KR20140101897A - Optical adaptor-type connector with reflector being included - Google Patents

Abstract

The present invention relates to an optical fiber connector having an optical fiber fixing structure with a reflector and an optical connecting method using the same. The optical fiber connector having a reflector including an optical fiber bragg grating is capable of securing wavelength stability by compensating for reflection wavelength transition of a bragg grating due to external environment changes such as increase of stress and peripheral temperature. Furthermore, one end thereof is formed to have a plug type same as an existing optical fiber connector, and the other end thereof is formed to have an adaptor type to which the existing optical fiber connector can be inserted, thereby solving the problem that may be caused by the remaining length of the optical fiber due to spatial constraints when an optical communications system is realized.

Description

TECHNICAL FIELD [0001] The present invention relates to an optical fiber connector having a reflector built-in optical fiber fixing structure and an optical connection method using the same,

The present invention relates to an optical fiber connector, and more particularly, to an optical fiber connector in which a reflector including an optical fiber Bragg grating is built in, and a reflection wavelength of a bragg grating caused by an external environment change, And the wavelength stabilization can be ensured by compensating the transition. One end of the optical fiber connector is in the same plug shape as the optical fiber connector, and the other end is connected to an adapter An optical fiber connector having a reflector built-in optical fiber fixing structure capable of solving a problem caused by an optical fiber filament due to restriction of space when an optical communication system is implemented, and an optical connecting method using the optical fiber connector.

Since the diameter of the core of the optical fiber is as small as about 10 to 50 mu m, it is required to match the optical axis of the mutual optical fiber to be connected so as to correspond to several micrometers with high precision in order to reduce the connection loss when connecting with a connector. In order to match the outer diameter of the optical fiber, the optical fiber shaft is fixed using a ferrule which accommodates the optical fiber in a small and precise fine hole concentric with the outer coupling surface so as to maintain high precision.

The ferrule is made of aluminum oxide or zirconium oxide, which is stainless steel, polymer or ceramic type, so that a precise shape of the ferrule can be maintained. In the connection using the optical connector, a minute hole penetrating the optical fiber It is the part used to align the optical fiber.

In the connector using a ferrule, it is possible to secure accurate positional accuracy by polishing a cross section by fixing an optical fiber inserted into a cylindrical-shaped optical fiber receiving hole with a diameter slightly larger than the outer diameter of the optical fiber and highly precisely opened in the center of the ferrule with an adhesive .

On the other hand, in order to connect to the socket of the plug board, a connector is formed at both ends of a relatively short optical cable cord, and a patch cord is used for interconnecting the communication lines at the crossing points.

Fiber optic connectors or optical fiber patch cords are essential optical components for optical connection between optical modules. Various structures and shapes are standardized according to the type of connection and contact interface, and they are mass-produced at low cost.

Other fiber optic connectors designed for connection type are connectors designed for high density packaging and coupling. They are made by PC (Physical Contact) polishing of optical cable to reduce connection loss. They are small size and square type, ), A large server with 2Gbps support, a SAN switch, and a storage-type connector. The LC type (local channel), which is suitable for a compact connector bank structure in a narrow space, and the ST type It is suitable for low reflection loss applications because it has low mounting density in a straight type and a simple uni-directional (simplex) structure. It is suitable for low reflection loss applications. Bi type (biconic connector), mini size unit which can connect several connectors at the same time, etc. It has become a mass-produced at a low cost and so.

Fig. 1 shows an example of the optical fiber patch cord 1 described above. As shown in this figure, the optical fiber patch cord 1 comprises a first optical connecting portion 10 and a second optical connecting portion 11 having a known plug structure and a first optical connecting portion 10 and a second optical connecting portion 11, And an optical cable cord 12 for connecting the optical connector 11.

FIG. 2 shows the internal structure of an optical fiber connector mounted in the conventional optical fiber patch cord 1. As shown in FIG. Referring to this figure, a ferrule 2 made of zirconia is press-fitted into a metal sleeve 3, and an optical fiber 40 having an optical fiber bragg grating 41 formed in the inner cavity 30 of the metal sleeve 3 Respectively. The optical fiber 40 engraved with the bragg grating 41 is terminated at the end portion 21 of the ferrule 2 while being inserted into the fine hole 20 of the ferrule 2. In the end portion 31 of the metal sleeve 3, Is not terminated but remains in a pigtail form, and is inserted into the optical cable cord 12 of the optical fiber patch cord 1.

Here, the ferrule 2 is located inside the first optical connecting portion 10 or the second optical connecting portion 11 of the patch cord 1. The detailed structure of the first optical connection part 10 and the second optical connection part 11 is formed in the form of a plug of a standard standard and the optical module to which the optical connection is optically connected is a standard adapter or an optical connection part in the form of a receptacle, The optical connection between the optical modules can be easily realized.

In designing the optical cable, the temperature characteristic which is the influence of the temperature change on the transmission characteristic, the side pressure characteristic of the side pressure on the transmission characteristic when the cable is installed, the bending characteristic on the transmission characteristic of the cable connection and the bare fiber treatment, Transmission characteristics, and the characteristics of life span.

Among the above, the temperature characteristic has a serious influence on the transmission characteristics of the optical fiber due to the unpredictable temperature change. A technique for forming a fiber Bragg grating is used as a method for improving the transmission characteristics of an optical fiber.

The fiber Bragg grating induces a change in the refractive index of the optical fiber to have a constant period in the longitudinal direction. The Bragg grating reflects only the Bragg wavelength band satisfying the Bragg reflection condition, and has a characteristic of transmitting the other wavelengths. The optical fiber Bragg grating filter can be easily fabricated on a commercial optical fiber, and since it has the same size and transmission characteristics as conventional optical fibers, optical connection is very easy, so it is widely applied not only for optical communication filters but also for optical sensors.

The Bragg reflection wavelength of the Bragg grating is sensitive to a change in the state of the optical fiber grating due to an external environment such as a temperature change and thus a change in stress applied to the Bragg grating. In particular, in order to be used as a reflection and transmission filter in optical communication, the stability of the reflection wavelength of the bragg grating should be ensured against the external environment and the stress change.

The structure in which the optical fiber bragg grating is inserted into the standard optical fiber connector and the patch cord and the change of the Bragg reflection wavelength is compensated by the external environment change such as a temperature change is disclosed in Korean Patent No. 10-1016179 .

FIG. 3 is a structural view showing the inside of an optical fiber connector including a ferrule and a temperature compensator in connection with the prior patent.

Referring to this figure, the optical fiber 4 has a bragg grating 41 engraved on a part of the core 40 from which the outer jacket 42 and the inner jacket 43 of the polymer are removed, And the ferrule 2 made of zirconia and fixed by the thermosetting resin.

Specifically, the bragg grating 41 is located in the inner pupil 22 of the ferrule 2 so that there is no mechanical interference, while both portions near the bragg grating 41 are located on the axis of the temperature compensator 5, Is fixed with a thermosetting resin to the fine holes (20) perforated at the center of the direction and the fine holes (20) perforated at the axial center of the ferrule (2).

The outer circumferential surface of the ferrule 2 and the inner circumferential surface of the outer jacket 42 of the optical fiber 4 are fixed to the outer surface of the ferrule 2 by thermosetting resin, The body 5 is accommodated.

 This structure can compensate the change of the Bragg wavelength for environmental changes such as temperature by structurally combining heterogeneous materials with different thermal expansion coefficients, thereby canceling the thermo-optic effect and photoelastic effect of the bragg grating.

Here, the coefficient of thermal expansion of the ferrule 3 is? 1, the coefficient of thermal expansion of the temperature compensating body 2 is? 2, and the effective coefficient of thermal expansion of the region of the brick lattice 41 according to the temperature change of the external environment is? For temperature compensation of the lattice, α2 should be larger than α1.

The length from the position where the temperature compensating body 5 and the ferrule 2 are fixed to each other by the thermosetting resin to the position where the optical fiber 40 is fixed to the ferrule 2 by the thermosetting resin is L1, When the length of the lattice 41 is L ?, the relational expression of? And L1 and L2 for temperature compensation of the brick lattice 41 is expressed by the following equation.

α = (α1 × L1-α2 × L2) / (L1-L2) = -9 × 10 ^-6 [1 / deg]

The principle of the above formula is known in the US Pat. No. 5,042,898, wherein the change in the refractive index due to the thermo-optic effect of the silica optical fiber is canceled by the variation rate of the optical fiber grating period due to the difference in the thermal expansion coefficient, by using different kinds of materials having different thermal expansion coefficients It is possible to derive the temperature compensation structure of various brick gratings by preventing the reflection wavelength of the brick from being dependent on the temperature change of the external environment.

The length L2 of the temperature compensating member 2 and the magnitude a2 of the thermal expansion coefficient according to the principle of the formula are calculated by adding the length L1 in the ferrule 3 and the magnitude a1 of the thermal expansion coefficient and the amount of change due to the thermo- Value so that the wavelength change does not occur in the bragg grating due to the temperature change.

United States Patent 5042898 Korean Patent No. 10-1016179

The optical fiber patch cord 1 is commonly used for optical connection between optical modules in an optical communication system. However, the optical cable cord 1 has various lengths due to the limited space of the optical cable cord 1, the system mounting density, the system shape and size, the ease of maintenance of the optical module in the system, Is required.

This is because the length of the bragg grating-incorporated optical fiber patch cord is dependent on the shape of the specific optical communication system and the environment in which it is applied, which is a major cause of increasing the price of the optical fiber patch cord incorporating the bragg grating, Because.

The present invention solves the problem of the optical fiber length, which is a problem of the conventional Bragg grating-incorporated optical fiber patch cord, and can be used as an integral unit by being inserted into another optical module, for example, an optical output port of a receptacle, The oscillation wavelength of the external resonance laser is fixed by the Bragg grating wavelength so that only the Bragg grating wavelength is changed without changing the optical transceiver and wavelength can be managed and generated as the main communication resource of the optical communication efficiently. An optical fiber connector having a reflector-built optical fiber fixing structure capable of reducing the number of patch cords and solving the problem of matching of optical fiber lengths that can occur when optical connection between optical modules in an optical communication system is complicated and problems due to optical fiber yarns, .

In the optical connector of the present invention, one end has the same plug shape as the conventional optical fiber connector, and the other end has an adapter type in which a conventional optical fiber connector can be inserted, Disclosed is an optical fiber connector structure having an adapter in which a formed optical fiber is embedded.

 Secondly, since the structure of the ferrule to be applied to the optical fiber connector having one end portion as a plug type and the other end portion as an adapter type as described above is different from the structure of a ferrule mounted on a conventional optical fiber patch cord, The structure of the temperature compensator for temperature compensation of the temperature compensator must be changed from the conventional structure. For this purpose, a braid having a detailed structure of a ferrule capable of compensating the bridging lattice temperature when the reflector is a bragg grating can be mounted on an optical fiber connector whose one end is in the form of a plug and the other end is in the form of an adapter A grating-incorporated optical fiber connector structure is disclosed.

Third, a structure in which the structure of the bragg grating-incorporated optical fiber connector is applied is disclosed, which is optically connected to a transmission port of an SFP (small form factor pluggable) optical transceiver to form an external resonator.

Fourth, in an SFP optical transceiver that performs optical transmission and optical reception functions using different wavelength bands, two optical connection ports are connected to one optical connection Port of the light beam.

An optical fiber connector having a reflector built-in optical fiber fixing structure for achieving the object intended by the present invention has a shape that is coupled to a plug, an adapter or a receptacle, and is a thin film filter which is dependent on a bragg grating or a wavelength, A fiber optic connector incorporating a reflector in which a transition of a reflection center wavelength is compensated for an environmental change such as a temperature change by a reflector selected from a thin film filter, And the opposite end of the first connecting portion is a second connecting portion having a form of a standard adapter or a receptacle to which a conventional optical fiber connector can be inserted, and the first connecting portion and the second connecting portion are optical fiber connecting And is optically connected to another optical module by the structure.

In such an optical fiber connector, the structure of the first connection part is formed like the optical connection part of the standard optical fiber patch cord, but the detailed structure of the optical fiber fixing structure installed therein must be different from each other. The structural features of the optical fiber fixing structure are as follows: an optical fiber having a reflector; A first sleeve; A first ferrule formed with a fine hole into which the optical fiber is inserted and fixed to one end of the first sleeve; Wherein the optical fiber is inserted into the first space and is accommodated in the inner space of the first sleeve to compensate for a change in the reflected wavelength of the reflector due to a change in the external environment temperature, Sieve; A second sleeve for receiving and fixing the first sleeve and the temperature compensating member in an inner space; And a second ferrule for supporting the optical fiber, wherein the optical fiber is press-fitted into the first ferrule and the micropore of the temperature compensating body, and the optical fiber is inserted into the first ferrule and fixed to one end of the second sleeve, And a reflector positioned between the first ferrule and the temperature compensating body in the inner space of the first sleeve, and is mounted to form a longitudinal section between the ends of the first ferrule and the second ferrule.

The reflector may be selected from a thin film filter that is independent of the brass grating or wavelength or a thin film filter that is independent of the wavelength.

 In the optical fiber connector having the reflector-built optical fiber fixing structure according to the present invention, the first ferrule and the second ferrule, each having a perforation hole for receiving the optical fiber, are inserted into both ends of the first sleeve and the second sleeve, 1, a temperature compensator having a perforated fine hole for receiving an optical fiber coaxial with the fine holes is fixed in the second sleeve, so that an optical fiber having a bragg grating forms a temperature compensator at one end of the first ferrule To the end of the second ferrule, thereby acting as plugs and adapters, respectively.

Another characteristic of the optical fiber connector having the reflector built-in optical fiber fixing structure of the present invention is that the bragg grating-built optical fiber connector is coupled to an SFP optical transceiver having a built-in transmission optical component (TOSA) Thereby forming an external resonator whose oscillation wavelength is determined.

The SFP optical transceiver includes a semiconductor laser diode in which a transmitter optical subassembly (TOSA) emits a broadband light, and the reflector built-in optical fiber connector is optically connected to a transmission port to form an external resonator, An external resonance laser is generated in which the wavelength of the light source is determined by the reflection wavelength of the bragg grating.

And optical connection port conversion means for converting two optical connection ports into one optical connection port by using an optical filter when a wavelength band different from the transmission light wavelength and the reception light wavelength is used in the SFP optical transceiver.

The optical connection port converting means includes an input adapter into which a commercial LC type and an SC type optical fiber patch cord are inserted, an output first plug and an output second plug identical in shape to a commercially available LC connector, an optical filter, and an optical isolator, Wherein the second optical fiber connector is optically connected to the first connection part of the reflector built-in optical fiber connector when the wavelength band of the transmission light and the wavelength of the reception light are different from each other in the optical transceiver and the output first plug of the SFP optical transceiver and the reflector And the second connection portion of the built-in optical fiber connector is connected to the transmission port and the reception port of the dual receptacle optical transceiver, respectively, thereby converting the two optical connection ports provided in the SFP optical transceiver into one optical connection port using the optical filter portion.

A technical feature of the optical connection method using the optical fiber connector having the reflector built-in optical fiber fixing structure of the present invention is that the first connection portion of the optical fiber connector is inserted into the adapter or receptacle of another optical module and is optically connected, The first optical connection part or the second optical connection part of the optical fiber patch cord 1 connected from the optical module is optically connected so that the external resonant laser using the optical connection with the broadband light source semiconductor laser diode is operated and the optical cable of the optical fiber patch cord 1 and the second It is possible to exclude the optical connection portion.

Another technical feature of the optical connection method using the optical fiber connector having the reflector built-in optical fiber fixing structure of the present invention is that a first end is a first connection part having a plug shape and an opposite end of the first connection part is an optical fiber connector Wherein the first connection part and the second connection part are optically connected to the other optical module by the optical fiber connection structure, The optical fiber connector having the reflector built-in optical fiber fixing structure is optically connected to the transmission optical part (TOSA) of the receptacle-type optical transceiver 8 having the receptacle shape in which the semiconductor laser diode for emitting the broadband light is mounted, An external resonant laser is generated by the wavelength of the light source determined and output by the band .

According to the present invention, when a Bragg grating is used as a reflector, the wavelength shift of the Bragg grating caused by an external environment change such as a stress applied to the optical fiber grating from the outside and a temperature rise around the Bragg grating is compensated, And the shape of both terminals is a plug and an adapter in order to facilitate optical connection with other optical modules and optical fiber connectors, thereby solving the problem due to the restriction of the optical fiber due to space limitation in actual implementation of the optical communication system .

According to the present invention, there is provided an optical fiber connector having a bragg reflector and a structure for compensating for a change in Bragg grating reflection wavelength with respect to an external environment change, one end of the optical fiber connector having a plug shape and the other end having an adapter shape, First, since the plug and adapter type optical connection is simultaneously provided in contrast to the conventional optical fiber connector having a patch cord type, it can be inserted into the receptacle optical output port of the other optical module and used integrally with the optical module.

Second, an external resonance laser is formed through an optical connection between the SFP optical transceiver including the semiconductor laser diode emitting the broadband light and the bragg grating internal optical fiber connector, whereby the oscillation wavelength is fixed by the Bragg grating wavelength. This enables efficient generation and management of wavelengths, which are the main communication resources of optical communication, by changing only the bragg grating wavelength without changing the SFP optical transceiver.

Third, since the number of optical fiber patch cords required for the SFP optical transceiver is reduced from two to one through the optical connection converter for converting the two optical connection ports of the SFP optical transceiver into one optical connection port, It is possible to easily solve the problem of the optical fiber length matching and the problem of the optical fiber sheath which can occur in the inter-optical connection.

FIG. 1 is a perspective view showing an outline of an optical fiber patch cord incorporating a bragg grating and a temperature compensator in the prior art
2 is a view showing the internal structure of a conventional optical fiber patch cord
(A) is a perspective view
(B) is a section
3 is a view showing an internal connection structure of a bragg grating and a temperature compensator in a conventional optical fiber connector
(A) is a partially cut perspective view
(B) is a section
4 is a perspective view of the optical fiber connector of the present invention
5 is an exploded perspective view of the optical fiber connector of the present invention
6 is a sectional view of the optical fiber connector of the present invention
7 is a view showing an internal connection structure of the bragg grating and the temperature compensator in the optical fiber connector of the present invention
(A) is a partially cut perspective view
(B) is a section
8 is a cross-sectional view showing another embodiment of the temperature compensator in the present invention
9 is a cross-sectional view showing another embodiment of the temperature compensator in the present invention
10 is a perspective view showing another embodiment to which the present invention is applied.
11 to 13 are graphs showing the oscillation wavelength characteristics according to the variation of the Bragg grating reflection wavelength in the external resonance laser structure
14 is a graph showing the oscillation wavelength characteristics according to the variation of the Bragg grating reflection wavelength in the external resonant laser structure of the present invention
15 is a perspective view showing a state in which the optical fiber connector of the present invention is connected to the optical connection port converting means
(A) is a perspective view in which the optical fiber connector and the optical connection port converter are separated
(B) is a perspective view in a state in which an optical fiber connector and an optical connection port converter are connected
16 is a block diagram showing a state in which an optical fiber connector and an optical connection port converter are connected in the present invention
17 is a perspective view of the optical fiber connector, the optical connection port converter, and the optical transceiver in the present invention,
Fig. 18 is a characteristic diagram of an optical filter in the optical filter section of Fig. 16,
(A) is a characteristic diagram when an edge filter is used;
(B) is a characteristic diagram when a band pass filter is used.

BRIEF DESCRIPTION OF THE DRAWINGS The features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings. Hereinafter, embodiments of the present invention will be described.

4 is a perspective view of a bragg grating-built optical fiber connector according to the present invention, FIG. 5 is an exploded perspective view, and FIG. 6 is a cross-sectional view.

As shown in this figure, the optical fiber connector 6 of the present invention is composed of the first connecting portion 61, the second connecting portion 62, and the optical fiber fixing structure 63.

5 and 6, the first connection part 61 is formed in the same plug shape as that of a conventional commercial LC connector, with a housing 610 and a lever 611 formed thereon. Specifically, the housing 610 includes a fixing groove 612 for supporting the optical fiber fixing structure 63, a connecting groove 613 for receiving and connecting the transmitting optical component 81, an optical fiber fixing structure 63, And a coupling groove 615 for fixing the second connection part 62 is formed on the vertical surface of the end where the second connection part 62 is inserted .

5 and 6, the second connector 62 includes a housing 620 in a form of a standard adapter into which a conventional optical fiber connector can be inserted or a receptacle coupled to the receptacle at the rear of the first connector 61, A fixed end portion 622 is formed at one end to be inserted into the hole 614 so as to be coupled to the first connection portion 61, On both vertical sides of the fixed end portion 622, coupling protrusions 623 protruding in a triangular cross section are formed with inclined surfaces so as to be inserted into coupling grooves 615 formed in the housing 610.

The spring 624 is installed between the inner wall of the housing 620 of the second connection portion 62 and the optical fiber fixing structure 63 to provide relative motion between the housing 61 and the optical fiber fixing structure 63.

FIG. 7 shows the internal structure of an optical fiber fixing structure 63 to which a bragg grating and a temperature compensating member, which are applied to the optical fiber connector of the present invention, are connected.

As shown in this figure, the optical fiber fixing structure 63 includes a first ferrule 630, a first sleeve 640, a temperature compensation structure 650, a second sleeve 660, and a second ferrule 670 .

The first ferrule 630 is made of zirconia and has a fine hole 631 through which the optical fiber 70 is inserted in the center. While the other end is formed with an inclined surface 633 gradually narrowed toward the inside so as to guide the inserted optical fiber 70 so that the optical fiber 70 is physically inserted into the first sleeve 631 or thermally cured by the thermosetting resin .

The first ferrule 630 is located inside the first connection part 61 and performs a plug connection.

The first sleeve 640 is made of a metal material such as stainless steel and passes through the inner center of the hexagonal body 641 and the circular tubular body 642 so that the first ferrule 630 and the temperature compensating structure 650, (643) are formed.

The cavity 643 is formed to include an extended cavity 644 having a larger inner diameter than a portion where the first ferrule 630 is inserted than a portion where the temperature compensating structure 650 is inserted.

The temperature compensating structure 650 may include a temperature compensator 651 selected from aluminum, brass, acetal, polycarbonate, polyimide, and austenitic stainless steel to compensate for changes in the reflection wavelength of the brick grating due to a change in the external environment temperature, And a fixture 652 for fixing the temperature compensating body 651.

The temperature compensating body 651 is formed with a fine hole 653 passing through the center in the axial direction so that the optical fiber 70 can be inserted.

The fixture 652 is fixed to the fixture 652 so that the temperature compensator 651 is fixed to the fixture 654 from the fixed end 654 inserted into the cavity 643 formed in the circular tube 642 of the first sleeve 640 to the same outer diameter as the circular tube 642 A fine hole 656 continuous to the fine hole 653 of the temperature compensator 651 and passing through the center in the axial direction is formed in the center so that the optical fiber 70 can be inserted into the center of the flange 655 have.

The temperature compensating body 651 is fixed to the fixture 652 by a thermosetting resin so that it is not interfered with the cavity 643 and the fixture 652 is physically inserted into the circular tube body 642 of the first sleeve 640 The contacted portion is fixed by the thermosetting resin and is concealed by the second sleeve 660.

The second sleeve 660 is formed in a cylindrical shape and has a first pore 661 into which the circular tubular body 642 of the first sleeve 640 is inserted and an inner diameter smaller than the inner diameter of the first pore 661, A second pore 662 into which the ferrule 670 is inserted is formed.

A circular tubular body 642 to which the fixture 652 is fixed is inserted into the first pore 661 and is fixed to the first sleeve 640 with a thermosetting resin.

The second ferrule 670 has the same structure as that of the first ferrule 630 described above, and has a role of performing optical connection with a fixed position between components. That is, the second ferrule 670 is made of zirconia, and a fine hole 671 through which the optical fiber 70 is inserted is formed at the center, and a conical slope 672 is formed on the outer circumferential surface of one end portion, And an inclined surface 673 gradually becoming narrower toward the inside is formed so as to guide the optical fiber 70 inserted into the other end of the second sleeve 660 and is physically inserted into the second sleeve 660 or fixed by the thermosetting resin .

The second ferrule 670 is positioned inside the second connection portion 62 to perform an optical connection functioning as an adapter.

The fine holes 631, 653, 655, and 671 formed in the first ferrule 630, the second ferrule 670, and the temperature compensating structure 650 have the same center axis in a straight line.

The hexagonal body 641 of the first ferrule 630 is inserted and supported in the support groove 612 of the first connection portion 61 and the second ferrule 670 Is inserted and fixed in the guide 621 of the second connecting portion 62. [

The optical fiber 70 has an outer jacket formed of a polymer material and a braid grating 71 formed of a polymeric polymer inner jacket.

The bragg grating 71 is placed in the cavity 643 of the first sleeve 640 without physical contact or interference with the first ferrule 630, the first sleeve 640 and the temperature compensating body 651 , And both ends are mounted so as to coincide with the longitudinal face 639 of the first ferrule 630 and the longitudinal face 679 of the second ferrule 670.

 Other portions of the optical fiber 70 excluding the bragg grating 71 are formed by the fine holes 631 inside the first ferrule 630, the fine holes 653 inside the temperature compensating structure 650 and the second ferrule 670, Is fixed to the inner fine holes 671 by thermosetting resin, thereby forming the optical fiber connector 6.

The total length L0 between the ends of the second ferrule 670 fixed to the second sleeve 660 at the end of the first ferrule 630 fixed to the first sleeve 640 depends on the shape of the optical fiber connector 6 Which is in the range of approximately 15 to 25 mm.

The length Lc of the area where the first ferrule 630 is not pressed into the first sleeve 640 is determined to be a standard size and has a value of approximately 4.9 to 5.0 mm.

The length Lb of the region where the second ferrule 670 is not pressed into the second sleeve 660 is determined within a range of 2 to 5 mm according to the shape of the optical fiber connector 6. [

In the structure described above, a length parameter for compensating for the change of the Bragg reflection wavelength due to a change in the external environment of the bragg grating 71 corresponds to the length L2 of the temperature compensator 651 and the length L2 of the bragg grating 71, (LBG) between the first ferrule 630 and the portion fixed to the temperature compensating member 651 at both sides of the first ferrule 630 and the temperature compensating member 651.

Table 1 and Table 2 show the calculated values of the length variable using Equation 1 described above, and Table 3 shows the thermal expansion coefficient values of the materials used in this calculation.

SUS304 / Al SUS304 / polymer L2 [mm] LBG [mm] L1 [mm] L2 [mm] LBG [mm] L1 [mm] 1.50 0.21 1.71 1.50 1.65 3.15 2.00 0.28 2.28 2.00 2.21 4.21 2.50 0.36 2.86 2.50 2.76 5.26 3.00 0.43 3.43 3.00 3.31 6.31 3.50 0.50 4.00 3.50 3.86 7.36 4.00 0.57 4.57 4.00 4.41 8.41 4.50 0.64 5.14 4.50 4.96 9.46 5.00 0.71 5.71 5.00 5.51 10.51

SUS430 / Al SUS430 / polymer L2 [mm] LBG [mm] L1 [mm] L2 [mm] LBG [mm] L1 [mm] 1.5 1.02 2.52 1.50 3.14 4.64 2.0 1.36 3.36 2.00 4.19 6.19 2.5 1.70 4.20 2.50 5.23 7.73 3.0 2.04 5.04 3.00 6.28 9.28 3.5 2.38 5.88 3.50 7.32 10.82 4.0 2.72 6.72 4.00 8.37 12.37 4.5 3.06 7.56 4.50 9.42 13.92 5.0 3.40 8.40 5.00 10.46 15.46

물질 CTE [10-6 / deg] Al 23 SUS430 10 to 11 SUS304 17-19 Brass 17-19 Polymer 50

The length LBG of the bragg grating 71 is in the range of 0.5 to 10 mm and the material and length L2 of the first sleeve 640 and the temperature compensator 650 are determined by the above equation.

The metal sleeve used for the standard commercial ferrule is made of stainless steel (SUS) and brass. In particular, the length L2 of the temperature compensator 651 because of relatively SUS304 and the thermal expansion coefficient of about 19 × 10 compared to ^-6 / deg thermal expansion coefficient of SUS430 material of the brass material is smaller by about 10 × 10 ^-6 / deg Temperature compensation is possible.

8 and 9 show another embodiment of the temperature compensation structure 650 of the present invention. The temperature compensating structure 650a of FIG. 8 has a protrusion 657 formed in the temperature compensating body 651a and an insertion groove 658 formed in the fixture 652a so that the protrusion 657 can be inserted therein. It is pressed or fixed by a thermosetting resin.

The temperature compensating structure 650b of FIG. 9 is a structure in which the temperature compensating member 651b and the fixing member 652b are integrally formed of the same material.

In the optical fiber connector 6 of the present invention as described above, the first connecting portion 61 has a standard plug shape and the second connecting portion 62 on the opposite side has a standard adapter or receptacle shape, Is inserted and optically connected to the adapter or receptacle of another optical module and the second connecting portion 62 is connected to the first optical connecting portion 10 or the second optical connecting portion 11 of the optical fiber patch cord 1 connected from another optical module Are inserted and optically connected.

Therefore, the optical fiber 12 and the second optical connector 11 can be omitted in the conventional optical fiber patch cord 1 described in Fig.

Figure 10 shows another embodiment of the present invention.

This embodiment is an example in which the first connection part 61 of the optical fiber connector 6 of the present invention is inserted into the transmission port 80 of a small form factor pluggable (SFP) optical transceiver 8 in the form of a receptacle, An external resonant laser using an optical connection with a semiconductor laser diode is operated.

A semiconductor laser diode, which is a broadband light source, is mounted on the transmission optical part (TOSA) 91 located inside the transmission port 80 of the optical transceiver 8 and is optically connected to the optical fiber connector 6 A receptacle is attached.

The operation principle of the external resonant laser using the optical connection between the optical fiber connector 6 of the present invention and the broadband light source semiconductor laser diode is shown in Figs.

As shown in FIG. 6, the transmission optical component 82 incorporating the semiconductor laser diode emits a broadband spectrum 800 having a wavelength range of 1500 to 1600 nm through the receptacle 83.

When the first connection portion 61 of the optical fiber connector 6 is inserted into the receptacle 82 of the transmission optical component 81 and optical connection is made therebetween, as shown in FIG. 12, in the band of the bragg grating reflection spectrum 801 External resonance is formed and oscillation occurs.

The wavelength of the oscillation spectrum 802 is determined by the wavelength of the Bragg grating reflection Z spectrum 801 as shown in FIG.

Therefore, even if the SFP optical transceiver 8 is not replaced, an external resonator is formed by inserting the bragg grating-built optical fiber connector 6 having a desired wavelength into the transmission port 80 of the SFP optical transceiver 8, A light source having a desired wavelength can be obtained.

14 shows a graph of the oscillation wavelength characteristic according to the variation of the Bragg grating reflection wavelength in the external resonance laser structure.

Referring to this figure, the oscillation spectrum 810 is obtained by optically connecting an optical fiber connector 6 having a Bragg grating reflection wavelength of 1534 nm, and the oscillation spectrum 811 is a Bragg grating built-in optical fiber connector having a reflection wavelength of 1558 nm The oscillation spectrum 812 is an example in which the bragg grating internal optical fiber connector 6 having the reflection wavelength of 1583 nm is optically connected and the oscillation spectrum 813 is an example of the bragg grating having the reflection wavelength of 1592 nm, And the grid built-in optical fiber connector 6 is an optical connection.

As described above, the wavelength of the oscillation light source through the optical connection between the bridgewave built-in optical fiber connector and the broadband light source semiconductor laser diode can be in the optical communication wavelength band of 1260 to 1660 nm.

 In the wavelength division multiplexing optical network, since the optical wavelength band outputted from the transmission port 80 is different from the optical wavelength band inputted into the reception port 81, it is possible to use two optical connection ports as one optical fiber It is possible to optically connect to the connection port.

Since the SFP optical transceiver 8 has the transmitting port 80 and the receiving port 81, it means that two optical fiber patch cords must be connected to one SFP optical transceiver 8 for optical transmission and reception.

In practice, when constructing an optical communication system of wavelength division multiplexing type, at least 32 SFP optical transceivers 8 are used. At this time, more than 64 optical fiber patch cords must be used.

Therefore, considering the limitation of the space in which the optical communication system is installed, the maintenance of the optical module, and the processing of the optical fiber sheath, an optical connection port converting means for reducing the number of optical fiber patch cords required by the SFP optical transceiver 8 to one is needed.

In the wavelength division multiplexing optical network, since the optical wavelength band outputted from the transmission port 80 and the optical wavelength band inputted from the reception port 81 are different from each other, It is possible to optically connect the two optical connection ports to one optical connection port.

Therefore, by optically connecting the optical connection port conversion means and the bragg grating-incorporated optical fiber connector 6 to the transmission port 80 and the reception port 81 of the above-described SFP optical transceiver 8, The number of optical fiber patch cords required to connect to the SFP optical transceiver 80 can be reduced to one.

15 is a perspective view showing a state in which an optical fiber connector 6 is connected to an optical module such as an optical connection port converter 9 as optical connection port converting means in the present invention. 15A is a perspective view in which the optical connection port converter 9 and the optical fiber connector 6 are separated from each other, FIG. 15B is a perspective view of the state in which the optical connection port converter 9 and the optical fiber connector 6 are connected Fig. 16 shows a block diagram in a state in which the optical connection port converter 9 and the optical fiber connector 6 are connected.

The external structure of the optical connection port converter 9 is such that an input adapter 91 is formed at one end of the housing 90 that is the input side of the housing 90 and is connected in parallel to the other end of the housing 90 as an output side And the first output plug 92 and the second output plug 93 are optically connected.

The input adapter 91 may be connected to a commercially available LC type or SC type optical fiber patch cord inserted therein.

The first output plug 92 and the second output plug 93 are the same as those of the commercial LC connector.

As shown in FIG. 16, the optical connection port converter 9 has an optical filter unit 900 and an optical isolator 901 installed in parallel inside the housing 90.

The input side of the optical filter unit 900 is optically connected to the input adapter 91 and the output side is optically connected to the first output plug 92. The optical filter unit 900 can perform various types of wavelength division and combining functions by using one or more optical filters having an edge filter or a band pass filter characteristic.

The optical isolator 901 is optically connected to the optical filter unit 900 and the second output plug 93 to prevent the direction of light from proceeding in the reverse direction.

Although the optical filter unit 900 and the optical isolator 901 are shown as being separated from each other in the example shown in FIG. 16, the optical filter unit 900 and the optical isolator 901 are constituted by one block .

The second output plug 93 of the optical connection port converter 9 is optically connected to the second connection portion 62 of the bragg grating built-in optical fiber connector 6 according to the characteristic embodiment of the present invention.

17, the first output plug 92 is inserted and optically connected to the receiving port 81 of the SFP optical transceiver 8, and the first connecting portion 61 of the optical fiber connector 6 is connected to the SFP optical transmitter / It is inserted into the transmission port 80 of the transceiver 8 and optically connected to oscillate the light source by the external resonator.

In this embodiment, the optical signal input to the input adapter 91 is transmitted to the optical filter unit 900, and the optical filter unit 900 transmits the determined specific wavelength band only to the first output plug 92, To the receiving port 81 of the SFP optical transceiver 8. [

The light source oscillated through the external resonator by optical connection between the Bragg grating internal optical fiber connector 6 and the transmission port 80 of the SFP optical transceiver 8 is connected to the optical isolator 901 And is reflected by the optical filter unit 91 and optically connected to the input adapter 93. [

By optically connecting the optical connection port converter 9 and the bragg grating-incorporated optical fiber connector 6 to the transmission port 80 and the reception port 81 of the SFP optical transceiver 8 of Fig. 9, The number of optical fiber patch cords required for the SFP optical transceiver 8 can be reduced to one while controlling the wavelength.

Although the optical isolator 901 and the optical filter unit 900 are separated from each other in the above embodiment, in the actual implementation, the optical isolator 901 and the optical filter unit 900 are coupled to each other It can be produced in one block. In addition, the optical filter unit 900 may use one or more optical filters to perform various types of wavelength division and combining functions.

FIG. 18 shows the optical filter wavelength characteristic diagram of the optical filter unit 900. FIG.

18 (a) shows a case where different wavelength bands are separated by using the optical communication wavelength band C-band and the L-band as a wavelength edge filter, FIG. 18 (b) FIG. 2 is a graph showing a wavelength characteristic in a case where different wavelength bands are separated by using a wavelength band.

The wavelength characteristic line 920 indicates the transmission characteristic of the optical filter unit 91 and the wavelength characteristic line 921 indicates the reflection characteristic of the optical filter unit 91. [

The wavelength? 3 is usually in the range of 1560 to 1565 nm, and the wavelength? 4 is in the range of 1570 to 1575 nm.

In another embodiment, when the optical communication wavelength band C-band and the L-band are separated by using the wavelength band transmission filter, the wavelength characteristic diagram 922 indicates the transmission characteristic of the optical filter unit 91 and the wavelength characteristic graph 923 Represents the reflection characteristic of the optical filter unit 91. [

The wavelength? 1 is usually in the range of 1518 to 1523 nm, and the wavelength? 2 is in the range of 1528 to 1533 nm.

Although the embodiment of the wavelength characteristic of the optical filter unit 900 is applied to the case of C-band and L-band, it can be applied to an optical communication system using different wavelength bands. For example, in a coarse wavelength division multiplexing (CWDM) transmission network having a wavelength interval of 20 nm, not only can different CWDM wavelength channels be distinguished, but also arbitrary different wavelengths can be distinguished even in the same CWDM channel wavelength band.

1: Fiber optic patch cord 2: Ferrule
3: Sleeve 4: Fiber
5: Temperature compensator 6: Connector
8: optical transceiver 9: optical connection port converter
9: housing 10: first optical connection
11: second optical connection part 12: optical cable cord
20: fine hole 22: inner pupil
30: inner pupil 31: end
40: Optical fiber 41: Bragg grating
42: outer jacket 43: inner jacket
40: Core 61: First connection
62: second connecting portion 63: optical fiber fixing structure
70: Optical fiber 71: Bragg grating
80: transmit port 81: receive port
82: Transmission optical component 83: Receptacle
90: housing 91: input adapter
92: first output plug 93: second output plug
610: housing 611: lever
612: Fixing groove 81: Transmission optical part
613: connection groove 614: pupil
615: coupling groove 620: housing
621: guide 622: fixed end
624: spring 630: first ferrule
631: first sleeve 631: fine hole
633: sloped surface 640: first sleeve
641: Hexagon body 642: Circular tube
643: pupil 644: dilated pupil
650: Temperature compensation structure 651: Temperature compensator
652: sloped surface 652: fastener
653: fine hole 654: fixed end
655: flange 656: fine hole
657: protrusion 658: insertion groove
660: second sleeve 661: first pupil
662: second pupil 670: second ferrule
671: fine hole 672: inclined surface
673: slope 800: broadband spectrum
801: Bragg grating reflection spectrum 802: Oscillation spectrum
810, 811, 812, 813: oscillation spectrum 900: optical filter unit
901: Optical isolator

Claims (11)

A reflector built-in optical fiber connector in which a reflection center wavelength shift is compensated in a reflector,
One end of the first connector is a first connector having a plug shape and the opposite end of the first connector is a second connector having a form of a standard adapter into which an optical fiber connector can be inserted or a receptacle, Wherein the connecting portion and the second connecting portion are optically connected to the other optical module by the optical fiber connecting structure.
The optical fiber connector as set forth in claim 1, wherein the reflector is selected from a thin film filter which is dependent on a brass grating or a wavelength or a thin film filter which is independent of a wavelength.
The optical fiber connector according to claim 1,
A first sleeve;
A first ferrule formed with a fine hole and fixed to one end of the first sleeve;
A temperature compensator for compensating for a change in the reflection wavelength of the brass lattice due to a change in temperature of the external environment, the temperature compensator being accommodated in the inner space of the first sleeve, wherein the fine holes forming the same axis as the fine holes of the first ferrule are formed, ;
A second sleeve accommodating and fixing the first sleeve and the temperature compensating member in an inner space;
A second ferrule formed with a fine hole coaxial with the fine holes of the first ferrule and the temperature compensating member and fixed to one end of the second sleeve;
The optical fiber connector according to claim 1, further comprising an optical fiber having a bragg grating positioned between the first ferrule and the temperature compensating body in the inner space of the first sleeve and mounted in the fine hole.
4. The optical fiber connector as set forth in claim 3, wherein the optical fiber mounted in the fine hole is mounted from the end of the first ferrule to the end of the second ferrule.
The optical fiber connector according to claim 3, wherein the temperature compensator is formed by attaching a temperature compensator to an end of a fixture fixed to the first sleeve and the second sleeve.
4. The optical fiber connector as set forth in claim 3, wherein the temperature compensating body is formed integrally with the temperature compensating body at the end of the fixture fixed to the first sleeve and the second sleeve.
4. The temperature compensation body according to claim 3, wherein the temperature compensating body is formed with an insertion groove formed in one of the end of the fixture fixed to the first sleeve and the second sleeve and the temperature compensating body, and the insertion protrusion is formed and coupled to the other end thereof And a reflector built-in optical fiber fixing structure.
The optical fiber connector according to claim 1, wherein the reflector built-in optical fiber connector includes optical connection port converting means.
9. The optical connector according to claim 8, wherein the optical connection port converting means comprises: an input adapter into which a commercial LC type and SC type optical fiber patch cord are inserted; a first output plug and an output second plug identical in shape to a commercial LC connector; Wherein the SFP optical transceiver optically connects the output second plug to a first connection portion of the reflector built-in optical fiber connector when a wavelength band different from the transmission light wavelength and the reception light wavelength is used in the SFP optical transceiver, By connecting the second connection part of the first plug and the reflector built-in optical fiber connector to the transmission port and the reception port of the dual receptacle optical transceiver respectively, the two optical connection ports provided in the SFP optical transceiver are connected to one optical connection port Wherein the optical fiber connector includes a reflector-incorporated optical fiber fixing structure.
The first connecting portion 61 of the optical fiber connector 6 is inserted and optically connected to the adapter or the receptacle of another optical module and the second connecting portion 62 is connected to the first optical portion of the optical fiber patch cord 1 The connection part 10 or the second optical connection part 11 is optically connected and an external resonant laser using an optical connection with the broadband light source semiconductor laser diode is operated so that the optical fiber 12 of the optical fiber patch cord 1, Wherein the optical fiber connector includes a reflector built-in optical fiber fixing structure.
One end of the first connector is a first connector having a plug shape and the other end of the first connector is a second connector having a form of a standard adapter into which an optical fiber connector can be inserted or a receptacle, Wherein the optical fiber connector includes a first optical fiber connector and a second optical fiber connector. The optical fiber connector includes a reflector built-in optical fiber fixing structure, And an external resonance laser is generated at a wavelength of a light source which is optically connected to the transmission optical component (TOSA) of the receptacle type optical transceiver (8) An optical connection method using an optical fiber connector having an optical fiber fixing structure.

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