FR2796766A1 - Optical bi-directional amplifier for fibre optics has two pumping sources with output applied to fibre optic via multiplexers - Google Patents

Abstract

The optical bi-directional amplifier has two pumping sources (2,3) formed by semiconductor laser diode modules. The pumped light emitted by the sources is applied to the amplifying fibre optic (FDE) via Mach-Zender wavelength dividing multiplexers (4). The pumping light sources have a different wavelength from that emitted by the front and rear sources (2,3).

Description

 BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a bi-directional pumping optical amplifier in which an optical amplification fiber (FDE) is pumped to from a forward direction by pumping light from a pump source ahead and from a rearward direction by pumping light from a rear pump source.

Thus, the present invention relates to an optical amplifier used in an optical communications system and, more particularly, to a bidirectionally pumped optical amplifier for pumping an amplifying optical fiber (Erbium Doped Fiber) from from a direction towards the front and from a direction towards the back.

<B> Description of the relevant technology </ B> Erbium doped fiber optic amplifiers (EDDEs) using Erbium doped fibers (EDFs) have recently been increasingly developed and have been used as optical amplifiers in optical fiber communication systems. Among these amplifiers, noteworthy application to a communications system using a wavelength division multiplex (MDLO) in which several optical signals (channels) having different wavelengths are combined by a multiplexer wavelength splitter plexor, to provide a wavelength division multiplexed signal which is in turn transmitted to thereby increase the transfer capability. AFDE can collectively amplify wavelength division multiplexed optical signals, and has been provided as a simple linear relay (instead of a conventional regenerative relay) in the MDLO system.

However, when the AFDE is applied to the MDLO system, there is a problem with the output properties of the AFDE. So, when you increase the number of channels to 1, 2, ... n, you have to increase the output level of the AFDE by 1, 2, ... n times, so you need a AFDE of higher output level. The AFDE basically comprises an EDF as an amplification agent, a pumping source to pump the FDE, and a combiner to introduce into the FDE pump light from the pump source. In this case, to obtain a higher output level, it is necessary to provide a pump source having a higher output level.

To obtain a high output level of the AFDE by increasing the intensity of the pump source, it has conventionally been applied to the FDE by the following methods (1) First <U> method </ U> As shown in FIG. 5, pump sources A, B are arranged in front of and behind an FDE so that it is bi-directionally pumped by the combination of a front pump intended to pump the FDE by supplying it with the pump light from the front pump source A via a front combiner C, in the same direction as the optical signal, and a rear pump to pump the FDE supplied thereto the pump light from the rear pump source B via a rear combiner D, arriving in a direction opposite to that of the optical signal.

<U> (2) Second Process </ U> As shown in FIG. 6, two pumping sources A1, AZ for generating pumping light with a single wave polarization are arranged in front of an FDE , and two pumping sources B1, B2 for generating pumping light with a single wave polarization are also arranged behind the FDE, so that the pumping lights generated by the pumping sources before A1, A2 are combined by a front polarization wave combination element E to thereby pump the FDE by providing combined light arriving by a forward combiner C in the same direction as that of the optical signal, and that the pump lights generated by the rear pump sources B1, B2 are combined by a rear-polarization wave-mixing element E to pump the FDE by providing the combined light arriving by a rear combiner D in a direction opposite to that of the optical signal.

<U> (3) Third method </ U> The pumping sources before A1, A2 and the rear pumping sources B1, B2 shown in FIG. 6 are constituted by pumping sources intended to generate pumping lights having different wavelengths, so that the pump lights generated by the front pump sources A1, A2 are combined by a wavelength division multiplexing element before F to thereby pump the FDE by providing it with the combined light arriving by a forward combiner C in the same direction as that of the optical signal, and that the pump lights generated by the rear pumping sources B1, B2 are combined by a time division multiplexing element A rear wave F to thereby pump the FDE by providing the combined light arriving by a rear combiner D in a direction opposite to that of the optical signal.

<U> (4) Other process </ U> A process using a combination of the first to the third processes.

In the bidirectional pumping process (1) above, there is pump light (residual pump light) that has been introduced into the FDE but has not been used to pump the FDE. The residual pump light may fall on the pump source opposite the pump source by which the pump light is emitted, thereby making the output of this first pump source unstable or risking the pump source. to damage. To avoid this, as shown in FIGS. 5 and 6, it was inevitable in the past to introduce an optical isolator G at the output end of the pump source.

In the above pumping method (2), as each polarized wave combination element E can combine only two pump lights, there is a limitation to obtaining a high output level of the pump. pom page light.

In the above pumping method (3), as long as the wavelength division multiplexing element F is within an effective pumping wavelength band, the number of lights pumping that can be multiplexed is theoretically not limited. However, in fact, since the output spectrum of each of the pump sources A1, A2, B1, B2 has a certain width, the multiplexing output is limited according to the combined wavelength properties of the multiplexing element. For example, a semiconductor laser diode (LD) having a wavelength of 1480 nm, which is the most common pumping source for AFDE, exhibits an oscillation. multiple longitudinal and the width of its spectrum is about 5 nm. On the other hand, since the effective pumping wavelength band of AFDE at 1480 nm is about 1450 to 1500 nm, multiplexing is actually limited to wavelength division multiplexing. triple.

In recent years, as shown in FIG. 7, use has been made of a semiconductor laser diode module (LD module with RBF) in which the spectrum width is narrowed using a network. fiber Bragg (RBF) on the outside of a semiconductor laser diode (LD) as an external resonator. In such a modulus, the RFB is provided on the portion of the optical fiber that is connected to the semiconductor laser, so as to make the width of the output spectrum narrower than that of a conventional module that does not include RBF, to bring it to about 1 nm, as shown in Figure 8. As a result, a higher density wavelength division multiplexing is allowed.

In recent years, a wavelength division multiplexer has been developed as a wavelength division multiplexer of the Mach-Zehnder type using a fiber-fusion waveguide element. in silica. Fig. 9A shows a schematic view thereof and Fig. 9B shows its transmittance spectrum. Fig. 10 shows an example of the 1 × 8 wavelength division multiplexer of the Mach-Zehnder type. This wavelength division multiplexer has 1 x 8 ports to provide different central wavelengths from the ports of order n (= 1.2 ... 8), and presents a property according to which, when frequency equidistant lights are input, these lights are combined to be output by the port 0.

The transmittance of each of the Mach-Zehnder 1 × 8 wavelength division multiplexer ports is that shown in FIG. 11. As indicated above, by performing the LD module with RBF in a form capable of multiplexing the wavelengths with a high density by narrowing the spectrum, and the Mach-Zehnder type wavelength dividing multiplexer in a form capable of effectively combining multiple lights having lengths different central wavelengths, it is possible to obtain a pump source having a higher output level. If such a pumping source can be used as a pumping source for AFDE, an AFDE with a high output level can be easily and efficiently obtained.

However, when the LD module with RBF is used as a pumping source for AFDE, the following problems must occur (1) As shown above, in Figures 5 and 6, due to the presence of light In the case of residual pumping, the pumping light emitted by the pumping source may become unstable or the pumping source may be damaged. To prevent this, the use of the optical isolator is unavoidable. However, since the LD module with RBF includes the RBF as the external resonator, the optical isolator can not be placed inside the module.

(2) For the reason indicated above, the optical isolator must be provided outside the module or must be inserted after the combination of the pump lights output by the LD module with RBF. By doing so, although an unstable pumping light output level and deterioration of the pumping source due to the residual pumping light can be avoided due to insulator insertion loss. optical, the intensity of the pumping light is decreased.

 SUMMARY OF THE INVENTION The object of the present invention is to solve the above-mentioned problems of the optical communication system using AFDE. To achieve this object, in the present invention, a semiconductor laser diode module (LD module with RBF) is used as a pump source, and a Mach-Zehnder type wavelength division multiplexer is used. As a combiner for sending an AFDE pump light from the pump source, and further the front pump light length is different from that of the rear pump light, so as to be able to suppress an optical isolator.

To this end, the present invention provides a bidirectional pumping optical amplifier (AFDE) in which an optical amplification fiber (FDE) is pumped from a forward direction by pumping light from a pump source before, and from a rearward direction by pumping light from a rear pump source, the amplifier being characterized in that the pump sources are constituted by semiconductor laser diode (LD modules with RBF), while the pump lights emitted by the respective pumping sources are applied to the optical amplification fiber (FDE) via dividing-length multiplexers. Mach-Zehnder type wave, so that pumping lights having different wavelengths are emitted by the front pump source and the rear pump source.

According to another aspect of the present invention, two or more forward pumping sources and two or more rear pumping sources are used, so that pumping lights having different wavelengths are emitted by all four. pumping sources or more.

According to another aspect of the present invention, the wavelengths of the pump lights emitted by the two or more pump sources before and by the two or more rear pump sources are different from each other, while the sources front pumping and the rear pumping sources are arranged alternately.

According to yet another aspect of the present invention, the wavelengths of the pump lights emitted by the two or more pump sources before and by the two or more rear pump sources are different from each other, while that the longest wavelength of the front pumping lights is smaller than the shorter wavelengths of the rear pom lights.

According to yet another aspect of the present invention, the Mach-zehnder wavelength division multiplexer and the semiconductor laser diode module (LD module with RBF) correspond to a pumping band of about 980. nm or about 1480 nm.

In yet another aspect of the present invention, the level of residual pusher light emitted by a vacant port of the Mach-Zehnder wavelength division multiplexer can be monitored.

In a final aspect of the present invention, the level of the residual pump light emitted from a vacant port of the Mach-Zehnder wavelength division multiplexer is monitored, and the FDE amplification level is monitored. is controlled by adjusting the level or levels of one or both of the front and rear pump sources, based on a monitored result.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be described hereinafter in more detail with the aid of embodiments shown in the accompanying drawings in which FIG. 1 is an explanatory view showing an amplifier. bidirectional pumping optical indicator according to a first embodiment of the present invention; Fig. 2 is an explanatory view showing a bi-directional pumping optical amplifier according to a second embodiment of the present invention; Fig. 3 is an explanatory view showing a bi-directional pumping optical amplifier according to a third embodiment of the present invention; FIG. 4 is an explanatory view showing a bi-directional pumping optical amplifier according to a fourth embodiment of the present invention; Fig. 5 is an explanatory view showing an example of a conventional bidirectional pumping optical amplifier; FIG. 6 is an explanatory view showing another example of a conventional bidirectional pumping optical amplifier; Fig. 7 is an explanatory view showing a fundamental feature of an LB module with RBF; FIG. 8 is a graph showing a comparison between the output spectrum of the LB module with RBF, and the output spectrum of a normal LB module; Fig. 9A is an explanatory view showing a fundamental feature of a Mach-Zehnder type wavelength division multiplexer, and Fig. 9B is a graph showing the transmittance intensity spectrum of the multiplexer. Figure 9A; Fig. 10 is an explanatory view showing a fundamental feature of a Mach-Zehnder type wavelength division multiplexer with 1 x 8 ports; and FIG. 11 is a graph showing the transmittance intensity spectrum of the multiplexer of FIG.

BEST MODE FOR CARRYING OUT THE INVENTION <U> (First Embodiment) </ U> A bidirectional pumping optical amplifier according to a first embodiment of the present invention is shown in FIG. bi-directional pumping optical amplifier is designed such that an optical amplification fiber (FDE) is pumped from a forward direction by pumping light from a front pump source 2, and from a rearward direction by pumping light from a rear pump source 3. A Mach-Zehnder type 4 wavelength division multiplexer, with 1 x 2 ports, is connected to a front end of the FDE through a front combiner (MDLO coupler) 10, the front pump source 2 is connected to one (P1) of incident ports of the wavelength division multiplexer 4 of Mach-Zehnder type, a division multiplexer 4-port Mach-Zehnder type with 1 x 2 ports, is connected to a rear end of the FDE via a rear combiner (MDLO coupler) 12, and the rear pump source 3 is connected to the one (P2) of incident ports of the wavelength division multiplexer 4 of Mach-Zehnder type. In addition, semiconductor laser diode modules (LD modules with RBF) are used as pumping sources 2, 3, so that pumping lights having different wavelengths are emitted by the pumping sources before and back 2, 3.

The wafer division multiplexer 4 of the Mach-Zehnder type used in the present invention has a fundamental characteristic shown in FIG. 9A, as well as a transmittance intensity 113 (%,) for ports 1-> 3, and a transmittance intensity 114 (7 @) for ports 1-4, which are represented as follows 113 (A,) = 1-4 Cc (1-a) sin2 (nci + / 2) 114 (# -) = 4 (c (1-oc) sine (nci / @. + / 2) ... (1) In these expressions, cc is a branching rate, T is a delay due to the difference in lengths between the two paths, and 0 is the initial phase.

The transmittance intensity spectrum of Mach-Zehnder wavelength division multiplexer 4 is shown in FIG. 9B. As can be seen from equations (1) above and from FIGS. 9A and 9B, at a wavelength for which the transmittance becomes maximum at port 1 <B> ---> </ B> 3, the transmittance for ports 1-> 4 is -40 dB or less, so as to provide very high isolation. Similarly, in a Mach-Zehnder wavelength division multiplexer designed so that (1 xn) ports are provided and the port n allows to pass a wavelength a, n with a high transmittance, such as a light having a wavelength 2, m (1- <m- <n) introduced by the port 0 is coupled only to the port m and is not coupled to the other port 1 (1-t1 and m # 1), in the port n, the wavelength λ 1 is suitably isolated from the wavelength m m.

Figure 10 shows a Mach-Zehnder wavelength division multiplexer with 1 x 8 ports, and Figure 11 shows the transmittance intensity spectra in port 0 and ports 1 to 8 of multi-port. wavelength division plexeur of the Mach-Zehnder type. As shown in the graph of Fig. 11, if one considers the transmittance property <B> (O </ B> in Fig. 11) between ports 0 and 1, the transmittance becomes wavelength maximum. for port 1, and greater than -40 dB isolation is provided for the central wavelengths of other ports. Similarly, considering the transmittance property (in Figure 11) between ports 0 and 2, the transmittance becomes maximum at the center wavelength for port 2, and greater than - 40 dB is provided for the central wavelengths of other ports; furthermore, if we consider the transmittance property (in Fig. 11) between ports 0 and 3, the transmittance becomes maximum at the central wavelength for port 3 and an isolation greater than -40 dB is provided for the central wavelengths of other ports; finally, considering the transmittance property <B> (O </ B> in Figure 11) between ports 0 and 4, the transmittance becomes maximum at the central wavelength for port 4 and an isolation Greater than -40 dB is available for the central wavelengths of other ports. As a result, when the pump source corresponding to the central wavelength λ, 1 of port P1 of Mach-Zehnder wavelength division multiplexer 4 with 1 x 2 ports is connected to the port P1 for pumping the FDE from the forward direction, and when the pumping source corresponding to the center wavelength @, 2 of the port P2 of the rear-wavelength division multiplexer 4 of the Mach-type. Zehnder with 1 x 2 ports having the same property, is connected to the P2 port to pump the FDE from the backward direction, as the front pump light pumps the FDE and the residual pump light reaches the Mach-Zehnder rear wavelength division multiplexer 4 via the rear MDLO neck 12 and is emitted by the port of the mutiplexer 4 which is not connected to the pump source. back 3, there is no bad influence affecting the source of p On the contrary, because the residual pumping light of the rear pumping light which did not pump the FDE reaches the Mach-Zehnder front wavelength division multiplexer 4 via the coupler MDLO before 10 and is admitted by the port of the multiplexer 4 which is not connected to the pump source 2, there is no bad influence affecting the source of pumping before 2.

<U> (Second Embodiment) </ U> A bidirectional pumping optical amplifier according to a second embodiment of the present invention will now be described with reference to Fig. 2. The fundamental construction of the optical amplifier shown Figure 2 is the same as that shown in Figure 1. The differences are that wavelength division multiplexers 4 of the Mach-Zehnder type have 1 x 4 ports, whereas lights having M wave,%, 3 are applied to the input of ports P1, P3 of Mach-Zehnder type wavelength division multiplexers before 4 from a forward pumping source (LD semiconductor with RBF) 2 connected to the ports P1, P3, and that lights having wavelengths;, 2, U (the wavelengths;, 1, h2, a.3 and U are differentiated from each other) are in ports P2, P4 of the wavelength division multiplexers 4th Mach-Zehnder type from a rear pump source (semiconductor LD with RBF) 3 connected to ports P2, P4. In this case, the lights (M, @ .3) applied to the input of the ports P1, P3 of the forward-wavelength division multiplexers before Mach-Zehnder 4 are combined by these multiplexers 4, and the lights (;, 2, a, 4) applied to the input of the ports P2, P4 of the Mach-Zehnder type rear-wavelength division multiplexers 4 are combined by these multiplexers 4, so that these Lights are introduced into the FDE respectively by the forward combiner (MDLO coupler 10 and back combiner (MDLO coupler) 12, to pump the FDE, while the respective residual pump lights are emitted by the vacant ports (opposite to the sides). output) of wavelength division multiplexers 4 of the Mach-Zehnder type.

<U> (Third Embodiment) </ U> A bidirectional pumping optical amplifier according to a third embodiment of the present invention will now be described with reference to Fig. 3. The fundamental construction of the optical amplifier shown FIG. 3 is the same as that shown in FIG. 2. The difference is that the wavelengths λ1, λ2, λ3, and λ4 of the pump lights emitted by the sources of 2, 3 have a relationship such that k1, <B> 2.3 </ b> <_, 2, U, i.e. short wavelength pumping light is associated with pumping before and a long wavelength light is associated with the back page pom. With this arrangement, low noise and high output saturation properties can be achieved. Also in this case, the residual pumping lights of the front and rear pumping lights are emitted by the vacant ports (opposite the output sides) of the Mach-Zehnder wavelength division multiplexers. The wavelengths a, 1, # .2, @ 3, X, 4 of the lights generated by the respective pump sources have a relation such that a, 1 <<U <_ a, 3 _ <% 4 that is, the forward pumping wavelengths and the back pumping wavelengths can be arranged alternately. <U> (Fourth Embodiment) </ U> A bidirectional pumping optical amplifier according to a fourth embodiment of the present invention will now be described with reference to Fig. 4. The fundamental construction of the optical amplifier shown FIG. 4 is the same as that shown in FIG. 2. The differences are that the residual pumping lights emitted by the P2, P4 ports of the forward wavelength division multiplexers 4 of the type Mach-Zehnder, are received by optical receiving elements 21 connected to the ports P2, P4, so that the pumping state of the FDE is detected by monitoring the residual pumping lights, and that the levels of the pumping lights Backward are set by a control circuit 22 on the basis of a detection result, thereby maintaining a predetermined amplification state.

In FIG. 4, although an example is illustrated in which the two residual lights emitted by the ports P2, P4 of the forward wavelength division multiplexers before 4 of the Mach-Zehder type are monitored as illus trely, one can only monitor only one or the other of the residual lights emitted by ports P2, P4. In addition, the light emitted by the ports P1, P3 of the Mach-Zehnder rear wavelength division multiplexers 4 can be monitored accordingly to adjust the levels of the forward pump lights. In addition, the residual lights emitted by the two front and rear wavelength division multiplexers 4 of the Mach-Zehnder type can be monitored to adjust the respective pump lights accordingly.

In the bidirectional pumped optical amplifier of the present invention, such as laser diode (LD) modules with RBF are used for the pump sources, and as the pump lights emitted by the pump sources are applied to the pump sources. FDE via the Mach-Zehnder wavelength division multiplexers, so that pump lights having different wavelengths are emitted by the front and rear pump sources, The following advantages (1) The residual pumping lights from the front and rear pumping sources are emitted from the vacant ports (opposite the output sides) of the Mach-Zehnder type wavelength division multiplexers, which has as a result, levels of pumping sources can not become unstable, and pumping sources are not likely to be damaged, even when the optical isolator is not inserted.

(2) Since the optical isolator can be removed, there is no insertion loss of this optical isolator. (3) The pump lights emitted by the semiconductor laser diode modules with RBF can be multiplexed with a high density to efficiently pump the optical amplification fiber, thereby obtaining an optical amplifier having a level of high output.

In the bidirectional pumping optical amplifier of the present invention, as two or more forward pumping sources and two or more back pumping sources are used so that pumping lights having different wavelengths are emitted by the respective pump sources, in addition to the advantages indicated above, the pump lights having different wavelengths can be multiplexed by Mach-Zehnder type wavelength division multiplexers to obtain pumping lights having higher levels, which allows to increase the output level of the optical amplifier.

In the bidirectional pumping optical amplifier of the present invention, as the longest wavelength of the front pumping lights is less than the shortest wavelength of the rear pumping lights, in addition to the advantages As noted above, an optical amplifier having high output level and low noise can be realized.

In the bidirectional pumping optical amplifier of the present invention, such as the Mach-Zehnder type wavelength division multiplexer and the RBF semiconductor laser diode module, correspond to a pumping band. At about 980 nm or about 1480 nm, which is most common in such an optical amplifier, in addition to the advantages noted above, the range of applications can be expanded.

In the bidirectional pumping optical amplifier of the present invention, as the residual pumping light emitted from the vacant port of the Mach-Zehnder wavelength division multiplexer can be monitored, in addition to the advantages mentioned below. above, the amplification state and any other information required on the fiber optic amplifier can be obtained.

In the bidirectional pumped optical amplifier of the present invention, as the level of the residual pump light emitted from the vacant port of the Mach-Zehnder wavelength division multiplexer is monitored, and as is controlled the amplification level of the fiber optic amplifier by adjusting the level or levels of one or both of the front and rear pumping sources, based on a monitored result, in addition to the benefits listed above , the amplification level of the optical fiber amplifier can always be maintained at a predetermined level.

Claims (1)

<U> REVENDICATI 0 NS </ U> 1) Bidirectional pumping optical amplifier in which an optical amplification fiber (EDF) is pumped from a forward direction by pumping light from a light source. front pump source (2), and from a rearward direction by pumping light from a rear pump source (3), characterized in that the pump sources (2, 3) are constituted by semiconductor laser diode modules, and the pumping lights emitted by the respective pumping sources (2, 3) are applied to the amplification optical fiber (FDE) via multiplexers Mach-Zehnder-type wavelength splitting device (4) so that pumping lights having different wavelengths are emitted by the forward and reverse pumping sources (2, 3). 2) bidirectional pumping optical amplifier according to claim 1, characterized in that two or more forward pumping sources (2) and two or more rear pumping sources (3) are used, so that pumping lights having Different wavelengths are emitted by all four pump sources (2, 3) or more. 3) bidirectional pumping optical amplifier according to claim 1, characterized in that # two or more forward pump sources (2) and two or more rear pump sources (3) are used, # the wavelengths of the lights The pumping stations emitted by the two or more pumping sources before and by the two or more rear pumping sources are different from each other, and the front pumping lights and the rear pumping lights are arranged alternately. 4) bidirectional pumping optical amplifier according to claim 1, characterized in that # two or more forward pumping sources (2) and two or more rear pumping sources (3) are used, # the wavelengths of the lights pumped by the two or more pump sources before and by the two or more rear pump sources are different from each other, and # the longest wavelength of the front pump lights is less than the length the shortest wave of rear pump lights. 5) bidirectional pumping optical amplifier according to claim 1, characterized in that the wavelength dividing multiplexer (4) of the Mach-Zehnder type and the semiconductor laser diode module correspond to a pumping band. about 980 nm or about 1480 nm. 6) bidirectional pumping optical amplifier according to claim 2, characterized in that the wavelength dividing multiplexer (4) of the Mach-Zehnder type and the semiconductor laser diode module correspond to a pumping band. about 980 nm or about 1480 nm. 7) bidirectional pumping optical amplifier according to claim 3, characterized in that the wavelength dividing multiplexer (4) of the Mach-Zehnder type and the semiconductor laser diode module correspond to a pumping band. about 980 nm or about 1480 nm. 8) bidirectional pumping optical amplifier according to claim 4, characterized in that the wavelength dividing multiplexer (4) of the Mach-Zehnder type and the semiconductor laser diode module correspond to a pumping band. about 980 nm or about 1480 nm. 9) bidirectional pumping optical amplifier according to any one of claims 1 to 8, characterized in that the residual pump light level emitted by a vacant port of the wavelength division multiplexer (4) can be monitored (4). ) of the Mach-Zehnder type. 10) bidirectional pumping optical amplifier according to any one of claims 1 to 8, characterized in that the residual pump light level emitted by a vacant port of the wavelength division multiplexer of the type can be monitored. Mach-Zehnder, and the amplification optical fiber amplification level (FDE) is controlled by adjusting the level or levels of one or both of the front and rear pumping sources (2, 3) on the basis of a monitored result.