KR20020053568A - Hybrid Fiber Amplifier Employing Pump Power Control Loop - Google Patents

Abstract

PURPOSE: A pump light source controller of an optical fiber amplifier and a hybrid type optical fiber amplifier using the same are provided to gain a sufficient operation band width about an input power change while maintaining a constant optical amplification feature with respect to a change of an input signal light intensity. CONSTITUTION: A pump power control loop(210) controls a pump power of a Raman amplification module for a lossless division compensation. A tap coupler(211) divides a part of an input signal. An optical detector(212) measures a signal divided by the tap coupler(211). An amplifier(213) amplifies a signal detected by the optical detector(212). An A/D converter(214) converts an analog signal amplified by the amplifier(213) into a digital signal. A processor(215) controls the digital signal from the A/D converter(214). A D/A converter(216) converts the digital signal controlled by the processor(215) into an analog signal. An adder(217) adds the analog signal from the D/A converter(216) to an off-set voltage.

Description

Pump light source control device of optical fiber amplification device and hybrid optical fiber amplification device using same {Hybrid Fiber Amplifier Employing Pump Power Control Loop}

The present invention relates to a pump light source control device of the optical fiber amplification device and a hybrid optical fiber amplification device using the same, and more particularly, in the optical fiber amplification device, while maintaining a constant optical amplification characteristics against a wide range of changes in the input signal light intensity A pump light source control device for controlling an input pump light source to enable amplification, and a hybrid optical fiber amplifying device using the same.

Optical fiber amplification device is a key component of Wavelength Division Multiplexing (WDM) type optical transmission, and is mainly focused on Erbium Dopped Fiber Amplifier (EDFA). Research is ongoing and many products are already commercialized. In recent years, as the traffic volume increases rapidly, a larger number of channels are required. Accordingly, the demand for wideband optical fiber amplification devices is also rapidly increasing.

Accordingly, research on the introduction of Raman amplification has been actively conducted because a wavelength band wider than that of the EDFA is required. Such research on the optical fiber Raman amplification apparatus has largely been made by using the optical path itself as a gain medium. ) And a separate Raman amplifier using a separate Raman amplifying fiber.

In addition to the two methods described above, the hybrid type optical fiber amplifying device which combines Raman amplification and EDFA to form an amplifying device may be one type of the optical fiber Raman amplifying device.

In the optical amplification device composed only of EDFA, a two-stage amplification module structure is used to compensate the insertion loss of the dispersion compensation optical fiber module for dispersion compensation. However, the hybrid optical fiber amplification device induces and distributes the Raman gain to the dispersion compensation optical fiber. Compensation for the insertion loss in the compensation optical fiber module itself, the effect of replacing the single-stage amplification module with only one pumping light source to obtain the Raman gain, it can be a more efficient optical fiber amplification device.

The present invention relates to a hybrid optical fiber amplification apparatus using such a lossless dispersion compensation optical fiber module, Figure 1 is an exemplary configuration of a hybrid optical fiber amplification apparatus using a conventional lossless dispersion compensation optical fiber module.

As shown in FIG. 1, the conventional hybrid optical fiber amplifying apparatus includes a lossless dispersion compensation optical fiber module (LLDCM) 110 and a single stage EDFA module 120.

In addition, the lossless dispersion compensation optical fiber module 110, the first WDM combiner 112 and Raman for combining the dispersion compensation optical fiber 111 and the Raman pumping light source for the transmission path used in the actual WDM optical transmission device with the signal light In order to eliminate the dependence of the pump light polarization of the gain, a Lyot type optical fiber depolarizer 113 is included.

At this time, the pump light is incident in the reverse direction to eliminate the fluctuation of the gain caused by the fluctuation of the pump light.

The EDFA 120 used in combination with the lossless dispersion compensation optical fiber module 110 is a second WDM coupler that simultaneously combines the gain medium EDF 122 and the pumping light source with the signal light and simultaneously enters the EDF 122. (121).

With the above configuration, it is possible to implement the optical fiber amplification apparatus having the dispersion compensation function by compensating dispersion without loss in the lossless dispersion compensation fiber module 110 at the front end and amplifying the optical signal at the EDFA 120 at the rear end.

However, the conventional hybrid optical fiber amplifying device has a problem that the characteristics of the optical amplifying device cannot be kept constant because the amplification performance is very sensitive to the intensity of the input signal light.

The present invention has been proposed to solve the above problems, in the optical fiber amplification device, a pump light source control device for controlling the input pump light source to enable amplification while maintaining a constant optical amplification characteristics against a wide range of changes in the input signal light intensity And a hybrid optical fiber amplifying apparatus using the same.

1 is an exemplary configuration of a hybrid optical fiber amplifying apparatus using a conventional lossless dispersion compensation optical fiber module.

Figure 2 is a configuration diagram of an embodiment of a pump light source control device of the optical fiber amplifying apparatus and a hybrid optical fiber amplifying apparatus using the same.

3 is a configuration diagram of an embodiment of a 32-channel hybrid optical fiber amplifying apparatus using a pump light source control apparatus according to the present invention.

Figures 4a and 4b is an exemplary explanatory diagram for measuring the gain and noise figure for each wavelength of the hybrid optical fiber amplifying apparatus according to the present invention.

5A and 5B are diagrams illustrating exemplary measurement of gain and noise figure for each wavelength of a hybrid optical fiber amplifier for 32 channels according to the present invention;

* Explanation of symbols for the main parts of the drawings

210: pump power control loop 220: lossless dispersion compensation module (LLDCM)

230: Erbium-doped fiber amplifier (EDFA)

In order to achieve the above object, the present invention is a pump light source control device for controlling the pump power in accordance with the change in the input power of the optical fiber amplifying apparatus, comprising: an optical branch means for branching a portion of the input optical signal; Light detecting means for detecting a signal branched by the optical branch means and converting the signal into an electrical signal; Signal amplifying means for amplifying the electrical signal detected by the photodetecting means; First signal conversion means for converting the electrical signal amplified by the signal amplification means into a digital signal; Signal control means for controlling the digital signal converted by the signal conversion means so that the pump power has a predetermined output power; Second signal conversion means for converting the digital signal controlled by the signal control means into an analog signal; And signal coupling means for coupling the analog signal converted by the second signal conversion means with an offset voltage.

The present invention also provides a hybrid optical fiber amplifying apparatus comprising: first optical amplifying means for amplifying an input optical signal by inducing a Raman gain in a dispersion compensation optical fiber; Second optical amplification means for amplifying again the optical signal amplified by the first optical amplification means; And pump power control means for controlling the power of the Raman pump of the first optical amplification means.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a configuration diagram of an embodiment of a pump light source control device of the optical fiber amplifying apparatus and a hybrid type optical fiber amplifying apparatus using the same.

As shown in FIG. 2, the hybrid optical fiber amplifying apparatus using the pump light source control apparatus according to the present invention is installed in a conventional hybrid optical fiber amplifying apparatus 240 and its front end to pump a Raman amplification module for lossless dispersion compensation. And a pump power control loop 210 for controlling power.

In addition, the pump power control loop 210 may include a tap coupler 211 for branching a part of an input signal, a photodetector 212 for measuring a signal branched from the tap coupler 211, and the photodetector ( An amplifier 213 for amplifying the signal detected at 212, an A / D converter 214 for converting the analog signal amplified by the amplifier 213 into a digital signal for processor 215 processing, and the A / A processor 215 for controlling the digital value converted in the D converter 214, a D / A converter 216 for converting the digital value controlled by the processor 215 into an analog signal, and the D / A converter And an adder 217 for adding the analog signal converted at 216 to an offset voltage.

Looking at the operation of the pump power control loop 210 in more detail as follows.

To keep the output power constant with changes in input power, the pump power must be controlled to be inversely proportional to the input power. Therefore, in order to automatically control the pump power inversely proportional to the input power, the input power must be sensed first, so that a part of the input is extracted using the tap coupler 211, and then the input power is converted into an electrical signal by the photodetector 212. In turn, this signal is so weak that it is amplified by the amplifier 213.

In order to change the pump power to an appropriate pump power, the drive current value applied to the laser diode, which is the pump light source, must be properly adjusted. The processor 215 is used to control the current value.

Therefore, for control by the processor 215, an analog signal is converted into a digital signal using the A / D converter 214, and the processor 215 obtains a constant output power using the converted digital signal. The laser diode is controlled, and the D / A converter 216 converts the digital signal into an analog signal, and then adds the existing offset voltage to the adder 217.

At this time, the added voltage operates the current driving unit of the pump light source to supply a current having an appropriate intensity, and thus, the pump power is inversely proportional to the input power, thereby obtaining a constant output power even if the input power changes.

By this automatically controlled pump power, an appropriate Raman gain is induced in the lossless dispersion compensation optical fiber module 220, which is the front end of the hybrid optical fiber amplification apparatus 240, to give a constant output power with respect to the input power change with dispersion compensation. Then, the EDFA 230 at the rear end amplifies the optical signal.

3 is a configuration diagram of an embodiment of a 32-channel hybrid optical fiber amplifying apparatus using a pump light source control apparatus according to the present invention.

As shown in FIG. 3, the 32-channel hybrid optical fiber amplifying apparatus using the pump light source control apparatus according to the present invention includes a tap coupler for branching a part of an input optical signal and providing it to the pump power control loop 320. 310, the pump power control loop 320 for controlling the pump power of the LLDCM 330 using the signal branched from the tap coupler 310, LLDCM 330 and EDFA used in a general hybrid type optical fiber amplification device And a gain flattening filter (GFF) 340 for reducing the gain variation of the optical signal input to the EDFA 350.

Unlike when amplifying the input signal of 16 channels in general, the amplification of 32 channels doubles the wavelength band and the wavelength range of 1530-1557 nm, so the gain variation in the wavelength band is less than 1 dB due to the characteristics of EDFA. In order to achieve the gain flattening filter 340 is inserted between the lossless dispersion compensation optical fiber module 330 and the EDFA module 350.

In addition, when the number of channels is doubled, in order to obtain the same gain / channel, the total gain must be 3 dB higher, and thus, reverse pumping is added to the EDFA 350 at the rear end to increase the gain.

4A and 4B are diagrams illustrating exemplary measurement of gain and noise figure for each wavelength of the hybrid type optical fiber amplifier according to the present invention.

4A and 4B are graphs of the hybrid optical fiber amplifying apparatus using the pump light source control apparatus of the optical fiber amplifying apparatus according to the present invention shown in FIG. 4.5, -2 dBm, EDFA pumped forward with a 980 nm laser diode, Raman pumped light source using a 1480 nm laser diode for general EDFA pumping, gain for signals around 1550 nm An example of the results of the measurement of the gain and noise index for each wavelength when the temperature of the pumping laser diode is moved to the short wavelength such that the center wavelength is 1465 to 1470 nm is shown in order to obtain the result.

As shown in Figs. 4A and 4B, it can be seen that the output power, the gain spectrum, and the noise figure remain relatively constant even if the input power changes.

5A and 5B are diagrams illustrating exemplary measurement of gain and noise figure for each wavelength of a hybrid optical fiber amplifier for 32 channels according to the present invention.

5A and 5B show a gain spectrum and a noise figure in one embodiment of the 32-channel hybrid optical fiber amplifying apparatus using the pump light source control apparatus according to the present invention shown in FIG.

The Raman pumping light source used the same conditions as in FIGS. 4A and 4B, and in EDFA, bidirectional pumping was performed with 980 nm in the forward direction and 1480 nm in the reverse direction to increase the gain.

Also in this case, it can be seen that the output power, the gain spectrum, and the noise figure remain relatively constant with respect to the change in the input power.

Accordingly, it is possible to implement a hybrid type optical fiber amplifying apparatus in which a constant optical amplification characteristic is maintained even if the input power is changed, that is, the input dynamic range is improved.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be apparent to those of ordinary knowledge.

The present invention as described above, by controlling the pump power in accordance with the change in the input power of the optical amplifier to make the optical amplification characteristics constant, it is possible to ensure a sufficiently wide operating bandwidth against the change in the input power, the optimum gain and noise It has the effect of maintaining the index.

Claims (3)

In the pump light source control device for controlling the pump power in accordance with the change in the input power of the optical fiber amplifier, Optical branch means for branching a portion of the input optical signal; Light detecting means for detecting a signal branched by the optical branch means and converting the signal into an electrical signal; Signal amplifying means for amplifying the electrical signal detected by the photodetecting means; First signal conversion means for converting the electrical signal amplified by the signal amplification means into a digital signal; Signal control means for controlling the digital signal converted by the signal conversion means so that the pump power has a predetermined output power; Second signal conversion means for converting the digital signal controlled by the signal control means into an analog signal; And Signal combining means for combining an analog signal converted by the second signal converting means with an offset voltage; Pump light source control device comprising a. In the hybrid optical fiber amplification device, First optical amplification means for amplifying an input optical signal by inducing a Raman gain in the dispersion compensation optical fiber; Second optical amplification means for amplifying again the optical signal amplified by the first optical amplification means; And Pump power control means for controlling the power of the Raman pump of said first optical amplification means Hybrid optical fiber amplification apparatus comprising a. The method of claim 2, The pump power control means, Optical branch means for branching a portion of the input optical signal; Light detecting means for detecting a signal branched by the optical branch means and converting the signal into an electrical signal; Signal amplifying means for amplifying the electrical signal detected by the photodetecting means; First signal conversion means for converting the electrical signal amplified by the signal amplification means into a digital signal; Signal control means for controlling the digital signal converted by the signal conversion means so that the Raman pump power has a predetermined output power; Second signal conversion means for converting the digital signal controlled by the signal control means into an analog signal; And Signal combining means for combining the analog signal converted by the second signal converting means with an offset voltage Hybrid optical fiber amplification apparatus comprising a.