KR20050049167A - Broadband light source with dual-port structure - Google Patents

Abstract

The broadband light source of the dual output structure according to the present invention comprises: an amplifying medium for outputting spontaneous emission light ASE amplified through both ends as pumped by the pump light; A pumping unit for outputting the pump light to the amplifying medium; A first distribution unit disposed on one side of the amplification medium and configured to pass an ASE of a first wavelength band among the inputted ASEs to a first output end of the broadband light source and reflect an ASE of a second wavelength band to the amplification medium; ; A second distribution part disposed on the other side of the amplification medium and configured to pass an ASE of a second wavelength band among the inputted ASEs to a second output end of the broadband light source and reflect the ASE of the first wavelength band to the amplification medium side; do.

Description

BROADBAND LIGHT SOURCE WITH DUAL-PORT STRUCTURE}

The present invention relates to an optical module, and more particularly to a broadband light source having a dual output structure.

In order to measure optical characteristics of various devices used in optical communication, a light source having a wide wavelength band is required. In particular, when an erbium-doped fiber amplifier (EDFA) is used in an optical communication system, since a wavelength band of an optical signal used for communication is 1520 nm to 1620 nm, a light source capable of measuring various optical elements in this band is required. In addition, a broadband light source used with wavelength-locked laser diode (LD) as a light source for simultaneously accommodating multiple subscribers in a Wavelength Division Multiplexing Passive Optical Network (WDM-PON), which has recently been spotlighted as a future high-speed optical subscriber network. It is getting attention. In the case of conventionally sold broadband light sources, amplified spontaneous emission (ASE) of a white light source or an Erbium Doped Fiber Amplifier (EDFA) is mainly used. However, in the case of a white light source, the output is weak, so there is a limit in using the WDM-PON light source or optical device characteristic measurement, which requires high power, and EDFA has a disadvantage in that it is not economical in terms of price.

1 is a view showing the configuration of a typical broadband light source. The broadband light source 100 includes an erbium doped fiber (EDF) 110, first and second wavelength selective couplers (WSC) 120, 125, and first and second pump laser diodes. laser diode: pump LD, 130,135), and optical isolator (ISO, 140). The first and second pump laser diodes 130 and 135 respectively output the pump light 160 and 165 of a predetermined wavelength, and the first and second wavelength selective couplers 120 and 125 are respectively the first and second pump laser diodes. Pump lights 160 and 165 output from the fields 130 and 135 are output to the erbium-doped optical fiber 110. The erbium-doped optical fiber 110 is pumped bidirectionally by the input pump lights 160 and 165 and outputs spontaneous emission lights 170 and 175 amplified through both ends thereof. The amplified spontaneous emission light 175 output to the front of the erbium-doped optical fiber 110 passes through the second wavelength selective coupler 125 and the optical isolator 140 to pass through the output terminal 155 of the light source 100. It is output through the outside. The amplified spontaneous emission light 170 output to the rear of the erbium-doped optical fiber 110 passes through the first wavelength selective coupler 120 and is input to the termination 150 of the light source 100 and then disappears. do.

However, the broadband light source using the rare earth addition optical fiber such as EDF outputs only the amplified spontaneous emission light in one direction among the amplified spontaneous emission light output from both ends of the rare earth addition optical fiber to the outside, thereby greatly reducing the output efficiency. have.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a bidirectional bidirectional light output with high light intensity and high efficiency for measuring the characteristics of an optical device or as a broadband light source for WDM-PON Therefore, the present invention provides a broadband light source having a dual output structure capable of outputting ASEs having different wavelength bands.

In order to achieve the above objects, the broadband light source of the dual output structure according to the present invention comprises: an amplifying medium for outputting spontaneous emission light ASE amplified through both ends as pumped by the pump light; A pumping unit for outputting the pump light to the amplifying medium; A first distribution unit disposed on one side of the amplification medium and configured to pass an ASE of a first wavelength band among the inputted ASEs to a first output end of the broadband light source and reflect an ASE of a second wavelength band to the amplification medium; ; A second distribution part disposed on the other side of the amplification medium and configured to pass an ASE of a second wavelength band among the inputted ASEs to a second output end of the broadband light source and reflect the ASE of the first wavelength band to the amplification medium side; do.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention; In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

FIG. 2 is a diagram showing the configuration of a broadband light source having a dual output structure according to the first preferred embodiment of the present invention, and FIG. 3 is a diagram showing an output spectrum of the broadband light source shown in FIG. The broadband light source 200 includes a gain medium GM 210, a pumping part 220, first and second distribution parts 230 and 240, and first and second light. Isolators (ISO, 250, 255).

The pumping unit 220 includes first and second pump light sources pump LS 226 and 228 and first and second wavelength selective couplers WSC 222 and 224.

The first pump light source 226 outputs the first pump light 227 having a predetermined wavelength, and the first wavelength selective combiner 222 transfers the input first pump light 227 to the amplifying medium 210. Output

The second pump light source 228 outputs a second pump light 229 having a predetermined wavelength, and the second wavelength selective combiner 224 transfers the input second pump light 229 to the amplifying medium 210. Output As the first and second pump light sources 226 and 228, a laser diode, a light emitted diode (LED), or the like may be used.

The amplification medium 210 is bidirectionally pumped by the first and second pump lights 227 and 229, and outputs the generated ASE through both ends thereof. The amplification medium 210 may include a rare earth addition fiber or a rare earth addition planar lightwave circuit, and the rare earth addition fiber may include an erbium addition fiber, a thulium doped fiber (TDF), and a praseodymium addition. Optical fibers (praseodymium doped fiber (PDF)) and the like can be used. Erbium-doped optical fibers can be used in the wavelength range of 1520-1570 nm by shortening their length or increasing the output of the pump light, that is, by increasing the density reversal. Can be used in the ~ 1620nm wavelength band. The thulium-doped optical fiber can be used in the 1450 ~ 1510nm wavelength band, the praseodymium-doped optical fiber can be used in the 1270 ~ 1330nm wavelength band. The first and second pump lights 227 and 229 have a wavelength capable of exciting the amplification medium 210 according to the type of the amplification medium 210. A kind of the amplification medium 210 having a large gain spectrum in the wavelength band according to the available wavelength band of the broadband light source 200, and the first and second pumps capable of exciting the amplification medium 210. The type of light sources 226 and 228 may be selected.

The first distribution unit 230 includes a first wavelength division multiplexing coupler (WDMC) 232 and a first mirror 234.

The first wavelength division multiple coupler 232 includes first to third ports 2321 to 2323, and the first port 2321 is connected to the first wavelength selective combiner 222 and the second wavelength coupler 222. The port 2322 is connected to the first mirror 234, and the third port 2323 is connected to the first optical isolator 250. The first wavelength division multiple coupler 232 outputs the ASE 270 of the first wavelength band among the ASEs input to the first port 2321 to the third port 2323, and the ASE 275 of the second wavelength band. ) Is output to the second port 2232. The first mirror 234 reflects the ASE 275 of the second wavelength band input from the second port 2232 of the wavelength division multiple coupler 232, and the first wavelength division multiple coupler 232. Outputs the ASE 275 of the second wavelength band input to the second port 2322 to the first port 2321.

The second distribution unit 240 includes a second wavelength division multiple coupler 242 and a second mirror 244.

The second wavelength division multiplexer 242 includes first to third ports 2421 to 2423, and the first port 2421 is connected to the second wavelength selective coupler 224 and the second The port 2422 is connected to the second optical isolator 255, and the third port 2423 is connected to the second mirror 244. The second wavelength division multiplexer 242 outputs the ASE 275 of the second wavelength band among the ASEs input to the first port 2421 to the second port 2422 and the ASE 270 of the first wavelength band. ) Is output to the third port 2423. The second mirror 244 reflects the ASE 270 of the first wavelength band input from the third port 2423 of the second wavelength division multiple coupler 242, and the second wavelength division multiple coupler ( 242 outputs the ASE 270 of the first wavelength band inputted to the third port 2423 to the first port 2421.

The first optical isolator 250 is disposed between the first output terminal 260 of the broadband light source 200 and the first wavelength division multiple coupler 232, and is input from the first wavelength division multiple coupler 232. The ASE 270 of the first wavelength band is passed to the first output terminal 260 side and blocks the light traveling in the reverse direction.

The second optical isolator 255 is disposed between the second output terminal 265 of the broadband light source 200 and the second wavelength division multiple coupler 242, and is input from the second wavelength division multiple coupler 242. The ASE 275 of the second wavelength band is passed to the second output terminal 265 side, and the light traveling in the reverse direction is blocked.

First, the path of the ASE 270 of the first wavelength band is sequentially described based on the amplification medium 210. The ASE 270 of the first wavelength band, which is output from the amplifying medium 210 to the second output terminal 265, passes through the second wavelength selective coupler 224 of the second wavelength division multiplexer 242. The second wavelength division multiple coupler 242, which is input to the first port 2421, outputs the input ASE 270 of the first wavelength band to the third port 2423. The second reflector 244 reflects the ASE 270 of the first wavelength band input from the third port 2423 of the second wavelength division multiple coupler 242 to the third port 2423. The second wavelength division multiplexer 242 outputs the ASE 270 of the first wavelength band input to the third port 2423 to the first port 2421. The ASE 270 of the first wavelength band output from the first port 2421 of the second wavelength division multiple coupler 242 passes through the second wavelength selective coupler 224 to the amplification medium 210. After the amplification and amplification, the signal is input to the first port 2321 of the first wavelength division multiple coupler 232 through the first wavelength selective coupler 222. The first wavelength division multiple coupler 232 outputs the input ASE 270 of the first wavelength band to the third port 2323, and outputs the first wavelength band output from the third port 2323. The ASE 270 is output through the first output terminal 260 after passing through the first optical isolator 250.

Next, the progress path of the ASE 275 of the second wavelength band will be described sequentially with reference to the amplification medium 210. The ASE 275 of the second wavelength band, which is output from the amplifying medium 210 to the first output terminal 260, passes through the first wavelength selective coupler 222 of the first wavelength division multiplexer 232. The first wavelength division multiple coupler 232 is input to the first port 2321, and outputs the input ASE 275 of the second wavelength band to the second port 2322. The first reflector 234 reflects the ASE 275 of the second wavelength band input from the second port 2232 of the first wavelength division multiple coupler 232 to the second port 2322, The first wavelength division multiple coupler 232 outputs the ASE 275 of the second wavelength band input to the second port 2232 to the first port 2321. The ASE 275 of the second wavelength band output from the first port 2321 of the first wavelength division multiple coupler 232 passes through the first wavelength selective combiner 222 and enters the amplification medium 210. After being amplified and passed through the second wavelength selective coupler 224, it is input to the first port 2421 of the second wavelength division multiplexer 242. The second wavelength division multiple coupler 242 outputs the input ASE 275 of the second wavelength band to the second port 2422, and outputs the second wavelength band output from the second port 2422. The ASE 275 passes through the second optical isolator 255 and is output to the outside through the second output terminal 27.

4 is a diagram illustrating a configuration of a broadband light source having a dual output structure according to a second preferred embodiment of the present invention. The broadband light source 300 includes an amplifying medium 310, a pumping part 320, first and second distribution parts 330 and 340, and first and second connectors 350 and 355. Since the broadband light source 300 has a configuration in which the first and second isolators 250 and 255 are removed and the first and second connectors 350 and 355 are added in the configuration shown in FIG. It will be omitted and briefly described.

The pumping unit 320 includes first and second pump light sources 326 and 328, and first and second wavelength selective couplers 322 and 324.

The first pump light source 326 outputs the first pump light 327 having a predetermined wavelength, and the first wavelength selective combiner 322 transfers the input first pump light 327 to the amplifying medium 310. Output

The second pump light source 328 outputs a second pump light 329 having a predetermined wavelength, and the second wavelength selective combiner 324 sends the input second pump light 329 to the amplifying medium 310. Output

The amplification medium 310 is bidirectionally pumped by the first and second pump lights 327 and 329, and outputs the generated ASE through both ends thereof.

The first distribution unit 330 includes a first wavelength division multiple coupler 332 and a first mirror 334.

The first wavelength division multiple coupler 332 includes first to third ports 3321 to 3323, and the first port 3321 is connected to the first wavelength selective combiner 322 and the second The port 3322 is connected to the first mirror 334, and the third port 3323 is connected to the first connector 350. The first wavelength division multiple coupler 332 outputs the ASE 370 of the first wavelength band among the ASEs input to the first port 3321 to the third port 3323, and the ASE 375 of the second wavelength band. ) Is output to the second port 3322. The first mirror 334 reflects the ASE 375 of the second wavelength band input from the second port 3322 of the wavelength division multiple coupler 332, and the first wavelength division multiple coupler 332. Outputs the ASE 375 of the second wavelength band input to the second port 3322 to the first port 3321.

The second distribution unit 340 includes a second wavelength division multiple coupler 342 and a second mirror 344.

The second wavelength division multiple coupler 342 includes first to third ports 341 to 3423, and the first port 341 is connected to the second wavelength selective coupler 324 and the second The port 3342 is connected to the second connector 355, and the third port 3423 is connected to the second mirror 344. The second wavelength division multiplexer 342 outputs the ASE 375 of the second wavelength band among the ASEs input to the first port 3441 to the second port 3422, and the ASE 375 of the first wavelength band. Is output to the third port 3423. The second mirror 344 reflects the ASE 370 of the first wavelength band input from the third port 3423 of the second wavelength division multiple coupler 342, and the second wavelength division multiple coupler ( The 342 outputs the ASE 370 of the first wavelength band input to the third port 3423 to the first port 341.

The first connector 350 is installed at the first output terminal 360 of the broadband light source 300, and the second connector 355 is installed at the second output terminal 365 of the broadband light source 300. The first and second connectors 350 and 355 may each include an end inclined optical fiber, and since the end of the optical fiber is inclined, the amount of light reflected from the end of the optical fiber and input to the amplification medium 310 is reduced. do. The inclination angle may be set to the Brewster angle.

First, the path of the ASE 370 of the first wavelength band is sequentially described based on the amplification medium 310. The ASE 370 of the first wavelength band output from the amplifying medium 310 to the second output terminal 365 passes through the second wavelength selective coupler 324 to the second wavelength division multiple coupler 342. The second wavelength division multiple coupler 342, which is input to the first port 3441, outputs the input ASE 370 of the first wavelength band to the third port 3423. The second reflector 344 reflects the ASE 370 of the first wavelength band input from the third port 3423 of the second wavelength division multiple coupler 342 to the third port 3423. The second wavelength division multiplexer 342 outputs the ASE 370 of the first wavelength band input to the third port 3423 to the first port 341. The ASE 370 of the first wavelength band output from the first port 341 of the second wavelength division multiplexer 342 passes through the second wavelength selective coupler 324 to the amplification medium 310. After the amplification, the signal is input to the first port 3321 of the first wavelength division multiple coupler 332 through the first wavelength selective coupler 322. The first wavelength division multiple coupler 332 outputs the input ASE 370 of the first wavelength band to the third port 3323, and outputs the first wavelength band of the first wavelength band output from the third port 3323. The ASE 370 is output to the outside through the first connector 350.

Next, the progress path of the ASE 375 of the second wavelength band will be described sequentially with reference to the amplification medium 310. The ASE 375 of the second wavelength band, which is output from the amplifying medium 310 to the first output terminal 360, passes through the first wavelength selective coupler 322 of the first wavelength division multiple coupler 332. The first wavelength division multiple coupler 332, which is input to the first port 3321, outputs the input ASE 375 of the second wavelength band to the second port 3322. The first reflector 334 reflects the ASE 375 of the second wavelength band input from the second port 3322 of the first wavelength division multiple coupler 332 to the second port 3322, The first wavelength division multiple coupler 332 outputs the ASE 375 of the second wavelength band input to the second port 3322 to the first port 3321. The ASE 375 of the second wavelength band output from the first port 3321 of the first wavelength division multiple coupler 332 passes through the first wavelength selective combiner 322 and enters the amplification medium 310. After being amplified and passed through the second wavelength selective coupler 324, it is input to the first port 341 of the second wavelength division multiplexer 342. The second wavelength division multiplexer 342 outputs the inputted ASE 375 of the second wavelength band to the second port 3342, and outputs the second wavelength band output from the second port 3342. The ASE 375 is output to the outside through the second connector 355.

As described above, the broadband light source of the dual output structure according to the present invention outputs the ASE output through both ends of the amplification medium to the outside through the first and second output terminals, so that the output efficiency is high and one broadband light source There is an economic advantage because it functions as a substitute. In particular, in the case of the WDM-PON system using the wavelength-locked laser diode, since the cost portion of the broadband light source is large, there is an advantage that an economical optical subscriber network can be realized when the broadband light source of the present invention is used. In addition, the number of broadband light sources can be reduced by half, enabling system integration.

In addition, the broadband light source of the dual output structure according to the present invention has an advantage of outputting ASEs having different wavelength bands in both directions by using the first and second reflectors.

1 is a view showing the configuration of a typical broadband light source,

2 is a view showing the configuration of a broadband light source having a dual output structure according to a first embodiment of the present invention;

3 is a view showing an output spectrum of the broadband light source shown in FIG.

4 is a diagram showing the configuration of a broadband light source having a dual output structure according to a second preferred embodiment of the present invention.

Claims (8)

In a broadband light source, An amplifying medium for outputting spontaneous emission light ASE amplified through both ends as pumped by the pump light; A pumping unit for outputting the pump light to the amplifying medium; A first distribution unit disposed on one side of the amplification medium and configured to pass an ASE of a first wavelength band among the inputted ASEs to a first output end of the broadband light source and reflect an ASE of a second wavelength band to the amplification medium; ; A second distribution part disposed on the other side of the amplification medium and configured to pass an ASE of a second wavelength band among the inputted ASEs to a second output end of the broadband light source and reflect the ASE of the first wavelength band to the amplification medium side; Broadband light source of dual output structure characterized in that. The method of claim 1, wherein the pumping unit, A pump light source for outputting pump light of a predetermined wavelength; And a wavelength selective combiner for outputting the input pump light to the amplification medium. The method of claim 1, wherein the pumping unit, A first pump light source for outputting a first pump light of a predetermined wavelength; A first wavelength selective combiner for outputting the input first pump light to the amplifying medium; A first pump light source for outputting a first pump light of a predetermined wavelength; A first wavelength selective combiner for outputting the input first pump light to the amplification medium, The first pump light source and the first wavelength selective coupler are disposed on one side of the amplification medium, and the second pump light source and the second wavelength selective coupler are disposed on the other side of the amplification medium. . The method of claim 1, wherein the first distribution unit, A first port having a first to third port, and outputting an ASE of a first wavelength band among the ASEs inputted to the first port of the amplification medium, to the third port of the first output end, and outputting an ASE of the second wavelength band to the second port A first wavelength division multiple coupler for outputting an ASE of a second wavelength band inputted to the second port to the first port; And a first reflector for reflecting the ASE of the second wavelength band input from the second port of the first wavelength division multiple coupler to the second port. The method of claim 1, wherein the second distribution unit, A first port through a third port, outputting an ASE of a second wavelength band among the ASEs input to the first port on the amplification medium side to the second port of the second output end side, and outputting an ASE of the first wavelength band to the third port A second wavelength division multiple coupler for outputting an ASE of a first wavelength band inputted to the third port to the first port; And a second reflector for reflecting the ASE of the first wavelength band input from the third port of the first wavelength division multiple coupler to the third port. The method of claim 1, A first device disposed between the first output terminal and the first distribution unit and configured to pass an ASE of a first wavelength band input from the first distribution unit to the first output terminal and to block light traveling in the opposite direction; A broadband dual-output light source, characterized in that it further comprises an optical isolator. The method of claim 1, A second device disposed between the second output terminal and the second distribution unit and configured to pass an ASE of a second wavelength band inputted from the second distribution unit to the second output terminal side and block light traveling in the opposite direction; A broadband dual-output light source, characterized in that it further comprises an optical isolator. The method of claim 1, A first connector installed at the first output end and including a first end inclined optical fiber to reduce an amount of light reflected from an end of the first end inclined optical fiber and input to the amplifying medium; And a second connector installed at the second output end to reduce the amount of light reflected from the end of the second inclined optical fiber to the amplification medium by including the second inclined optical fiber. Broadband light source of dual output structure.