole 115 integrally, the cover block 130 Guide pin 131 of the) and the guide hole 115 of the optical coupling block 110 is coupled to the cover block 130 and the optical coupling block 110 is assembled by the cover block 130 The upper portion of the light coupling block 110 is sealed.

When the guide pin and the guide hole are fastened, a predetermined adhesive may be applied to the bonding surface when the guide pin or the guide hole is integrally injected for each block to be bonded to each other.

The optical module according to the present invention described above with reference to FIGS. 5 to 13 has a structure in which the optical device is sealed in the optical plastic without being exposed to external air by the optical device block structure of the transparent optical plastic material in which the optical device is embedded. This prevents deterioration due to contamination and oxidation of the optical device.

In addition, since the lens surface of the output collimating lens is formed on the surface of the optical element block, and the optical element is combined at the focus of the lens surface corresponding to each of the lens surfaces within the optical element block, the output collimating lens and the optical element are integrated. It is possible to prevent assembly errors caused during assembly of the collimated lens, the optical element, and the like.

In addition, the optical device block can minimize the manufacturing tolerance by the configuration of the injection molded body, and by the stable light path configuration according to the characteristics of the present invention described above can also minimize the decrease in the optical coupling efficiency according to the manufacturing tolerances. It also has a very strong advantage in physical impact.

The optical module according to the present invention has a receptacle for fixing the optical fiber at a physically accurate position, a filter cradle in which each of the plurality of optical filters is located, and a refraction unit having an integrated structure formed in an optical coupling block made of a transparent optical plastic material. By fixing the optical fiber (ferrole) and attaching the optical filter to the filter holder using the optical adhesive, the splitting of the received light and the coupling of the transmitted light are performed, thereby assembling and attaching the optical elements. Errors can be prevented, and the position of the optical fiber (core) is strictly controlled by the receptacle, and the position and tilt angle of the optical filter are strictly controlled by the filter holder. have.

In addition, the optical coupling block may minimize the manufacturing tolerance by the injection molded configuration, and by the stable optical path configuration according to the above-described features of the present invention it is also possible to minimize the decrease in the optical coupling efficiency according to the manufacturing tolerance. It also has a very strong advantage in physical impact.

The optical module according to the present invention is a single transparent optical plastic injection molded body, the cover block for sealing the upper portion of the optical coupling block, the simple block between the optical coupling block and the optical element block sealing the lower portion of the optical coupling block The optical coupling of optical fiber, input collimating lens, optical filter, refracting part, output collimating lens and optical element by mechanical coupling is precise. And it has high optical coupling efficiency and very precise optical alignment. As it can be mass-produced in a short time, there is an advantage to improve the productivity (yield).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Those skilled in the art will recognize that many modifications and variations are possible in light of the above teachings.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and all the things that are equivalent to or equivalent to the scope of the claims as well as the claims to be described later belong to the scope of the present invention. will be.

1 is an example of a conventional optical module,

2 is another example of a conventional optical module,

3 is another example of a conventional optical module,

Figure 4 is an example showing the optical path error according to the manufacturing error in the conventional optical module,

Figure 5 is an example showing the configuration of a wavelength division optical module according to the present invention, in detail Figure 5 (a) is an optical receiving module according to the present invention, Figure 5 (b) is an optical transmission module according to the present invention 5 (c) is a configuration diagram of an optical transmission and reception module according to the present invention,

6 is another example showing the configuration of an optical module according to the present invention;

7 is another example showing the configuration of an optical module according to the present invention,

8 is a diagram showing transmittances of S and P polarization components of an optical filter having an incident angle of 20 degrees (FIG. 8 (b)) and 45 degrees (FIG. 8 (a)), respectively.

9 is an example illustrating optical path control according to a wavelength performed by an optical filter and a refraction unit in an optical coupling block in an optical module according to the present invention.

10 is an example of a partial cross-sectional perspective view of an optical coupling block in an optical module according to the present invention;

11 is a perspective view of an optical device block in an optical module according to the present invention;

12 is a cross-sectional view of an optical device block in an optical module according to the present invention;

FIG. 13 is an example illustrating optical alignment and coupling by physical assembly of an optical device block, an optical coupling block, and a cover block in the optical module according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: optical fiber 111: input collimated lens

111 ': Input collimating lens surface 200: Optical optical filter

113: refractive portion 113A: primary refractive surface

113B: Secondary refractive surface 121 ': Output collimated lens surface

122: light receiving element 123: light emitting element

124: optical element 120: optical element block

110: optical coupling block 130: cover block

114: Receptacle 112: Filter Holder

125: recessed grooves 128: optical element guide hole

115: optical coupling guide hole 116: optical coupling guide pin

131: cover guide pin

Claims (12)

Wavelength split optical module using a single optical fiber, Optical fiber, an input collimating lens, an optical filter, a refraction portion, an output collimating lens, and an optical element which is a light receiving element, An input collimate lens for converting the multi-wavelength light output from the optical fiber into parallel light; Two or more optically tilted at a predetermined angle with respect to the traveling direction of the parallel light by the input collimating lens, spaced apart from each other at a predetermined distance in the traveling direction of the parallel light, and reflecting and transmitting light for each wavelength. filter; A refraction unit provided corresponding to each of the optical filters and refracting the traveling direction of the reflected light reflected by the optical filter to be perpendicular to the traveling direction of the parallel light; An output collimator lens provided corresponding to each of the refracting portions and condensing the reflected light refracted by the refracting portion; And A light receiving element provided corresponding to each of the output collimating lenses and receiving the light focused by the output collimating lens; Wavelength division optical module comprising a. Wavelength split optical module using a single optical fiber, Optical fiber, an input collimating lens, an optical filter, a refraction portion, an output collimating lens, and an optical element that is a light emitting element, Two or more light emitting devices for generating transmission light having different wavelengths; An output collimator lens provided on an upper portion of the light emitting element corresponding to each of the light emitting elements and configured to convert light output from the light emitting element into parallel light; A refractive unit provided corresponding to each of the output collimating lenses and receiving the parallel light and outputting the parallel light to an optical filter at a predetermined angle; An optical filter provided corresponding to each of the refraction parts and configured to receive light refracted by the refraction part to reflect light refracted by the corresponding refraction part and transmit wavelengths in other regions; An input collimator lens for condensing the light reflected by the optical filter; And An optical fiber for receiving the light collected by the input collimating lens; Including; The optical filter is disposed to be spaced apart from each other by a predetermined distance in a horizontal direction extending in the extending direction between the optical fiber and the input collimating lens, and the refracting portion is the parallel light traveling in a vertical direction in the extending direction between the light emitting element and the output collimating lens. Is inputted to the optical filter to be reflected in the horizontal direction by the optical filter, and the light reflected and transmitted in the horizontal direction by the optical filter is integrated into the single optical fiber by the single input collimating lens. Wavelength division optical module characterized in that the input. Wavelength split optical module using a single optical fiber, It comprises an optical fiber, an input collimating lens, an optical filter, a refractive unit, an output collimating lens, an optical element that is a light receiving element and an optical element that is a light emitting element, An input collimate lens for converting the multi-wavelength light output from the optical fiber into parallel light; Two or more optically tilted at a predetermined angle with respect to the traveling direction of the parallel light by the input collimating lens, spaced apart from each other at a predetermined distance in the traveling direction of the parallel light, and reflecting and transmitting light for each wavelength. filter; A refraction unit provided corresponding to each of the optical filters and refracting the traveling direction of the reflected light reflected by the optical filter to be perpendicular to the traveling direction of the parallel light; An output collimator lens provided corresponding to each of the refracting portions and condensing the reflected light refracted by the refracting portion; And Light paths of the light receiving element, the output collimating lens, the refraction unit, the optical filter, and the input collimating lens, which are provided corresponding to each of the output collimating lenses and receive the light collected by the output collimating lens. And at least two optical elements comprising a light emitting element for generating transmission light input to the optical fiber through the wavelength division optical module. The method according to claim 1 or 3, The refracting portion has a polygonal shape having at least a first refractive surface and a second refractive surface, wherein the first refractive surface is a plane parallel to a horizontal direction extending in the extending direction between the optical fiber and the input collimating lens, and the reflected light is directed to the first refractive surface. The incident light is refracted according to Snell's law between the air and the refracting portion, and the reflected light refracted at the first refractive surface is re-reflected according to Snell's law between the refracting portion and the air at the second refractive surface to be perpendicular to the direction of travel of the parallel light. Wavelength division optical module, characterized in that output from the refraction unit. The method according to any one of claims 1 to 3, And the optical filter is tilted such that an angle between a vertical axis of the optical filter and a traveling direction of the parallel light becomes 10 to 25 degrees. The method according to any one of claims 1 to 3, And the optical element is embedded in an optical element block which is a single transparent optical plastic injection molding, and the lens surface of the output collimating lens is a curved protruding surface of the optical element block. The method of claim 6, The optical filter is a wavelength division optical module, characterized in that attached to the filter holder formed on the optical coupling block that is a single transparent optical plastic injection molding. The method of claim 7, wherein And a tilt angle of the optical filter is controlled by the inclination of the filter holder. The method of claim 7, wherein And the refraction unit is integral with the optical coupling block. The method of claim 9, The optical coupling block includes a receptacle for fixing a ferrule that couples with the optical fiber, and a lens surface of the input collimating lens is spaced apart from the receptacle by a predetermined distance in a horizontal direction extending in an extension direction between the optical fiber and the input collimating lens. A wavelength division optical module, characterized in that the projecting surface of the optical coupling block curvature perpendicular to the. The method of claim 7, wherein The optical device block includes a guide hole, the optical coupling block includes a guide pin, and the optical device block and the optical coupling block are assembled and optically aligned by combining the guide hole and the guide pin and the optical The wavelength division optical module, characterized in that the coupling block is sealed below. The method of claim 11, The optical module includes a cover block that is a single transparent optical plastic injection molding, the cover block includes a guide pin, the optical coupling block includes a guide hole, and the guide pin of the cover block and the optical coupling block The guide hole is coupled to the cover block and the optical coupling block is assembled, the wavelength division optical module, characterized in that the top of the optical coupling block is sealed by the cover block.

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