KR20180015846A - Optical Amplifier And Method of Manufacturing Optical Amplifier - Google Patents

Abstract

In order to configure an optical amplifier coupled to an optical transceiver using a standardized case that operates in a plug manner, the upper end part of the standardized case including a long face part, a partition part, and a short face part, a cavity part formed in the end face part, a routing hole for mounting amplification optical fiber formed in the long face part are formed. Optical elements for optical amplification and a drive control part are positioned in the cavity part. It is possible to reduce a space of the entire system, utilize a limited space, facilitate an assembly process to improve productivity, by implementing the optical amplifier.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an optical amplifier and an optical amplifier,

The present invention relates to an optical amplifier that can be mounted in the space by providing a separate space in a standardized optical transceiver case.

Due to the diffusion of the Internet and the increase in data services, the demand for broadband services is increasing, and accordingly, the bandwidth increase in the optical communication technology continues. Therefore, it is required to innovate the technology to realize the ultra-broadband era beyond the broadband era have. In the past 10 years, the signaling speed of the optical transmission network, which is a base network for transmitting broadband signals, has been developed from 2.5Gbps to 10Gbps. However, according to the necessity of high-speed Ethernet, the IEEE completed standardization of 40Gbps and 100Gbps Ethernet in mid- -T recommends 40Gbps and 100Gbps OTN that can accept and transmit these signaling traffic. The trend of rapidly increasing bandwidth demands the development of optical transceivers capable of transmitting 40Gbps and 100Gbps. Optical transport networks have played an important role in the delivery of broadband services from the data center to the user terminals. Demand for ultra-wide bandwidths of photonic transmission has been emphasized by the spread of cloud services and data services of mobile devices. For the time being. In particular, 40G / 100G optical transceivers are expected to be replaced by continuous optical fibers for high-capacity / high-speed data centers and Ethernet / optical backbone networks.

A large number of optical transceivers are required for large capacity and there is a trend of miniaturization in order to reduce the space for collecting a large number of optical transceivers. In addition, since various operators do not have mechanism compatibility when they are made into each form, they are standardized with separate standards.

A typical standardization standard is C Form-factor Pluggable (CFP). CFP is divided into CFP, CFP2, and CFP4, and the larger the number, the smaller the number. In particular, CFP2 is the most widely used standard with optimized structure of speed and optical part size desired by telecom companies.

1 is an optical transceiver 10 applied to a dual CFP2 standard. The optical transceiver is provided as a fastening type. The dual CFP2 standard optical transceiver as shown in FIG. 1 is composed of several to several hundred optical networks, and enters a single rack to minimize the space.

In order to receive the optical signal without error, a certain amount of optical power is required, but the optical signal passing through the optical fiber decreases as the optical power increases as the distance increases. An optical amplifier is used to compensate for such optical power loss, and an optical amplifier based on a fiber is an optical amplifier that amplifies the optical signal at the level of light without converting it into an electrical signal. In particular, It is advantageous for most optical communication systems.

In addition, the optical amplifier is required to have optical elements such as an amplifying optical fiber for amplifying light and a pump light source for generating exciting light. Such optical parts have a certain size, and optical elements and optical fibers have a bending and temperature A guide, a holder, etc. are used. Due to such additional components, it is not practical to make the optical fiber-based optical amplifier smaller than a certain size.

As the optical signal speed increases to 40G / 100G, the required optical power of a certain size becomes higher and the optical amplifier must be used.

As mentioned earlier, in the recent years, all optical components have been standardized as CFP2, and each slot space is directly associated with money. That is, if one optical transceiver is used, one optical amplifier is additionally required, resulting in two slots, which are costly.

It is therefore an object of the present invention to provide a new type of optical amplifier or optical transceiver for use of an optical transceiver and an optical amplifier by minimizing the use of a standardized slot space, that is, increasing space utilization.

In addition, the assembly must be configured in a manner that facilitates assembly, thereby improving productivity by shortening assembly time.

According to an aspect of the present invention, there is provided an optical amplifier coupled to an optical transceiver using a standardized case, the optical amplifier having a long surface, a partition, A cavity portion formed in the end face portion, a routing hole formed in the scene portion, and the cavity portion and the routing hole are formed so as not to affect the outer shape of the standardized case, Optical devices for optical amplification and a drive control unit are located inside the cavity, and the amplification optical fiber is located in the routing hole.

According to an embodiment of the present invention, the drive control unit formed on the flexible printed circuit board is located on the case side of the cavity, and the optical components above the drive control unit, which is the opposite side of the case, include a pump light source, an isolator, a wavelength division multiplexing coupler, Filters, and monitoring tap photodiodes.

According to an embodiment of the present invention, a cavity is formed at the center of the partition, and an upper surface of the partition includes a coupling hole into which an electrical connector can be coupled, .

According to one embodiment, a plurality of supports of the letter 'A' shape located at the outer periphery of the cavity of the end face portion, two of the plurality of support portions are provided in the space where the cavity is not present between the end face portion and the partition portion And is coupled to the surface of the partition.

According to one embodiment, the amplifying optical fiber located in the routing hole, the driving control part located in the cavity, and the optical part formed above the driving control part are fixed by a silicone gel type thermosetting molding material, and when the molding material is fixed, And is coupled to the upper end portion.

According to one embodiment, the amplifying optical fiber is a low-bending loss optical fiber.

According to one embodiment, an optical amplifier coupled to an optical transceiver using a standardized case that operates in a plug-type configuration operates at a top end of a standardized case consisting of a long face, a compartment, a short face, Wherein the driving control section is located on the case side surface inside the cavity, and the amplifying optical fiber is arranged above the driving control section along the outer surface of the cavity section And the optical parts for optical amplification are placed in the optical fiber for amplification which is wound and positioned in an elliptical shape.

According to one embodiment, the drive control unit is formed of a flexible printed circuit board, and the optical parts are formed of a combination of a pump light source, an isolator, a wavelength division multiplexing coupler, a wavelength tunable optical filter, and a monitoring tap photodiode .

According to an embodiment of the present invention, a cavity is formed at the center of the partition, and an upper surface of the partition includes a coupling hole into which an electrical connector can be coupled, .

According to one embodiment, a plurality of supports of the letter 'A' shape located at the outer periphery of the cavity of the end face portion, two of the plurality of support portions are provided in the space where the cavity is not present between the end face portion and the partition portion And is coupled to the surface of the partition.

According to one embodiment, the amplifying optical fiber, the driving control unit, and the optical parts located in the cavity are fixed by a silicone gel type thermosetting molding material, and when the molding material is fixed, the molding material is coupled to the upper end.

According to one embodiment, an optical amplifier coupled to an optical transceiver using a standardized case that operates in a plug-type configuration operates at a top end of a standardized case consisting of a long face, a compartment, a short face, A cavity portion formed in a shape that does not affect the outer shape of the case standardized in the end face portion, a single type amplification module portion coupled to the cavity portion, and a driving control portion located at the bottom of the amplification module portion, And the optical amplifying optical fiber is placed in an elliptical shape along the outer surface of the cavity, and optical parts for optical amplification are positioned inside the amplifying optical fiber wound around the amplifying optical fiber.

According to one embodiment, the drive control unit is formed of a flexible printed circuit board, and the optical parts are formed of a combination of a pump light source, an isolator, a wavelength division multiplexing coupler, a wavelength tunable optical filter, and a monitoring tap photodiode .

According to an embodiment of the present invention, a cavity is formed at the center of the compartment, and a coupling hole through which an electrical connector can be coupled is formed on an upper surface of the compartment, Of the flexible connector are positioned.

According to one embodiment, the amplification module unit is fixed through the upper end portion and the fastening member.

According to an embodiment of the present invention, the amplifying optical fiber, the driving control unit, and the optical parts located in the amplification module unit are fixed by a silicone gel type thermosetting molding material.

According to one embodiment, the optical transceiver including the above-mentioned optical amplifier includes an optical transmitter including a laser and a modulator, a light receiver including a photodiode, the optical amplifier, the optical transmitter, and the optical receiver, And a control unit of the optical amplifier and a main control unit are connected to each other, and the output of the optical transmitter is connected to the main control unit, the electrical connector to be connected to the compartment, the optical transmission unit and the air feed unit are located in the scene, And is input to the optical amplifier.

According to another aspect of the present invention, there is provided a method of manufacturing an optical amplifier coupled to an optical transceiver using a standardized case, A step of forming an upper end portion of a standardized case including a first end portion and a second end portion, forming a routing hole in the scene portion, and mounting an amplifying optical fiber having a low bending loss in the routing hole, Forming a hollow portion while maintaining a shape that does not affect the outer shape of the standardized case, positioning a drive control portion formed of optical components and a flexible printed circuit board for optical amplification in the hollow portion, A step of forming a cavity, connecting the amplifying optical fiber with the optical parts through the cavity, and positioning the connector of the drive control part, .

A method of fabricating an optical amplifier coupled to an optical transceiver using a standardized case tightening and operating in the form of a plug in accordance with one embodiment includes the steps of providing a standardized, And a drive control unit formed of a flexible printed circuit board is disposed on a side of a case inside the cavity, the cavity being formed in the cavity, Positioning an optical fiber within the amplifying optical fiber wound around the driving control unit by winding an amplifying optical fiber having a low bending loss characteristic along an outer surface of the cavity in an elliptical shape, And positioning the connector of the drive control unit through the cavity.

A method of fabricating an optical amplifier coupled to an optical transceiver using a standardized case tightening and operating in the form of a plug in accordance with one embodiment includes the steps of providing a standardized, Forming an upper end portion of the case, forming a cavity portion in the end face portion while maintaining a shape that does not affect the outer shape of the standardized case, joining the amplification module portion to the cavity portion, And positioning the flexible connector of the drive control unit from the inside to the outside of the amplification module unit in the cavity, wherein the drive control unit formed of the flexible printed circuit board is located at the bottom of the amplification module unit, The amplifying optical fiber having the low bending loss characteristic is wound in an elliptical shape along the outer surface of the amplification module part, And it characterized in that the position of optical components for optical amplification in the optical fiber inside the amplification.

According to an embodiment of the present invention, there is provided a method of manufacturing a semiconductor device, comprising the steps of: forming a plurality of 'A' shaped supports on the outside of the cavity; amplifying optical fibers located in the routing holes; And a step of fixing by a thermosetting molding material.

As described above, according to the present invention, there is an advantage that an optical amplifier can be realized by maximizing utilization of limited space in a standardized optical transceiver without a separate slot space.

As a result, the system price can be reduced, cost competitiveness can be increased, and efficiency can be increased.

In addition, a separate cavity can be formed to facilitate the assembly, shorten the assembly time, and improve the productivity.

1 optical transceiver with dual CFP2 standard
Figure 2 Optical transceiver case configuration with CFP2 standard
3 CFP2 upper end of the standardized case
Figure 4 Top of CFP2 standardized case
Figure 5 CFP2 embodiment in which the standardized case is coupled to the body
6 is a schematic diagram of an embodiment 1
Fig.
Fig.

FIGS. 2 to 5 are views of a normalized case 100 of an optical transceiver applied to a conventional CFP 2. FIG. 2 is a top view of the case of the CFP 2 coupled with the bottom end 120 of the case. As can be seen from the figures shown in Fig. 2, the size of the case must satisfy a very small size.

3 to 5 show the shape of the upper end 110 of the case of the conventional CFP2. The upper part 110 serves to separate a scene part 130 serving as a cover where the optical transceiver is located and parts constituting the optical transceiver, And the electrical connector 142 is coupled to the female electrical connector 43. The electrical connector 142 is connected to the female connector 143 and the electrical connector 142 is connected to the female electrical connector 143 And an end face 150 positioned on the upper surface of the female electrical connector 143.

2, 4 and 5, the outer shape of the end face 150 is standardized for general use, and the case 100 is of a very small size. Therefore, when an optical amplifier is required, The optical amplifier can not be inserted into the structure.

Figs. 6 to 8 are embodiments of a structure for accommodating an optical amplifier in a case of a standardized, small-sized CFP2 in order to solve this problem.

(Embodiment 1) - Fig. 6

In order to apply to a system having the specification of CFP2, a standardized case should be used. Therefore, the external structure of the case must be used equally.

The upper end 210 of the case 210 has the same shape as the upper end 210 of the case 210. The upper end 210 includes the scene 230, the partition 240,

The optical amplifier includes an amplification optical fiber 231 for amplification such as EDF, optical components (pump light source, isolator, wavelength division multiplexing coupler, tunable optical filter, monitoring tap photodiode) And a drive control unit.

Optical components are sensitive to the external environment such as vibration due to their characteristics, and the loss of optical power is apparent with respect to optical fiber bending and the like. Therefore, it is very important to mount an optical component, which is constituted by packaging a plurality of optical components in general.

In order to configure the optical amplifier in the upper part 210, a routing hole 232 is formed in the scene part 230 by winding an EDF (Erbium-doped fiber) 231 having a length required for amplification. The depth of the routing hole 232 should be smaller than the thickness of the standardized top 210. Further, the routing hole 232 can be formed in a circular shape and can be formed in an elliptical shape. In consideration of the shape of the case of the CFP 2, an elliptical shape is preferable. Also, the EDF 231 used should use a special EDF having low bending loss function, not a general EDF. This is because of the size of the case of CFP2, the use of conventional EDF results in a large bending loss. Therefore, when the routing hole 232 is formed in a circular or elliptical shape, the radius of the circular portion can be 5 mm or more, but the routing hole 232 is formed to have the largest radius in consideration of the shape of the upper end portion 210 desirable. The routing hole 232 is connected to the EDF 231 through the partition 240 and the optical elements of the cross section 250. It is preferable to use a separate member which forms a separate groove to connect the EDF 232 or prevent the EDF 232 from moving. Further, the EDF 231 mounted on the routing hole 232 must be fixed using a molding material or the like. The type of the molding material may be silicon or the like.

The conventional partition 140 has a configuration in which a lateral portion of a separate case upper end portion 110 is connected. However, in the present invention, a cavity 241 is formed at the center of the partition 240. As mentioned above, the cavity 241 is essentially required because the EDF 232 must be connected from the scene 230 to the end face 250. Further, the cavity 241 provides a space for testing the optical amplifier alone or connected to the main control unit through the connector of the drive control unit, which will be described later.

The partition 240 has the same fastening hole 242 as the conventional one, and the fastening hole 242 is coupled to the electric connector. However, since the existing partition 140 has no cavity and thus has a large area for supporting the electrical connector, the partition 240 is robustly coupled. However, since the partition 240 proposed in the present invention has a cavity, The space that can be made is reduced. This problem can be solved by forming a plurality of support portions 252 on one surface of the partitioning portion 240 to widen the support area of the electrical connector. Therefore, it is preferable that two of the plurality of supporting portions 252 are formed in the vicinity of the fastening hole 242.

In the conventional end face portion 150, only the structure for heat radiation is formed without using a separate internal space. The cavity portion 251 is formed in the end face portion 250 so that the shape of the outer frame of the CFP2 of the case upper end portion 210 should not be changed. The drive control unit 253 and the optical components 254 for constituting the optical amplifier are positioned inside the cavity 151. It is preferable that the drive control unit 253 is formed of a flexible printed circuit board and that the optical parts 254 are formed by the optical elements in which the low banding optical fiber is used and the miniaturized optical parts Should be used. The optical components 254 comprise a combination of a pump light source, an isolator, a wavelength division multiplexing coupler, a tunable optical filter, and a monitoring tap photodiode. The pump light source, the isolator, and the wavelength division multiplexing coupler are constituted of optical fiber based optical amplifiers generally used, and the wavelength variable optical filter is used to reduce the optical signal to noise ratio at the optical amplifier output. The connector of the drive control unit 253 is connected through the cavity 241 of the partition 240 to connect to the main control unit. The connector of the drive control unit 253 connected to the cavity 241 can function not only as a connection but also as a space and a function for performing module-by-module testing after coupling. This feature can be used to determine whether there is an abnormality in each module and to manage it easily.

In order to mount the drive control unit 253 and the optical parts 254 in the cavity 251, the drive control unit 253 is first placed on the lower surface of the cavity 251. Here, the lower side means the upper side in the case of the whole optical transceiver. After positioning the drive control unit 253, the optical components 254 are placed on the drive control unit 253. At this time, a separate partitioning member can be used so that the drive control unit 253 does not cause a shot by the case of the optical parts 254.

Since the drive control unit 253 and the optical components 254 are mounted on the upper end of the case, when the case is finally coupled, the drive control unit 253 and the optical components 254 are viewed downward, The optical component 253 and the optical components 254 must be fixed. In order to fix, it must be fixed with molding material. A silicone-type thermosetting molding liquid is used as the molding material. Such silicone type molding liquid is preferable for heat dissipation because heat transfer property is better than other molding materials and silicone type molding liquid abuts against the upper surface of the case when cured and is effective for heat dissipation. In addition, a separate jig is prepared to prevent the molding liquid from leaking into the cavity 241, and is injected using a needle. The molding liquid is then cured. Since the molding liquid is guided by using a jig, the shape can be formed by using a jig after the molding liquid is cured, and the shape can be made in consideration of the shape of the CFP 2 and the surface area capable of radiating heat. Therefore, the drive control unit 253 and the optical components 254 are molded at one time. Further, in molding, a separate cover-like member may be used on the surface exposed to the electrical connector in consideration of ease of use and reliability. When the cavity 251 as a whole is molded as shown in FIG. 5, the cross-sectional portion 250 should not interfere with the facing parts.

(Embodiment 2) - Fig. 7

Figure 7 shows another embodiment of the present invention. The upper end portion 310 of Embodiment 2 is composed of a scene portion, a dividing portion, and an end portion, and the dividing portion and the supporting portion have the same shape and characteristics as those of Embodiment 1. [ Further, a cavity portion is provided in the end face portion, and a drive control portion is positioned in the bottom of the cavity portion. The connector of the drive control unit can be connected to the main control unit in the scene through the cavity of the compartment, and the optical amplifier can be tested using the connector in the cavity.

And the amplifying optical fiber is mounted on the driving control unit so as to have an elliptical shape along the outer portion of the cavity. At this time, in order to guide the amplification optical fiber, it is also possible to fix the optical fiber by using grooves or support members inside the cavity. The optical components can be mounted inside the optical fiber for amplification mounted in an elliptical shape and the drive control unit, the amplification optical fiber and the optical parts can be fixed at once by using the molding liquid as in the first embodiment. Also, a cover or the like may be used as mentioned in Embodiment 1. [

(Embodiment 3) - Fig. 8

Fig. 8 shows another embodiment of the present invention. The third embodiment has a structure similar to that of the second embodiment. However, it has a better effect in terms of productivity, ease of testing after optical amplifier assembly, and the like.

In Embodiment 3, the optical amplifier is mounted on the end face portion, but the optical amplifier is implemented by using a separate module and an amplification module portion instead of directly mounting the optical amplifier on the upper end portion. .

The amplification module part locates the drive control part at the bottom, and positions the connector of the drive control part outside the amplification module part. The connector of the drive control unit may be connected to the main control unit through the cavity of the partition unit, and may be used for a separate test purpose.

Upstream of the drive control unit, the amplifying optical fiber is wound around the outer periphery of the amplification module unit to be mounted in an elliptical shape, the optical components are placed in the optical fiber unit, and the components are fixed in the amplification module unit .

In this embodiment, the amplifying optical fiber is mounted inside the amplifying module, but a module may be formed in the amplifying module except for the amplifying optical fiber by forming a routing hole in the scene.

10 Optical transceivers with dual CFP2 specifications
11 Female electrical connector
12 electrical connector
100 cases
110, 210, 310, 410,
120 lower end
130, and 230,
131 main control unit
140, 240 compartment
142 electrical connector
143 female electrical connector
150, < / RTI &
160, 242 fastening hole
231 Optical fiber for amplification
251 Cavity
232 routing hole
254 Optical components
253 drive control unit
241 joint
252 Support

Claims (15)

Claims [1] An optical amplifier coupled to an optical transmitter / receiver using a standardized case,
An upper end portion of a standardized case including a long face portion, a partition portion, and a short face portion;
A hollow portion formed in the end face portion;
A routing hole on which an amplifying optical fiber having a low bending loss is mounted;
The cavity and the routing hole are formed in a shape that does not affect the outer shape of the standardized case. Inside the cavity, a pump light source for amplifying the light, an isolator, a wavelength division multiplexing coupler, a tunable optical filter, An optical amplifier coupled to the optical transceiver using the standardized case, characterized in that optical devices composed of one or more combinations and a drive control unit formed of a flexible printed circuit board are located, and the amplifying optical fiber is located in the routing hole. .
The method according to claim 1,
The optical fiber connector according to claim 1, wherein the dividing portion includes a cavity at the center, the amplifying optical fiber mounted in the routing hole is connected to the optical parts of the end face through a cavity, Wherein the flexible connector of the drive control unit is located in the cavity, and the flexible connector of the drive control unit is located in the cavity.
The method according to claim 2,
And a plurality of support portions of '?' Shape located at the outer periphery of the cavity portion of the end face portion, wherein two of the plurality of support portions are coupled to the face of the partition portion in a space free of the cavity between the end face portion and the partition portion The optical amplifier being coupled to an optical transceiver using a standardized case.
The method according to claim 2,
The molding material is fixed to the upper end when the amplifying optical fiber located in the routing hole, the driving control part located in the cavity, and the optical part formed above the driving control part are fixed by the silicone gel type thermosetting molding material. Gt; optical amplifier < / RTI >
A method of manufacturing an optical amplifier coupled to an optical transceiver having a top end of a standardized case including a long face, a compartment, and a short face,
Forming a routing hole in the scene portion and mounting an amplifying optical fiber having a low bending loss in the routing hole;
Forming a hollow portion in the end face portion while maintaining a shape that does not affect the outer shape of the standardized case and positioning a drive control portion formed of optical components and a flexible printed circuit board for optical amplification in the hollow portion;
And a step of forming a cavity in the center of the partition and connecting the amplifying optical fiber and the optical parts through the cavity and positioning the connector of the drive control unit .
The method according to claim 5,
Forming a plurality of 'A' shaped supports on the outside of the cavity;
Further comprising the step of fixing the amplification optical fiber located in the routing hole, the drive control unit located in the cavity, and the optical components using a silicone gel type thermosetting molding material.
Claims [1] An optical amplifier coupled to an optical transmitter / receiver using a standardized case,
An upper end portion of a standardized case composed of a long face portion, a partition portion, and a short face portion;
A hollow portion formed in the end face portion in a shape that does not affect the outer shape of the case normalized;
A driving control section formed of a flexible printed circuit board is disposed on a case side surface inside the cavity, and an amplifying optical fiber having a low bending loss characteristic above the driving control section is wound and positioned in an elliptic shape along an outer surface of the cavity section, Characterized in that optical parts composed of a combination of at least one of a pump light source for optical amplification, an isolator, a wavelength division multiplexing coupler, a tunable optical filter, and a monitoring tap photodiode are disposed in the amplification optical fiber. An optical amplifier coupled to a transceiver.
The method of claim 7,
Characterized in that a cavity is formed in the center of the partition and a coupling hole in which an electrical connector is coupled is formed on an upper surface of the partition, Gt; optical < / RTI >
The method of claim 8,
And a plurality of support portions of '?' Shape located at the outer periphery of the cavity portion of the end face portion, wherein two of the plurality of support portions are coupled to the face of the partition portion in a space free of the cavity between the end face portion and the partition portion The optical amplifier being coupled to an optical transceiver using a standardized case.
A method of manufacturing an optical amplifier coupled to an optical transceiver having a top end of a standardized case including a long face, a compartment, and a short face,
A cavity is formed in the end face portion while maintaining a shape that does not affect the outer shape of the standardized case, a driving control portion formed of a flexible printed circuit board is positioned on the case side face inside the cavity portion, Positioning the optical components in the optical fiber for amplification, the amplification optical fiber having a bending loss characteristic being wound and positioned in an elliptical shape along the outer surface of the cavity portion;
And forming a cavity in the center of the compartment and positioning the connector of the drive control through the cavity. ≪ Desc / Clms Page number 21 >
11. The method of claim 10,
Forming a plurality of 'A' shaped supports on the outside of the cavity;
Further comprising the step of fixing the amplification optical fiber located in the routing hole, the drive control unit located in the cavity, and the optical components using a silicon gel type thermosetting molding material.
Claims [1] An optical amplifier coupled to an optical transmitter / receiver using a standardized case,
An upper end portion of a standardized case composed of a long face portion, a partition portion, and a short face portion;
A hollow portion formed in the end face portion in a shape that does not affect the outer shape of the case normalized;
A single type amplification module coupled to the cavity;
A driving control unit formed of a flexible printed circuit board is located at the bottom of the amplification module unit and an amplifying optical fiber having a low bending loss characteristic above the driving control unit is wound in an elliptical shape along the outer surface of the amplification module unit, Wherein the optical parts including a combination of at least one of a pump light source, an isolator, a wavelength division multiplexing coupler, a wavelength tunable optical filter, and a monitoring tap photodiode for optical amplification are disposed inside the optical fiber for optical transmission and reception using a standardized case An optical amplifier coupled to a device.
The method of claim 12,
Wherein a flexible connector of the drive control unit is located inside the amplification module unit from the inside of the amplification module unit, Wherein the optical amplifier is coupled to an optical transceiver using a standardized case.
A method of manufacturing an optical amplifier coupled to an optical transceiver having a top end of a standardized case including a long face, a compartment, and a short face,
Forming a cavity in the cross section while maintaining a shape that does not affect the outer shape of the standardized case;
Coupling the amplification module section to the cavity section;
Forming a cavity in the center of the compartment and positioning the flexible connector of the drive control unit in the cavity from the inside to the outside of the amplification module;
A driving control unit formed of a flexible printed circuit board is located at the bottom of the amplification module unit and an amplifying optical fiber having a low bending loss characteristic above the driving control unit is wound in an elliptical shape along the outer surface of the amplification module unit, And positioning the optical components for optical amplification within the optical fiber for the optical amplifier.
11. The method of claim 10,
Forming a plurality of 'A' shaped supports on the outside of the cavity;
Further comprising the step of fixing the amplification optical fiber located in the routing hole, the drive control unit located in the cavity, and the optical components using a silicon gel type thermosetting molding material.

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