KR20030064517A - Bi-directional tranceiver module - Google Patents

Abstract

PURPOSE: A bidirectional optical transmitting module is provided to improve an optical signal transfer characteristics by enabling all transmission or all reflection without regard to polarization as to a specific wavelength. CONSTITUTION: A light emitter(110) emits a light of an established wavelength. The first optical fiber(120) transfers the light of the wavelength emitted from the light emitter. A dual light collimator(130) comprises a GRIN lens outputting an incident light as a parallel light by being combined to an output part of the first optical fiber. A flat-convex lens(140) is formed with a semispherical lens having coated with a filter which reflects a light of an established wavelength totally and transmits light of other wavelength among the parallel light passing through the GRIN lens. A photo detector(150) detects the light passing through the flat-convex lens. And the second optical fiber(160) transfers the light reflected from the flat-convex lens to another node, and emits the light transferred from the node to the dual light collimator, by being combined to the GRIN lens.

Description

Bidirectional Optical Transmission Module {BI-DIRECTIONAL TRANCEIVER MODULE}

TECHNICAL FIELD The present invention relates to optical communication components, and more particularly, to a bidirectional optical transmission module applied to an optical communication system.

In general, an optical transceiver module is an apparatus for transmitting and receiving an optical signal through an optical fiber, and a one-directional or duplex optical transmission module in which transmission and reception of an optical signal are performed through different optical fibers, and an optical signal. There is a bi-directional optical transmission module in which the transmission and reception of signals is performed in one optical fiber.

The unidirectional optical transmission module does not need a separate wavelength multiplexing function because transmission and reception of the optical signal are performed through different optical fibers, but the bidirectional optical transmission module receives optical signals of different wavelengths transmitted through one optical fiber. Wavelength multiplexing is essential for combining or branching.

1 is a block diagram illustrating a bidirectional optical transmission module according to an exemplary embodiment of the present invention, which is disclosed in US Patent No. 6,106,160, "Optical transmitting and receiving module," filed by Kimihiro Kikuchi et al.

As shown in FIG. 1, the bidirectional optical transmission module according to an exemplary embodiment includes a laser diode 11, a first lens 12, a first optical demultiplexer 13, a second lens 14, and an optical fiber. 21, the second optical demultiplexer 22, the third lens 15, the first photodiode 16, the fourth lens 17 and the second photodiode 18. As shown in FIG.

The light of wavelength λ ₁ emitted from the laser diode 11 is converted into a parallel light state while passing through the first lens 12 and passes through the first optical demultiplex filter 13. Subsequently, the light is incident on the end of the optical fiber 21 by the second lens 14 and transmitted through the optical fiber 21. Meanwhile, the light having the wavelengths λ ₁ and λ ₂ transmitted through the optical fiber 21 is converted into a parallel light state by the second lens 14 and reflected by the first optical demultiplex filter 13. Subsequently, light having a wavelength λ ₂ of the light is reflected by the second optical demultiplexer 22 and passes through the third lens 15, and then is received by the first photodiode 16. On the other hand, the light having the wavelength λ ₁ of the light passes through the fourth lens 17 and is received by the second photodiode 18.

FIG. 2 is a block diagram illustrating a bidirectional optical transmission module according to another exemplary embodiment, and has been disclosed in US Patent No. 6,282,000, "Optical transmitting and receiving module" by Kimihiro Kikuchi et al.

As shown in FIG. 2, the bidirectional optical transmission module according to another exemplary embodiment includes a laser diode 6, a first lens 7, an inverse multiple filter 5, a second lens 13, and an optical fiber 12. , A reflection mirror 15, a third lens 10, and a photodiode 9, and unlike the embodiment shown in FIG. 1, the direction of the laser diode 6 and the photodiode 9 is an optical fiber ( Parallel to the direction of 12, for this purpose is further provided with the reflection mirror 15 is characterized by.

The light of wavelength λ ₁ emitted from the laser diode 6 is converted into parallel light while passing through the first lens 7, passes through the demultiplex filter 5, and then the optical fiber 12 by the second lens 13. And is transmitted through the optical fiber 12. On the other hand, the light having the wavelength λ ₂ transmitted through the optical fiber 12 is converted into a parallel light state by the second lens 13 and reflected by the demultiplex filter 5. Subsequently, the light having the wavelength λ ₂ is reflected by the reflection mirror 15, passes through the third lens 10, and is then received by the photodiode 9.

However, since the above-described conventional bidirectional light transmission modules have an angle of incidence of 45 degrees, which is incident on the light emitted from the laser diode and the demultiplex filter, the difference between the reflection and transmittance of the TE polarized light and the reflection and transmission of the TM polarized light is λ _1. Not only is the amount of light emitted from the laser diode having a wavelength of less than the optical fiber being input to the optical fiber, but also the light of the wavelength λ ₂ input from another node is input to the laser diode to shorten the lifetime of the laser diode or reduce the transmission characteristics. There was this.

In order to solve the problems described above, an object of the present invention is to minimize the angle between the filter and the incident light, thereby allowing a total amount of transmission or reflection of the entire wavelength regardless of the polarization direction, thereby improving the optical signal transmission characteristic. To provide.

Another object of the present invention is to provide a bidirectional optical transmission module capable of minimizing crosstalk loss along the polarization direction of light input to a filter.

Further, another object of the present invention is to provide a bidirectional optical transmission module that is easy to align the optical axis required to make divergent light into parallel light or to incident light into an optical fiber.

In addition, another object of the present invention to provide a bidirectional optical transmission module of the Small Form Fact form.

In order to achieve the above object, the present invention provides a light transmission module comprising: a light emitter for emitting light of a predetermined wavelength; A first optical fiber for transmitting light of a wavelength emitted from the light emitter; A dual optical collimator having a GRIN lens to which the output terminal of the first optical fiber is bonded to output the input light as parallel light; A planar-convex lens composed of a hemispherical lens having a filter-coated plane which totally reflects light of a predetermined wavelength among the parallel light passing through the GRIN lens of the dual optical collimator and transmits light of another wavelength; A light receiver for receiving light having a wavelength passing through the plane-convex lens; And an input end coupled to the GRIN lens, the second optical fiber receiving light of a wavelength reflected from the planar-convex lens and transmitting the light to another node and outputting the light of the wavelength transmitted from another node to the dual optical collimator. A bidirectional optical transmission module is provided.

1 is a block diagram showing a bidirectional optical transmission module according to a conventional embodiment;

2 is a block diagram showing a bidirectional optical transmission module according to another conventional embodiment;

3 is a schematic view showing a structure of a thin film multi coating,

4 is a graph showing the degree of reflection of TE polarized light and TM polarized light for the uncoated single medium and the highly reflective coated single medium,

5 is a block diagram showing a bidirectional optical transmission module according to a first embodiment of the present invention,

6 is a graph showing transmission characteristics for a specific wavelength of a planar-convex lens and a planar filter according to an aspect of the present invention;

7 is a block diagram showing a bidirectional optical transmission module according to a second embodiment of the present invention;

8 is a cross-sectional view of a bidirectional optical transmission module manufactured according to the first embodiment of the present invention;

9 is a cross-sectional view of a bidirectional optical transmission module fabricated in accordance with a second preferred embodiment of the present invention.

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

110: light emitter 120: first optical fiber

130: dual optical collimator 140: flat-convex lens

150: light receiver 160: second optical fiber

170: flat filter

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

Prior to describing a specific technical configuration of the present invention, a theoretical background that can support the technical gist of the present invention will be described with reference to FIGS. 3 and 4.

3 is a schematic view showing a structure of a thin film multi coating. As shown in FIG. 3, the Thin Film Multi Coating alternately laminates a medium having a high refractive index and a material having a low refractive index. As shown in <Equation 1> and <Equation 2>, the reflectance and TM of TE polarized light are shown. The reflectance of the polarized light has different properties, especially depending on the refractive index and the angle of incidence of the coating medium.

Where R _TE is the reflectance of the TE polarized wave, n _A is the refractive index of the incident portion, θ _A is the angle of incidence from the incident portion into the film medium, n _H is the refractive index of the higher refractive index of the coated layer, and θ _H is the coated layer Θ _L is the angle of incidence from the medium with high refractive index to the medium with low refractive index, θ _L is the angle of incidence from the low refractive medium with high refractive index in the coated layer, n _L is the refractive index of the low refractive index medium in the coated layer)

(R _TM is the reflectance of the TM polarized wave, n _A is the refractive index of the incident part, θ _A is the angle of incidence from the incident part into the film medium, n _H is the refractive index of the high refractive index medium in the coated layer, θ _H is the coated layer Θ _L is the angle of incidence from the medium with high refractive index to the medium with low refractive index, θ _L is the angle of incidence from the low refractive medium with high refractive index in the coated layer, n _L is the refractive index of the low refractive index medium in the coated layer)

Although the coating technology irrelevant to TE polarization and TM polarization has been studied in manufacturing such a non-polarization transmission or reflection filter by Thin Film Coating, the phase thickness change and optical admittance in each layer, which are fundamental problems, have not been completely eliminated. As a result, it is difficult to achieve reflection or transmission characteristics that are independent of the polarization direction, and this problem becomes more pronounced as the angle of incidence is large or the range of the input light wavelength is wide.

In addition, reflectance considering polarization in a single medium is determined by Fresnel's Equation described in Equations 3 and 4 according to the angle of incidence between the medium and the input light. The reflectance of the TE polarized light and the reflectance of the TM polarized light are different, and the same phenomenon occurs even when the dielectric thin film is coated on the reflecting surface of the reflector.

Where R _s is the reflectance for TE polarized light, n is the refractive index of the reflector, and θ is the angle between the normal of the reflector and the incident light)

Where R _p is the reflectance for TM polarization, n is the refractive index of the reflector, and θ is the angle between the normal of the reflector and the incident light)

FIG. 4 is a graph showing the degree of reflection of TE polarized light and TM polarized light for uncoated single medium and highly reflective coated single medium. As shown in FIG. 4, in the uncoated single medium and the highly reflective coated single medium, the reflectance distributions of the TE polarized light and the TM polarized light according to the incident angle change of the incident light differ only in their distribution forms, respectively. It can be seen that the difference in reflectance does not decrease.

In conclusion, there is a limit to reducing the reflectance difference between TE polarized light and TM polarized light by coating method such as high reflection coating. The most effective method for reducing the reflectance difference between TE polarized light and TM polarized light is 0 degree To stay close to stable.

Accordingly, the bidirectional light transmission module provided by the present invention arranges the light emitter, the planar-convex lens, and the light receiver on the same axis to keep the incident angle of the incident light near 0 degrees, and is not reflected by the planar-convex lens. An additional planar filter is provided between the planar-convex lens and the light receiver to prevent the residual light passing through without entering the light receiver.

5 is a block diagram showing a bidirectional optical transmission module according to a first embodiment of the present invention. As shown in FIG. 5, the bidirectional optical transmission module 100 according to the first preferred embodiment of the present invention includes a light emitter 110, a first optical fiber 120, a dual optical collimator 130, and a planar-convex lens ( 140, a light receiver 150, and a second optical fiber 160, and a flat filter 170 is further provided.

The light emitter 110 is a means for emitting light having a predetermined wavelength λ ₁ . It is preferable to use the laser diode 114 having the ball lens 112 as the light emitter 110.

The first optical fiber 120 is a signal medium means for transmitting the light of the wavelength emitted from the light emitter 110 to the dual optical collimator (130). The input end of the first optical fiber 120 is located at the focus of the light emitted through the ball lens 112 of the laser diode 114, which is the light emitter 110, and the output end of the first optical fiber 120 is a dual optical collimator. It is bonded to the GRIN lens 132 of 130.

The dual optical collimator 130 is a means for converting and outputting the light (λ ₁ , λ ₂ ) of the wavelength transmitted through the first optical fiber 120 and the second optical fiber 160 to parallel light. The dual optical collimator 130 is provided with a GRIN lens 132 therein, the output terminal of the first optical fiber 120 and the input terminal of the second optical fiber 160 are bonded to the GRIN lens 132, respectively. The light of the wavelength emitted through the output end of the first optical fiber 120 is converted into parallel light by the GRIN lens 132, the light of the wavelength (λ ₁ ) is reflected by the planar-convex lens 140 It is incident through the input terminal of the second optical fiber 160. The dual optical collimator 130 facilitates optical axis alignment.

The planar-convex lens 140 totally reflects the light λ ₁ having a predetermined wavelength among the parallel lights λ ₁ and λ ₂ passing through the GRIN lens 132 of the dual optical collimator 130, and the light having the remaining wavelength. (λ ₂ ) is a means for transmitting. The planar-convex lens 140 consists of a hemispherical lens with a filter coated plane 142. That is, the planar-convex lens 140 includes a plane having a function of filtering light of a specific wavelength and a convex surface having a condensing function. If the incident angle of the incident light incident on the plane 142 of the planar-convex lens 140 is maintained at near 0 degrees, the difference in reflectance between the TE polarized light and the TM polarized light may be reduced, thereby increasing the overall reflectance.

The light receiver 150 is a means for receiving light λ ₂ of a wavelength passing through the planar-convex lens 140. As the light receiver 150, a photodiode 154 having a planar window 152 may be used. The installation position of the photodiode 154 is adjusted so that the focus of the planar-convex lens 140 is located in the active area 156 of the photodiode 154.

The second optical fiber 160 has an input terminal bonded to the GRIN lens 132 and receives light λ ₁ reflected from the planar-convex lens 140 to transmit to another node, and a wavelength transmitted from another node. Λ ₂ is emitted to the dual optical collimator 130.

The planar filter 170 passes light λ ₂ at the wavelength passed through the planar-convex lens 140 as it is, and must be reflected by the planar-convex lens 140, but otherwise remains of the wavelength passed as it is. It is a means for preventing the light λ ₁ from entering the light receiver 150. That is, the planar filter 170 should be reflected by the planar-convex lens 140, but the light λ ₁ having the wavelength passed as it is is incident to the photodiode 154 which is the light receiver 150. The signal characteristic is prevented from being impaired, and the photodiode 154, which is the light receiver 150, receives only the light having the wavelength λ ₂ . The planar filter 170 is installed to be inclined at a predetermined angle between the planar-convex lens 140 and the light receiver 150. As the inclination angle β, 8 degrees is preferable.

Meanwhile, FIG. 6 is a graph showing transmission characteristics for a specific wavelength of a planar-convex lens and a planar filter according to an aspect of the present invention. In the case of the planar-convex lens filter and planar filter of the bidirectional optical transmission module installed in the first node, FIG. blocking light having a wavelength λ ₁ and wavelength λ ₂ of the light as it is, while passing, the two-way optical transmission module installed in the second node plane of the in the case of the positive lens filter and a flat filter contrary wavelength λ ₂ light to block and The light of wavelength lambda ₁ is filtered so as to pass as it is.

In addition, referring to Figures 5 and 6 look at the operation of the bidirectional optical transmission module according to a first embodiment of the present invention.

Light having a wavelength λ ₁ emitted from the laser diode 114 that is the light emitter 110 (eg, light of 1310 nm) is transmitted to the dual optical collimator 130 through the first optical fiber 120. Subsequently, the light having the wavelength λ ₁ is converted into parallel light while passing through the GRIN lens 132 of the dual optical collimator 130, and is totally reflected on the plane 142 of the planar-convex lens 140 to be second optical fiber 160. ) Is incident. In this case, the residual light having the wavelength λ _{1 that} passes through the plane 142 of the planar-convex lens 140 without being reflected is reflected again by the planar filter 170 that is inclined.

On the other hand, light having a wavelength λ ₂ (for example, light of 1550 nm) transmitted from another node through the second optical fiber 160 is converted into parallel light while passing through the GRIN lens 132 of the dual optical collimator 130. And a photodiode 154, which is an optical receiver 150, is passed through the planar-convex lens 140 and the planar filter 170.

On the other hand, Figure 7 is a block diagram showing a bidirectional optical transmission module according to a second embodiment of the present invention. As shown in FIG. 7, the bidirectional optical transmission module 200 according to the second exemplary embodiment of the present invention has a light emitter 210, a first optical fiber 220, and a dual optical collimator 230 like the first embodiment. , The planar-convex lens 240, the light receiver 250, the second optical fiber 260, and the planar filter 270, and unlike the first embodiment, the ball lens 252 is used as the light receiver 250. Is used a photodiode 254.

When the photodiode 254 having the ball lens 252 is used as the light receiver 250 as the second embodiment of the present invention, the light receiving angle is lower than that of the photodiode having the flat window as in the first embodiment. As a result, the optical signal transmission loss can be reduced. Operation of the bidirectional optical transmission module according to a second embodiment of the present invention is the same as the first embodiment.

8 is a cross-sectional view of a bidirectional optical transmission module manufactured according to the first application of the present invention, Figure 9 is a cross-sectional view of a bidirectional optical transmission module manufactured according to the second application of the present invention.

As shown in FIG. 8, the bidirectional optical transmission module 1000 manufactured according to the first application of the present invention includes a housing 1100 and four blocks inserted into the housing 1100. , Ferrule holder 1300, optical collimator-filter holder 1400, and photodiode block 1500.

The housing 1100 is an exterior portion of the bidirectional optical transmission module 1000 and is a pipe-shaped member. The material of the housing 1100 may be any synthetic resin or metal material as long as the material of the housing 1100 is strong enough to protect the built-in component from external force. Preferably, the housing 1100 is manufactured using a material resistant to moisture or temperature change. The housing 1100 includes an optical fiber hole 1110 through which the second optical fiber 160 passes. The laser diode block 1200 is fixed to one end of the housing 1100 and includes a laser diode 114 that is a light emitter. The ferrule holder 1300 includes a ferrule 1310 into which the first optical fiber 120 is inserted. The ferrule holder 1300 is fixed to the laser diode block 1200 such that the first optical fiber 120 is aligned with the laser diode 114 of the laser diode block 1200. The optical collimator-filter holder 1400 includes a dual optical collimator 130 and a planar-convex lens 140. The photodiode block 1500 is fixed to the other end of the housing 1100 and includes a planar filter 170 and a photodiode 154.

On the other hand, as shown in FIG. 9, the bidirectional optical transmission module 2000 manufactured according to the second application of the present invention has the housing 2100 and the four inserted into the housing 2100 like the first application. Blocks include a laser diode block 2200, a ferrule holder 2300, an optical collimator-filter holder 2400, and a photodiode block 2500, but are viewed as an optical receiver incorporated within the photodiode block 2500. A photodiode 254 with a lens 252 is used.

That is, the housing 2100 is an exterior portion of the bidirectional optical transmission module 2000 and is a pipe-shaped member. The housing 2100 includes an optical fiber hole 2110 through which the second optical fiber 260 passes. The laser diode block 2200 is fixed to one end of the housing 2100 and includes a laser diode 214 which is a light emitter. The ferrule holder 2300 includes a ferrule 2310 into which the first optical fiber 220 is inserted. The ferrule holder 2300 is fixed to the laser diode block 2200 such that the first optical fiber 220 is aligned with the laser diode 214 of the laser diode block 2200. The optical collimator-filter holder 2400 incorporates a dual optical collimator 230 and a planar-convex lens 240. The photodiode block 2500 is fixed to the other end of the housing 2100 and includes a photodiode 254 having a planar filter 270 and a ball lens 252.

As described above, the bidirectional optical transmission module according to the embodiment of the present invention maintains the angle between the filter-coated plane of the planar-convex lens and the incident light at about 0 degrees or near 0 degrees, so that the total transmission or total reflection of the specific wavelength is reduced. It is possible to improve the optical signal transmission characteristics.

In addition, the bidirectional optical transmission module according to an embodiment of the present invention has an effect of minimizing crosstalk loss due to polarization of input light.

In addition, since the bidirectional optical transmission module according to the embodiment of the present invention applies a dual optical collimator, there is an effect of facilitating the optical axis alignment operation required to make divergent light into parallel light or to inject light into the optical fiber.

In addition, the bidirectional optical transmission module according to an embodiment of the present invention can arrange a light emitter, a dual optical collimator, a planar-convex lens, a planar filter, and a light receiver in a line to manufacture a bidirectional optical transmission module in the form of Small Form Fact. It can work.

Claims (5)

In the optical transmission module, A light emitter for emitting light of a predetermined wavelength; A first optical fiber for transmitting light of a wavelength emitted from the light emitter; A dual optical collimator having a GRIN lens to which the output terminal of the first optical fiber is bonded to output the input light as parallel light; A planar-convex lens composed of a hemispherical lens having a filter-coated plane which totally reflects light of a predetermined wavelength among the parallel light passing through the GRIN lens of the dual optical collimator and transmits light of another wavelength; A light receiver for receiving light having a wavelength passing through the plane-convex lens; An input terminal is coupled to the GRIN lens to receive the light of the wavelength reflected from the planar-convex lens to pass to another node, and includes a second optical fiber for outputting the light of the wavelength transmitted from the other node to the dual optical collimator Bidirectional optical transmission module, characterized in that. The method of claim 1, Bidirectional light, characterized in that it is provided inclined between the planar-convex lens and the light receiver by a predetermined angle, and reflects only the light of a predetermined wavelength of the light passing through the planar-convex lens. Transmission module. The method of claim 1, The optical emitter is a bidirectional optical transmission module, characterized in that using a laser diode having a ball lens. The method of claim 1, And a photodiode having a ball lens for receiving the input light as the optical receiver. The method of claim 5, And the photodiode is installed by adjusting a relative distance from the planar-convex lens so that the focus of the planar-convex lens is formed in the active region.