KR20050014104A - The source of optical fiber for L-band - Google Patents

Abstract

PURPOSE: An L-band(Long wavelength-band) optical fiber optical source is provided amplify power of an L-band natural light without using expensive non-pumping EDF(Erbium-Doped Fiber). CONSTITUTION: An L-band optical fiber optical source includes an erbium-added optical fiber amplifier(203), an isolator(200), a wavelength division multiplexer(206), a wavelength selective mixer(205), a reflector(201), and an FBG(204). The erbium-added optical fiber amplifier amplifies a pumping light. The isolator prevents an uplink propagation of an output of the erbium-added optical fiber amplifier. The wavelength division multiplexer receives a pumping source. The wavelength selective mixer divides a reverse natural light into an L-band(Long wavelength-band) and a C-band(Conventional-band). The reflector reflects the L-band light. The FBG(Fiber Bragg Grating) selectively reflects the C-band light.

Description

L-band fiber light source {The source of optical fiber for L-band}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber light source, and more particularly, to a long wavelength band (L-band, 1565 nm to 1605 nm) optical fiber light source used for widening an amplification band of an optical fiber light source.

Today, as communication demand increases, wavelength division multiplexing (WDM) optical communication is widely adopted, and the wavelength band used to generate accurate characteristics of various optical components used in such wavelength division multiplexing optical communication is generated. It is necessary to have a light source.

1 is a diagram illustrating a configuration of a general erbium-doped optical fiber light source. An optical isolator 100 for blocking the light flowing backward with the conventional Erbium-doped optical fiber amplifier (EDF), the EDF 102 which is an amplification medium, and the pump light emitted from the pump optical laser diode 105 are wavelength-division multiplexing apparatus 103 ) To enter. In the intermediate EDF 102, the pump light excites the erbium, which is a rare earth ion added to the EDF 102, to amplify the optical signal.

Such a structure is the same structure as the structure for amplifying the existing 1530 nm to 1560 nm wavelength band (hereinafter referred to as C-band). However, unlike C-band light, which uses a high inversion state, the L-band light becomes less efficient by using a lower inversion state, thereby increasing the length of the expensive EDF 102 to increase the power of the L-band. It has the disadvantage of using 4 to 8 times longer.

Several methods have been proposed to increase the efficiency of L-band light sources. Inserting a reflection mirror in front of the wavelength selective coupler of the light source to reenter the reverse C-band ASE generated in the EDF by the excitation light source back to the EDF and inserting a FBG to selectively select a part of the reverse C-band ASE. The method of re-incidence and the method of adding the non-pumped EDF and converting the reverse C-band ASE into the L-band light to reentr it are known. Among the above methods, the method using the non-pumped EDF is known to be efficient, but it is expensive because additional EDF is required.

The present invention is to solve the above-mentioned problems, an object of the present invention in developing an optical fiber light source of the L-band amplification band, which is essential for increasing the communication capacity, a broadband that can increase the pumping efficiency in the long wavelength band To provide an erbium-added optical fiber light source.

It is still another object of the present invention to provide a broadband Erbium-doped optical fiber light source having an additional expensive non-pump EDF-free structure that reduces cost and improves reliability by replacing a passive element.

1 is a block diagram showing an optical fiber light source according to a conventional embodiment;

2 is a block diagram showing an embodiment of an L-band optical fiber light source according to the present invention;

3 is a block diagram of the experimental apparatus 3 of the optical fiber light source compared with the L-band optical fiber light source according to the present invention;

4 is a block diagram of the experimental apparatus 4 of the optical fiber light source compared with the L-band optical fiber light source according to the present invention;

5 is experimental data showing the effect of the output power spectrum of the L-band optical fiber light source according to the present invention,

6, 7 and 8 are block diagrams showing another embodiment of the L-band optical fiber light source according to the present invention.

* Description of drawing number

200 ... Isolator 201 ... Reflector

202 Pump optical laser diode 203 Erbium-doped fiber amplifier

204 ... FBG 205 ... Wavelength Splitter

206 ... wavelength division multiplexer

In order to achieve the above objects, the L-band optical fiber light source according to the present invention,

An erbium-doped optical fiber amplifying unit 203 pumped by a pump light source and an isolator 200 which prevents the reverse movement in the reverse direction at the rear end of the erbium-containing optical fiber amplifying unit, the pump light source in front of the erbium-added optical fiber amplifying unit An input wavelength division multiplexing device 206 is provided, which is located in front of the wavelength division multiplexing device and converts an amplified spontaneous emission generated from an erbium-doped fiber amplifier into L-band and C-band. A wavelength selective coupler 205 for dividing, a reflector 201 positioned in front of the wavelength selective coupler and reflecting the L-band light, and an FBG 204 for selectively reflecting the C-band light. do.

According to another embodiment of the present invention, in the structure of an optical fiber light source, an erbium-doped optical fiber amplifier 203 for amplifying pump light and a wavelength division multiplexing device 206 for inputting a pump light source to the front and rear ends of the erbium-doped optical fiber amplifying unit, respectively. ) And a second wavelength selective coupler 205b for dividing the reverse natural emission light into L-bands and C-bands, and located in front of the wavelength division multiplexing device and generating reverse natural emission from an erbium-doped optical fiber amplifier. A first wavelength selective coupler 205a for dividing the light into L-bands and C-bands, and a reflector 201 and C-band light selectively reflecting the L-band light in front of the first wavelength selective coupler; The reflecting FBG 204 is connected, the other end of the FBG and the second wavelength selective coupler 205b are connected by a first isolator 200a which prevents the reverse direction, and the second wavelength selective coupler of the second wavelength selective coupler Connect to the back end In that it comprises a second isolator (200b) to prevent the progress of the reverse control provides the L- band optical fiber light source according to claim.

As the structure capable of replacing the wavelength selective coupler 205, the reflector 201 and the FBG 204, in the present invention, an erbium-doped optical fiber amplifier 203 for amplifying pump light and a rear end of the erbium-doped optical fiber amplifying unit It is provided with an isolator 200 to prevent the reverse in the reverse direction, the front end of the erbium-added optical fiber amplification unit is provided with a wavelength division multiplexing device 206 to which a pump light source is input, and is located in front of the wavelength division multiplexing device It provides a power increase structure of the L-band optical fiber light source, characterized in that it comprises an L-band reflection filter 208 for selectively reflecting the L-band of the reverse natural emission light generated in the erbium-added optical fiber amplifier. In addition, the front-end of the L-band reflection filter provides a power increase structure of the L-band optical fiber light source, characterized in that it comprises a FBG (204) for reflecting the C-band light. Here, the L-band reflection filter may be provided alone, or the L-band transmission filter and the reflector may be installed in place of the L-band reflection filter.

In addition, the present invention includes an erbium-doped optical fiber amplifier (EDF) pumped by a pump light source, and an isolator 200 for preventing the reverse of the reverse direction at the rear end of the erbium-doped optical fiber amplifier, The front end includes a wavelength division multiplexing device 206 through which a pump light source is input, and connects the front end of the wavelength division multiplexing device to one port of the rotor 214 and is connected to two other ports of the rotor to form an L-band. It provides an L-band optical fiber light source, characterized in that it comprises a selectively transmitting L-band transmission filter (212).

Hereinafter, a preferred embodiment of the L-band optical fiber light source of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view for explaining an L-band optical fiber light source according to an embodiment of the present invention.

As shown, the L-band optical fiber light source uses an erbium-doped optical fiber 203 (EDF) as an amplification medium, the pump photodiode 202 for the light generating unit, the wavelength division multiplexing device 206, and the FBG for the reflection input unit. A fiber Bragg Grating Filter 204, an isolator 200 to block backflowing light, a wavelength selective coupler 205 for selecting and separating a specific wavelength, and a reflector 201 reflecting light.

The optical fiber light source according to the embodiment of the present invention is generated by the pump photodiode 202, which is an energy source, is excited by the EDF 203, which is an amplification medium, and emits natural light, which is output through the isolator. In front of the wavelength selective coupler 205, the L-band light traveling in the reverse direction using the reflector 201 is reincident to the EDF 203 again. In addition, the front end of the wavelength selective coupler is connected to the FBG filter 204 in parallel with the reflector to selectively reflect the C-band light traveling in the reverse direction. The optical isolator 200 is a forward isolator such as a signal light traveling direction. Inclined cleaving is configured at the front end of the FBG filter 204 for selecting a specific wavelength to prevent diffuse reflection of C-band light having a wavelength that is not reflected through the FBG.

Referring to the operation of the erbium-added optical fiber light source having such a configuration in detail as follows.

In the wavelength division multiplexing 206 at the front end of the EDF 203, the pump light generated by the forward pump photodiode 202 and the light output from the wavelength selective combiner 205 are combined with the EDF 203. The incident forward excitation light excites the erbium ions in the ground state in the EDF 203. It blocks the light flowing back from the isolator 200 located at the rear end of the EDF 203.

Backward spontaneous light generated in the EDF goes in the reverse direction. At this time, after the reverse natural light is separated into C-band light and L-band light by the wavelength selective combiner, the L-band light is re-injected back into the EDF through the reflector 201 and the C-band light by using an FBG filter. It selectively reflects and utilizes the reflected light as the secondary excitation light. The components are commercially available. EDF used 50 m of OFS's GP980 product. The excitation light source was 80 mW, the wavelength band was 980 nm, and the FBG was 1552.4 nm and 95%, respectively. .

The structure using only the existing optical mirror for the comparative structure and the proposed structure in Figure 2 was configured as shown in FIG. That is, it does not selectively reflect the C-band light traveling in the reverse direction in the wavelength selective coupler. Also. The structure in which only the FBG filter was applied without the optical mirror was constructed as shown in FIG. That is, since no reflector is provided at the front end of the wavelength selective coupler 205, the L-band light traveling in the reverse direction is not reincident to the EDF. The main difference between the proposed structure and the comparative experiment is the incidence of L-band light on the EDF. In addition, the characteristics were measured along with FIG. 1, which is a typical structure described above, and the results were analyzed.

5 shows the output power spectrum in each structure. Here, Fig. 5 (a) shows Fig. 2, Fig. 5 (b) shows Fig. 1, Fig. 5 (c) shows Fig. 3 and Fig. 5 (d) shows the output power spectrum of Fig. 4. The spectrum (a) of the structure according to the present invention shows a high power of about 1.5 dB at around 1570 nm compared to the spectrum (b) according to the conventional structure as shown in FIG. The reason is that the C-band and L-band light is incident at the same time so that the light of the C-band passes through the EDF and the excitation light is exhausted, so that only the L-band light is put into the EDF as in the present invention. This is because the optical power of the L-band is increased because it reduces the loss of the excitation light due to the band light.

Figure 6 is another embodiment of the optical fiber light source according to the present invention is a way to use the wasted light more efficiently.

Referring to the drawings, a pump light laser diode 202 for generating pump light, a wavelength division multiplexing device 206, and an EDF 203 are connected, and a second wavelength selective coupler 205b and a second end of the EDF 203 are connected to each other. Two isolators 200b are sequentially connected, and a first wavelength selective coupler 205a is connected to the front end of the wavelength division multiplexer 206, and an L-band light is reflected to the front end of the first wavelength selective coupler. A reflector 201 and an FBG 204 that selectively reflects C-band light are connected. Here, the other end of the FBG and the second wavelength selective coupler 205b are connected by a first isolator 200a that prevents the reverse direction.

Referring to the operation of the configuration as shown in FIG. 6, a part of the C-band reversed natural emission light separated by the first wavelength selective coupler 205a is selectively reflected by the FBG 204, and the remaining light is again reflected by the second wavelength. It is more efficient to use the wasted light by entering the selective coupler 205b and then entering the end of the EDF to utilize the secondary excitation light.

7 and 8 are block diagrams showing still another embodiment of the optical fiber light source according to the present invention.

7 shows an L-band reflection filter 208 for selectively reflecting the L-bands of the reverse natural emission light generated by the erbium-doped optical fiber amplifier in front of the wavelength division multiplexing device 206, and C-band light. The FBG 204 which reflects this is provided. Here, the L-band reflection filter may be provided alone. It is also possible to install an L-band transmission filter (not shown) and a reflector (not shown) in place of the L-band reflection filter.

Referring to the operation of the configuration as shown in Fig. 7, the pump light generated in the pump photodiode 202 is incident on the EDF 203 via the wavelength division multiplexing device 206. Reverse natural light generated in the EDF travels in the reverse direction. At this time, the reverse natural light is re-entered back into the EDF through the L-band reflection filter 208, and the C-band light transmitted through the L-band reflection filter is reflected by the FBG filter and used as the secondary excitation light. In addition, when the L-band reflection filter is installed alone, only the L-band of the backward natural light is reflected and reincident to the EDF.

In addition, when the L-band transmission filter and the reflector are installed in place of the L-band reflection filter, only the L-band is transmitted through the reverse natural light and the L-band light is reflected again, and then the EDF passes through the L-band transmission filter. Is re-entered as

In the optical fiber light source shown in FIG. 8, a pumping laser diode 202 for generating pump light, a wavelength division multiplexing device 206, and an EDF 203 are sequentially connected, and an isolator 200 is provided at a rear end of the EDF 203. Is connected, and one port (c) of the rotor 214 is connected to the front end of the wavelength division multiplexer 206, and the L-band transmission filter 212 is connected to the other two ports (a, b) of the rotor. have. The rotator is a three-port optical element, an optical signal input through port a is output to port b, an optical signal input through port b is output to port c, and an optical signal input through port c is port a Is output.

Referring to the operation of the configuration as shown in Fig. 8, the pump light generated in the pump photodiode 202 is incident on the EDF 203 via the wavelength division multiplexing device 206. The reverse spontaneous light generated in the EDF is input to the rotor 214 through the port c and output from the port a. That is, the output reverse natural light is inputted only through the L-band transmission filter 212 to the port b of the rotor, and is reincident to the EDF through the port c.

As described above, the present invention provides a broadband Erbium-doped optical fiber light source capable of increasing amplification efficiency by constructing an L-band naturally occurring light source with a wavelength selective coupler, a reflector, and an FBG.

In addition, the present invention provides a broadband erbium-doped optical fiber light source that increases cost and improves reliability by increasing the power of L-band spontaneous light without using additional expensive unpumped EDF.

In the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

Claims (6)

An optical fiber light source, comprising: an erbium-doped optical fiber amplifier 203 for amplifying pump light, and an isolator 200 for preventing advancing in the reverse direction at the rear end of the erbium-doped optical fiber amplifier. A wavelength division multiplexing device 206 into which a pump light source is input, and located at the front of the wavelength division multiplexing device to split the reverse natural emission light generated by the erbium-doped optical fiber amplifier into L-band and C-band. L-, characterized in that it comprises a selective coupler 205, a reflector 201 positioned in front of the wavelength selective coupler to reflect L-band light and an FBG 204 to selectively reflect C-band light. Band optical fiber light source. In the optical fiber light source, the erbium-doped optical fiber amplifying unit 203 to amplify the pump light, the wavelength division multiplexing device 206 to which the pump light source is input, and the reverse natural emission light are respectively applied to the front and rear ends of the erbium-added optical fiber amplifying unit. And a second wavelength selective coupler 205b for dividing the band and the C-band, and located in front of the wavelength division multiplexer to convert the reverse natural emission light generated from the erbium-doped optical fiber amplification unit into the L-band and the C-band. A first wavelength selective coupler 205a, which is divided into a light source, a reflector 201 that reflects L-band light and an FBG 204 that selectively reflects C-band light, are connected to the front end of the first wavelength selective coupler. The other end of the FBG and the second wavelength selective coupler 205b are connected to each other by a first isolator 200a which prevents the reverse direction from being reversed, and is connected to a rear end of the second wavelength selective coupler to proceed in the reverse direction. 2nd to prevent L- band fiber optic light source, characterized in that it comprises a concentrator ESOL (200b). An optical fiber light source, comprising: an erbium-doped optical fiber amplifier 203 for amplifying pump light, and an isolator 200 for preventing advancing in the reverse direction at the rear end of the erbium-doped optical fiber amplifier. L-band reflection having a wavelength division multiplexing device 206 to which a pump light source is input, which is located in front of the wavelength division multiplexing device and selectively reflects the L-band of reverse natural emission light generated in the erbium-doped optical fiber amplifier. L-band optical fiber light source, characterized in that it comprises a filter (208). 4. The L-band optical fiber light source according to claim 3, comprising an FBG (204) positioned at the front of the L-band reflective filter to selectively reflect C-band light. An optical fiber light source, comprising: an erbium-doped optical fiber amplifier 203 for amplifying pump light, and an isolator 200 for preventing advancing in the reverse direction at the rear end of the erbium-doped optical fiber amplifier. A wavelength division multiplexing device 206 to which a pump light source is input is provided, and is located in front of the wavelength division multiplexing device, and L-band transmission for selectively transmitting the L-band of reverse natural emission light generated in the erbium-doped optical fiber amplifier. And a reflector reflecting the L-band passing through the L-band transmission filter. An optical fiber light source, comprising: an erbium-doped optical fiber amplifier 203 for amplifying pump light, and an isolator 200 for preventing advancing in the reverse direction at the rear end of the erbium-doped optical fiber amplifier. And a wavelength division multiplexer 206 to which a pump light source is input, and is connected to one port of the rotor 214 at a front end of the wavelength division multiplexer, and is connected to two other ports of the rotor in an erbium-doped optical fiber amplifier. An L-band optical fiber light source, characterized in that it comprises an L-band transmission filter (212) for selectively transmitting the L-band of the generated reverse natural emission light.