KR100327300B1 - Dispersion compensated fiber module and optical amplifier using the same - Google Patents

Abstract

Disclosed is a dispersion compensating optical fiber module that can be manufactured at low cost and light weight, and an optical amplifier using the same. The dispersion compensating optical fiber module of the present invention comprises: a dispersion compensating optical fiber for compensating only a dispersion amount corresponding to a half of dispersion amount of an optical signal dispersed while passing through a transmission optical fiber for optical communication; A dispersion compensating optical fiber which is connected to one end of the dispersion compensating optical fiber to receive the dispersion compensating optical signal emitted from one end of the dispersion compensating optical fiber while making the dispersed optical signal enter the dispersion compensating optical fiber, A first curator having a bidirectional terminal and an output terminal for outputting the dispersion compensating optical signal; And means for re-incident on the other end of the dispersion-compensating optical fiber, the dispersion-compensated optical signal being transmitted through the dispersion-compensating optical fiber and coming to the other end of the dispersion-compensating optical fiber. Meanwhile, the optical amplifier of the present invention comprises: a first amplification stage connected to an input terminal of the first circulator, for amplifying the attenuated and dispersed optical signal; And a second amplification stage connected to the output terminal of the first curator and for amplifying the dispersion-compensated optical signal to a second amplification stage.

Description

Dispersion Compensated Fiber Module and Optical Amplifier Using the Dispersion Compensated Fiber Module

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device used in an optical transmission system, and more particularly, to a dispersion compensating optical fiber module that can be manufactured at low cost and light weight, and an optical amplifier using the same.

In the optical transmission system for long-distance optical communication, in the conventional optical communication system, an optical signal is converted into an optical signal by using a laser diode, the converted optical signal is transmitted through the optical fiber, And then converts the weakened optical signal into an electrical signal and then converts the amplified optical signal into an optical signal. Single-mode fiber (hereinafter referred to as 'SMF') is used as the transmission fiber. When optical signals are transmitted through the SMF, the intensity of the optical signal is weakened due to the loss of the optical fiber. The optical signal is spread over time. The optical signal transmitted through the optical fiber is converted from an optical signal to an electric signal by a light receiving element and an electric signal amplifier. In this case, the intensity of the optical signal applied to the light receiving element must be within the reception sensitivity, The spread of the signal must be compensated before it is applied to the light receiving element. Therefore, at present, the weakening of the optical signal intensity is solved by using an optical amplifier, and the dispersion of the optical signal due to the dispersion characteristic of the SMF is achieved by using a dispersion compensated fiber (DCF) . The spread of the signal light to the dispersion characteristic of the SMF becomes more severe as the transmission speed increases. The allowable range of optical signal spread is 12,000 cd / nm for 2.5 Gbps and 1000 cd / nm for 10 Gbps.

The tolerance of the dispersion characteristic according to the above-mentioned transmission speed must be compensated at an arbitrary position between the optical transmitter and the optical receiver when transmitting the optical signal, and the existing relay distance should be maintained.

In order to simultaneously compensate for the loss and dispersion of the optical signal as described above, a DCF is connected to the optical amplifier to amplify the weakened and dispersed optical signal through the SMF, and at the same time, the dispersion is compensated. In order to maintain the optical signal amplification while compensating for the dispersion, DCF is connected between the erbium doped optical fiber, which is the amplification medium of the optical amplifier, to solve the amplification and dispersion compensation at the same time.

1 schematically shows a configuration of a conventional optical amplifier for simultaneously achieving optical signal amplification and dispersion compensation. 1, the optical amplifier 100 includes a first optical amplification stage 110a for attenuating and amplifying a dispersed optical signal while passing through a transmission optical fiber for optical communication, a DCF 120, and a second optical amplification stage 110b for amplifying the optical signal weakened by the loss of the DCF. The operation of the optical amplifier 100 thus constructed is as follows. The first optical amplification stage 110a amplifies the weakened optical signal while passing through the transmission optical fiber for optical communication. The DCF 120 between the first optical amplification stage 110a and the second optical amplification stage 110b is transmitted through the transmission optical fiber to compensate for the dispersed optical signal. In general, when SMF is used as a transmission fiber, loss characteristics of general SMF are 0.275 dB / km in a 1550 nm wavelength region and 17 ㎰ / (nm ㎞) in a dispersion characteristic, while loss characteristics of a general DCF are 0.5 dB / The dispersion characteristic is -100 cd / (nm · km). The second optical amplification stage 110b at the rear stage of the DCF 120 amplifies the optical signal attenuated by the loss in the 1550 nm signal wavelength region of the DCF 120. In this DCF, the degree of dispersion compensation differs according to the relay distance. When the relay distance is 80 km, the dispersion of the optical signal is 1360 ㎰ / (nm ㎞), and the length of the DCF required is about 13~14 km. Typically, the DCF is composed of one module for mounting in an optical amplifier unit, and is wound in a device designed for the DCF module to withstand the environment because it is operated in the system. As mentioned above, there is a problem that the mass of the DCF module reaches several kilograms by the necessary DCF of 14 km in length and a specially designed instrument. In addition, there is a problem that a large amount of tens of thousands of dollars is required to purchase a DCF having a length of 14 km.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a DCF module that is light in weight and low in cost while achieving dispersion compensation, and an optical amplifier using the DCF module.

FIG. 1 is a schematic configuration diagram of a prior art optical amplifier for simultaneously achieving optical signal amplification and dispersion compensation; FIG.

FIG. 2A is a schematic configuration diagram of an optical amplifier including a dispersion compensation function according to a first embodiment of the present invention; FIG.

FIG. 2B is a schematic configuration diagram of an optical amplifier including a dispersion compensation function according to a second embodiment of the present invention; FIG. And

2C is a schematic block diagram of an optical amplifier including a dispersion compensation function according to a third embodiment of the present invention.

Description of reference numerals to the main parts of the drawings

100, 200a, 200b, 200c ... Optical amplifier

110a ... The first optical amplification stage 110b ... The second optical amplification stage

120, 220 ... Dispersion compensation optical fiber

230a ... The first circulator 230b ... Second Curator

230c ... Optical power splitter 230d ... reflector

250a, 250b, 250c ... Dispersion compensating optical fiber module

According to an aspect of the present invention, there is provided a DCF module comprising: a DCF for compensating only a dispersion amount corresponding to a half of dispersion amount of an optical signal dispersed while passing through a transmission optical fiber for optical communication; A bidirectional terminal connected to one end of the DCF to receive the dispersed optical signal from the one end of the DCF while causing the dispersed optical signal to enter the DCF, A first circulator having an output terminal for outputting a compensation optical signal; And means for re-entering the other end of the DCF, which is connected to the other end of the DCF, through the DCF and which is only half of the dispersion-compensated optical signal output to the other end.

According to the embodiment of the present invention, as the re-incident means, a second curator, an optical power splitter or a reflector may be used.

According to an aspect of the present invention, there is provided an optical amplifier including: a DCF module of the present invention, wherein the DCF module includes: a first amplifier connected to an input terminal of the first curator, and; And a second amplification stage connected to the output terminal of the first curator and for amplifying the dispersion-compensated optical signal to a second amplification stage. In the DCF module used in the optical amplifier of the present invention, a second curator, an optical power splitter, or a reflector may be used as the re-incident means.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

Since the DCF module is usually embedded in the optical amplifier, the DCF module in addition to the optical amplifier of the present invention will also be described. In the drawings, the same constituent elements are denoted by the same reference numerals in order to avoid redundancy, and a description thereof will be omitted.

[First Embodiment]

2A is a schematic configuration diagram of an optical amplifier 200a including a dispersion compensation function according to the first embodiment of the present invention. Referring to FIG. 2A, the optical amplifier 200a includes a first optical amplification stage 110a, a DCF module 250a, and a second optical amplification stage 110b. The first optical amplification stage 110a amplifies the dispersed and weakened optical signal transmitted through the transmission optical fiber, for example, SMF. The optical signal amplified and not compensated for dispersion is input through the input terminal 231a of the first curator 230a and the optical signal is incident on the bidirectional terminal 233a of the first curator 230a to be dispersively compensated. And is incident on the DCF 220. Since the length of the DCF 220 is only half that of the DCF 120 shown in FIG. 1, dispersion of the optical signal passing through the DCF 220 is also compensated to about half. The optical signal passed through the DCF 220 is applied to the bidirectional terminal 233b of the second circulator 230b and is supplied to the second circulator 230b via the output terminal 232b of the second circulator 230b. And then re-enters the DCF 220 through the bidirectional terminal 233b of the second circulator 230b. The dispersion of the optical signal re-incident on the DCF 220 through the above-described process is compensated by the DCF 220, and the dispersion is compensated to about half of the dispersion. 233a through the output terminal 232a of the first circulator 230a. Then, the amplified signal is applied to the second amplification stage 110b to amplify the weakened optical signal passing through the DCF 220, amplified, and then applied to the SMF, which is a transmission optical fiber, through an optical connector (not shown).

[Second Embodiment]

2B is a schematic block diagram of an optical amplifier 200b including a dispersion compensating function according to a second embodiment of the present invention. The optical amplifier 200b of the second embodiment uses an optical power splitter 230c in place of the second seeker used in the optical amplifier of the first embodiment. The optical amplifier 200b includes a first optical amplification stage 110a, a DCF A module 250b, and a second optical amplification stage 110b. The optical power splitter 230c is a three-terminal element having no directionality. An optical signal whose dispersion is compensated by half through the DCF 220 is applied to the common terminal 233c of the optical power splitter 230c, The signal is split in half and the half is output to the first terminal 231c of the optical power splitter 230c and then to the second terminal 232c and the other half is applied to the optical power splitter 230c And is output to the second terminal 232c and then to the first terminal 231c. The optical signals split in half with the dispersion being half compensated are recombined in the optical power splitter 230c and re-entered into the DCF 220. The optical signal re-incident on the DCF 220 through the above process is compensated for all the dispersion while passing through the DCF 220 and then transmitted through the bidirectional terminal 233a of the first circulator 230a to the first curator 230a Through the output terminal 232a. Then, the amplified signal is applied to the second amplification stage 110b to amplify the weakened optical signal passing through the DCF 220, amplified, and then applied to the SMF, which is a transmission optical fiber, through an optical connector (not shown).

[Third Embodiment]

2C is a schematic configuration diagram of an optical amplifier 200c including a dispersion compensation function according to the third embodiment of the present invention.

In the optical amplifier 200c of the third embodiment, the reflector 230d is used instead of the second seeker or the optical power splitter used in the optical amplifiers of the first and second embodiments. The optical amplifier 200c includes the first light An amplification stage 110a, a DCF module 250c, and a second optical amplification stage 110b. The reflector 230d is a device incorporating a reflection filter for reflecting an optical signal in a 1500 nm band which is a wavelength band of an optical signal. The optical signal whose dispersion is compensated by half through the DCF 220 is applied to the bi-directional terminal 233d of the reflector 230d and the optical signal is reflected by the reflection filter of the reflector 230d and then transmitted to the bi- 233d to re-enter the DCF 220 so that all of the dispersion is compensated. The optical signal whose dispersion has been compensated is output through the output terminal 232a of the first cursor 230a via the bidirectional terminal 233a of the first cursor 230a. Then, the amplified signal is applied to the second amplification stage 110b to amplify the weakened optical signal passing through the DCF 220, amplified, and then applied to the SMF, which is a transmission optical fiber, through an optical connector (not shown).

As described above, when the DCF module and the optical amplifier of the present invention are used, the same dispersion compensation effect can be obtained even when half length DCF is used, and the DCF length The DCF module is light in weight, and the weight of the optical amplifier module including the DCF module is also lightened. In addition, since the DCF is used in half, the price of the optical amplifier including the DCF module becomes low.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention.

Claims (8)

A DCF for compensating only a dispersion amount corresponding to half of the dispersion amount of the dispersed optical signal while passing through the transmission optical fiber for optical communication; A bidirectional terminal connected to one end of the DCF to receive the dispersed optical signal from the one end of the DCF while causing the dispersed optical signal to enter the DCF, A first circulator having an output terminal for outputting a compensation optical signal; And a DCF module connected to the other end of the DCF and having the half-dispersion-compensated optical signal passing through the DCF and coming out to the other end, again entering the other end of the DCF. The apparatus of claim 1, wherein the re-incident means comprises: And a bidirectional terminal connected to the other end of the DCF and receiving the half-dispersion-compensated optical signal, re-entering the other end of the DCF. The apparatus of claim 1, wherein the re-incident means comprises: A bidirectional terminal connected to the other end of the DCF to receive the dispersion-compensated optical signal only halfway and to re-enter the optical signal into the other end of the DCF; Wherein the DCF module is an optical power splitter having an input / output terminal for sending. The apparatus of claim 1, wherein the re-incident means comprises: And a reflector that reflects the dispersion-compensated optical signal only from the other end of the DCF and sends back the optical signal. (a) a DCF which attenuates and disperses a dispersion amount of the optical signal transmitted through the optical transmission fiber, and compensates only a dispersion amount corresponding to half of the dispersion amount; (b) a bidirectional terminal connected to one end of the DCF for receiving the dispersed optical signal, for receiving the dispersed optical signal from the one end of the DCF while making the dispersed optical signal incident on the DCF, A first curator having an output terminal for outputting the dispersion compensating optical signal, (c) a DCF module connected to the other end of the DCF and having means for re-entering the other end of the DCF through the half-only dispersion-compensated optical signal passing through the DCF; A first amplification stage connected to an input terminal of the first curator, for amplifying the attenuated and dispersed optical signal; A second amplification stage connected to an output terminal of the first curator, for amplifying the dispersion-compensated optical signal; . 6. The apparatus of claim 5, wherein the re-incident means comprises: And a bidirectional terminal connected to the other end of the DCF to receive the dispersion-compensated optical signal only in the half of the DCF and re-enter the other end of the DCF. 6. The apparatus of claim 5, wherein the re-incident means comprises: A bidirectional terminal connected to the other end of the DCF to receive the dispersion-compensated optical signal only halfway and to re-enter the optical signal into the other end of the DCF; And an optical power splitter having an input / output terminal for output. 6. The apparatus of claim 5, wherein the re-incident means comprises: And a reflector including a reflection filter for reflecting only the half of the dispersion-compensated optical signal coming from the other end of the DCF and returning it.